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1. Master Module MXCC OP2 MXCC OP2 MX420 IP2 MX420 IP2 z Z Fiber Link 1 gt Fiber Link 2 Fiber Link 3 Pang TE Virtual Link Fx Module Address Hex 1 Optional SFP to Create Ring Network Figure 4 Multi Node Lost Power 1 2 EOTec MX Multiplexer Modular Solution EOTec MX Multiplexer modules are designed to provide reliable operation in harsh industrial environments Ultra Electronics provides a modular solution for addressing various I O control requirements To create the multiplexed fiber optic modular solution that meets your needs begin by connecting locations together using bi directional MX Multi Node Base Modules connect a suitable 15 to 30Vdc power supply to each base and create a communication link with fiber optic cables between each module Now that you have established a link between your locations as shown in Figure 5 you are ready to start adding I O modules of your choice As shown in Figure 5 the fiber optic base modules are connected using Small Form factor Pluggable SFP transceivers and fiber optic cable The user can select either a multi mode or single mode solution and select from four different transceivers depending on the distance required between stations DATA j Input and Output Modules can now be added 10 2 sant to each base unit to provide the desired I O solution Bi directional communication POWER allows the user to
2. i T a Ll y a Li This type of addressing and communication scheme is commonly referred to as a Publisher Subscriber relationship When an Input Module sets a Module Address this can be seen as a Publisher which writes an I O data signal to a predetermined address location of the communication packet being sent over the optical fiber to each Multi Node Station When an Output Module is set to this same Module Address it becomes a Subscriber to this data signal As a new data packet arrives at each Multi Node Station all Output Modules at this same address are updated with new data auras Gp EA ET ULL VR All Module Address Switches ship from the factory in the off position 0000 0000 This means they are all set to the same address The user must change the Module Address Switches to fit their own fiber optic network configuration needs Figure 35 Module Address Switches Hexadecimal Notation To help in the discussion of module address selection it may of value to have a quick review of Hexadecimal Notation Hexadecimal Hex is a 16 digit numbering system which can be used in describing the current state of a bank of switches Since there are eight switches in each bank we can expand on binary notation to describe how to set SW1 SW4 on each Multi Node Module see Figure 35 Each switch bank has eight switches Figure 11 Each of these eight switches has two positions On Off so
3. 3 3 1 Module Installation For installation of this equipment in a hazardous location always remember that the power line must be de energized before connecting or disconnecting the terminal plugs on these devices To install place the top lip of any MX Multiplexer module s mounting channel onto the DIN rail as shown in Figure 39 Push the lower portion of the module towards the mounting surface until it clicks and locks the spring loaded clip into place Both I O Modules and Multi Node Bases are mounted onto the DIN rail in the same fashion Figure 39 Install Module Remove the bus covers Figure 41 on the Multi Node Base and set them aside for later use I O modules can now be attached to either side of the Multi Node Base by sliding the modules together along the DIN A total of 4 VO modules can be connected to each Multi Node Base When the DIN rail is strapped to earth ground the metal clip inside of the upper lip of the mounting channel of each MX Multiplexer module connects earth ground to the circuit boards inside each module 3 3 2 Bus Covers and End Clamps To complete the installation use the bus covers and end clamps shown in Figure 40 which ship with each MX 4 Multi Node Base MXBMN module Once the last I O module is mounted and operational the parts in Table 31 are used to finish the installation of each module stack or station residing throughout the Multi Node MX Multiplexer fiber optic network
4. Item Qty Description Part No Left BUS Cover 2BCL Je Table 31 Cover amp Clamp Part Numbers Figure 40 Covers amp Clamps Take the three parts listed in Table 31 and mount the two BUS covers over either side of each module stack or MX Multi Node Station As shown in Figure 41 the left cover will mount over the left male side of the BUS and the right cover will mount inside the right female side of the BUS 52 EOTec 2000 Multi Node MX Multiplexer User Manual The two End Clamps mount on either side of the MX Multi Node Station by ensuring the two end hooks catch the top and bottom of the DIN rail Then clamp the hooks down onto the rail by tightening the middle screw as shown in Figure 42 RIGHT COVER Figure 41 BUS Covers Figure 42 End Clamp End clamps have two cage clamp screw terminal blocks connections one on the top and the other on the bottom as you see it mounted on the rail in Figure 42 Wires of 12 to 24 AWG can be captured in one of two cage clamps with a direct connection to the DIN rail The end clamps can be used to connect earth ground to the DIN Rail or to connect to an I O cable shield as may be required ATEX Special Conditions of Safe Use Modules shall be installed in an enclosure which maintains an ingress protection rating of IP54 and meets the enclosure requirements of EN60079 0 and EN60079 15 The EOTec modules shall be installed on DIN rail with DIN end clamps mounted on both sides
5. Current Rating 90mA 24Vdc Max Loop Resistance 600 Ohms Operating Range 3 8 to 20 5mA Voltage Conversion 4mA OVdc 20mA 10Vdc Scale 1ma 0 625Vdc Screw Terminals 2 4 20mA Process Loop Ports Pluggable Cage Clamp Screw Terminal Blocks 12 to 24 AWG Weight lt 9 oz Enclosure Material Polyamide Flammability Rating UL 94V O MX420 OP2 Input Fuse 500mA 125V Replacement fuses can be purchased from your Schurter distributor Part number 3403 0163 11 21 PORT TERMINAL PORTA 1121 3 4 Porr 2 Isjelris el EIE p n m j b cn cri refet WOE F Ll WOE og D ER ul 2 3 EOTec 2000 Multi Node MX Input Power Range Current Rating Max Loop Resistance Operating Range Voltage Conversion Screw Terminals Weight Enclosure Material Flammability Rating MX420 OP4 noe Input Fuse mA Output Connection Ports 3 amp 4 Only Aavailable on d Port Model MX420 0P4 Interconnection 15 to 3OVDC via the interconnection Bus from an MX Multi Node Base Module MXBMN or MXBMN NH 130mA 24Vdc 600 Ohms 3 8 to 20 5mA 4mA OVdc 20mA 10Vdc Scale 1ma 0 625Vdc 4 4 20mA Process Loop Ports Pluggable Cage Clamp Screw Terminal Blocks 12 to 24 AWG lt 902 Polyamide UL 94V 0 500mA 125V Replacement fuses can be purchased from your Schurter distributor Part number 3403 0163 11 4 20mA LOOP MONITOR E GND
6. For Safety requirements these products comply with Canada CSA C22 2 APPSOVEN No 142 Process Control Equipment These products have been assessed against and found to be in conformity with approvals for hazardous locations and explosive atmospheres for USA Ex and Canada Also the Essential Health and Safety Requirements EHSR s of the ATEX Directive 94 9 EC for use in potentially explosive FM11ATEX0067X atmospheres and display the adjacent markings as shown to the left in II 3 G Ex nA IIC T4 Ta 40 C to 85 C Contact Closure In Regulatory Markings The connections to a Contact Closure Input Module are shown in Figure 26 Power is connected through the 10 2 Interconnection Bus when attached to the Multi Node Base As each module is stacked together the 10 data signals and 2 power signals are passed to the newly connected module Each Pluggable Screw Terminal Block serves as a Contact Closure input or port A contact closure can be created by connecting or shorting terminals I and 4 together on each port as shown in Figure 26 All MX Multiplexer I O Modules are hot pluggable when used in a non hazardous area Damage will not occur to either the I O Module or the Multi Node Base Module when connected disconnected while power is on However do not separate the internal board assembly from the housing while power is on as this may damage the electrical circuits of this board For safety reasons always remember that connecting d
7. MX010 OP2 Input Fuse 25 50mA 24Vdc 70 Ohms Minimum 125mV to 10 3125Vdc OVdc 4mA 10Vdc 20mA Scale 1Vdc 1 6mA 2 0 10Vdc Process Measurement Ports Pluggable Cage Clamp Screw Terminal Blocks 12 to 24 AWG lt 9 oz Polyamide UL 94V 0 500mA 125V Replacement fuses can be purchased from your Schurter distributor Part number 3403 0163 11 EOTec 2000 Multi Node MX Multiplexer User Manual 0 10Vdc Output Model Input Power Range Current Rating Output Impedance Operating Range Voltage Conversion Screw Terminals Weight Enclosure Material Flammability Rating MX010 OP4 HEREZ r 4 Port Specifications Input Fuse 15 to 30VDC via the interconnection Bus from an MX Multi Node Base Module MXBMN or MXBMN NH 65mA 24Vdc 70 Ohms Minimum 125mV to 10 3125Vdc OVdc 4mA 10Vdc 20mA Scale 1Vdc 1 6mA 4 0 10Vdc Process Measurement Ports Pluggable Cage Clamp Screw Terminal Blocks 12 to 24 AWG lt 9 oz Polyamide UL 94V 0 500mA 125V Replacement fuses can be purchased from your Schurter distributor Part number 3403 0163 11 0 10Vdc Output Connections PE GND OPTIONAL Ad amp 0 10Vdc y Connect Process Signal Monitor PORT TERMINAL porra 1121314 Porralslelris is als Gj n F m 3 El in cn 10 2 Interconnection 10 2 Interconnection POWER PORT 1 OPAC LO LIONISULOS OF 1 PAOLO
8. This example will show the user how to install a simple 4 20mA application as shown in Figure 37 All Multi Node MX Multiplexer fiber optic network installations follow the same basic steps By understanding this example you will understand how to install a fiber optic network to meet your needs This network configuration assumes that Fiber Links 1 2 and 3 Figure 37 are no farther than 2 kilometers each Multi mode fiber optic cable will be used to create a serial communication link or daisy chain network I Remote 1 Remote T Remote 4 44 Control FE FE FL vm Station I FI Station 2 pp Station 3 Room Fiber Link 1 Fiber Link 2 Fiber Link 4 Fa Module Address Hex Optional SFF to Create Ring Network Figure 37 Example 1 4 20mA Daisy Chain In this installation the objective is to provide three 4 20mA signals from three remote locations to a Control Room for monitoring The MX Multiplexer part numbers required to build this particular fiber optic network are listed in Table 17 Additional parts will also be needed to complete a fiber optic network but not supplied by Ultra Electronics NSPI See Table 18 Example 1 Ultra Electronics NSPI Required Parts Quantity Ultra Part Number MXBMN Multi Node Base Module MX420 IP2 4 20mA Input Module 2 Port MX420 0P2 4 20mA Output Module 2 Port 6 SFP13 100M2K Multi Mode SFP Transceiver 1310nm 8db 62 5 125um fiber 2k Table 17 Example 1 Ultra Parts Req
9. Example 1 Remote Station 1 Switch Settings ss 46 Table 23 Example 1 Network Configuration Worksheet ss 47 Table 24 Example 2 Ultra Parts Required issie Rd Ged sd Ge oe Re ke Be ed de Ge ee Ed Ed ee 48 Table 25 Example 2 Additional Parts Required ss 48 Table 26 Example 2 Control Room Switch Settings sise 49 EOTec 2000 Multi Node MX Multiplexer User Manual Table 27 Table 28 Table 29 Table 30 Table 31 Table 32 Table 33 Table 34 Example 2 Remote Station 1 Switch Settings sise 49 Example 2 Remote Station 2 Switch Settings sise 50 Example 2 Remote Station 3 Switch Settings sise 50 Example 2 Network Configuration Worksheet ss 51 Cover amp Clamp Part NUMDETS rv 52 Multi Node MXBMN Local Alarms wrrnrrnnnnnnnnnnnnnnnnnnvnnnnnnnnnnnnnnnnnnnnnnnnnnvnnnnnvnnnnnnnennnnnnnnnnnsennnnee 54 REA GLEN E TE T E de 54 I O Module Local Alarims ccccsssccsssscccssscccseccnsssecsssconsssenessceessseuseseusesscevescusssenesseneseseeseseeses 55 EOTec 2000 Multi Node MX Multiplexer User Manual Standards amp Safety The EOTec MX Multiplexer Modules from Ultra Electronics have been designed to meet the following standards Les modules EOTec multiplexeurs MX d Ultra Electronics ont t con us pour r pondre aux normes suivantes C The EOTec MX Multiplexer Series of products all meet the requirements for CE marking per EN61326 1 lose ou Please check the product information in Cha
10. No fiber connected 36 EOTec 2000 Multi Node MX Multiplexer User Manual This indicates that an SFP has been installed but that no fiber connection has been made between this Multi Node Base and another Because the transceiver RX is not receiving light across a fiber optic cable not only will it show a fault RX red but the Global LED will also show a fault For more information on the causes of global faults see Table 32 and Table 33 The diagnostic indicators identified in Table 7 and displayed on the unit in Figure 31 show a properly powered unit with no fiber optic cable connections The Module Status LEDs I O 00 11 are not applicable in this situation as no I O modules have been installed so these LEDs will remain off The Master LED is also off Default and will only turn green if the unit in question is selected to be the Master module for a redundant ring network For more information on Master selection see Chapter 0 Label Diagnostic Indicators N The diagnostic indicators displayed on the Power IN 1 Green Power Good AG Multi Node Base in Figure 32 show a correct IN 2 Green Power Good OD connection via optical fiber cable to two Eibert Tes Grean R Green utro ML other Multi Node Bases and referenced in EE SNF ng Table je If the Se en base i pe RE aidad connected to one other base unit then the Fiber 2 TX G RX G I ee amit man transmit TX and receive RX LEDs will be ae Li sal o
11. Master Slave Selection ee ee ee ee ee ee ee ee ee ee ee ee Ge 17 216 MX MuMENode Base Fuse Replacement saved 17 2 1 7 MX Multi Node Base Module Reassembly 4 18 2 1 8 MX Multi Node Base Product Regulatory Markings ss 18 2 2 Analog Data Links Products Designed for Flexibility ss 19 221 1064 2004 Process LOOD But apene 19 2 2 2 The4 20mA Process Lo0p Output sees sien Ee ei EG EE Ke see Ee ne ee EG Ge ee se ED EG RR EG ee N Ge ee ee Ee 21 2 2 3 The 0 10Vdc Process Management Input ek EE AR EE AR EE ARE Ee ee AAR Ee ee ee AR Ee ee ee AR ee ee ee ee ee ee ee RE 23 2 2 4 The 0 10Vdc Process Management OutpDU sesse ese ee REGS ek EE Ee ek EE Ee ek EER Ee dee Ee eGGSA EE Ee ek GEE Ee 25 225 Andog Data Link OP NNN EE ie ee n ee oe E ae ie oe Ee eo rit DE 27 2 2 6 Current Voltage Conversions Using Analog Data Links EE ee ee ee ee ee ee ee ee ee ee eed 28 2 3 Digital Data Links Products Designed for Reliability esse ee ee 29 241 The CONLAEE Closure SIN EEE EEE EE mit ie ee 29 232 The Contact de UN Leiden n ae oe net ae eee rence A en an te diem nue 31 2 3 3 Digital Data Link Operational Settings ses dee EEN ie ee Ge ei n Oe ee ee eel ee ee We ge ek ere Ne 33 3 Network Planning Configuration and Installation ccccscsccsccsccccsccsccccsccsceccececcsscsceccscescecees 34 3 1 N twork DES TAPES ta ee ee nu ce 34 LL Consider Number OF VO LOCOtIONS sae de N si en Re ee e
12. OPTIONAL PORT 1 N PORT 2 S 10 2 Interconnection Bus MX420 0P4 dee AN id S Figure 18 MX420 OP Mating Connections 22 EOTec 2000 Multi Node MX Multiplexer User Manual 4 20mA Output Regulatory Markings The EOTec MX Multiplexer modular 4 20mA Input products MX420 OP2 and MX420 OP4 comply with the essential requirements of the ho following applicable European Directives and carry the CE marking accordingly EMC Directive EN 61326 1 2006 lt i gt For Safety requirements these products comply with Canada CSA C22 2 APPROVED No 142 Process Control Equipment These products have been assessed against and found to be in conformity with approvals for hazardous locations and explosive atmospheres for USA Ex and Canada Also the Essential Health and Safety Requirements EHSR s of the ATEX Directive 94 9 EC for use in potentially explosive atmospheres and display the adjacent markings as shown to the left in 4 20mA Output Regulatory Markings FM11ATEX0067X II 3 G Ex nA IIC T4 Ta 40 C to 85 C The connections to a 4 20mA Output Module are shown in Figure 18 Power is connected through the 10 2 Interconnection Bus when attached to the MX Multi Node Base As each module is stacked together the 10 data signals and 2 power signals are passed to the newly connected module Each Pluggable Screw Terminal Block serves as a 4 20mA process loop output or port A current monitor can be connect
13. Signal Resolution 2 Sensitivity or 65 536 Steps gt Industrial Design for High Reliability o Modular flexible scalable o Operating temperature range 40 to 85C o FM approved for Class I Div 2 Groups A B C amp D T4 O O O O Cr D MX420 0P3 Mi O TEEd sede 9 05 ATEX listed II 3 G Ex nA IIC T4 Ta 40 C to 85 C Standard 35 mm DIN rail mounting gt Additional Features o Capable of translating between Current and Voltage o Replaceable Fuse 2 2 1 The 4 20mA Process Loop Input 4 20mA Input Model 2 Port Specifications GL VE Current Rating Input Impedance Operating Range Voltage Conversion Screw Terminals Weight Enclosure Material MX420 IP2 Input Fuse 19 Input Power Range Flammability Rating 15 to 30VDC via the interconnection Bus from an MX Multi Node Base Module MXBMN or MXBMN NH 55mA 24Vdc 50 Ohms 3 8 to 20 5mA AmA OVdc 20mA 10Vdc Scale Ima 0 625Vdc 2 4 20mA Process Loop Ports Pluggable Cage Clamp Screw Terminal Blocks 12 to 24 AWG lt 9 oz Polyamide UL 94V 0 500mA 125V Replacement fuses can be purchased from your Schurter distributor Part number 3403 0163 11 EOTec 2000 Multi Node MX Multiplexer User Manual 4 20mA Input Model 4 Port Specifications Input Power Range 15 to 30VDC via the interconnection Bus from an MX Multi Node Base Module MXBMN or MXBMN NH Current Rating 65mA 24Vdc Input Impedance 50 Ohms Opera
14. We begin this Multi Node MX Multiplexer fiber optic network configuration by starting at the left of Figure 37 with the first Input Module at Station 3 There is only one Input Module at this station so the Channel Select switches can be left in the default setting of 00 for this Input Module MX420 IP2 as shown in Table 19 The Multi Node Base Module at Station 3 must now set a Module Address for this Input Module to share the input data across the fiber optic network The Input Module selects to use of I O Channel 00 so now has the Module ID of Module 00 On the Multi Node Base an 8 position switch SW1 is used to select a Module Address for Module 00 As shown in Table 19 the Module Address has all switches turned to the On position 1 for an address of 1111 1111 Binary or FF Hex Since this is an Input Module the Output Port Mapping switches will have no effect on an Input Module so can be left in the default positions All unused switches for the Multi Node Base Module at Remote Station 3 are shown grayed out and left in the default position The Multi Node Base at this stage of the setup shows a green flashing LED for I O 00 Module ID 00 as the matching Output Module in the Control Room has not been setup yet This Input Module at Station 3 1s shown to be Abandoned until the module in the Control can be setup with the same Module Address I O Remote Station 3 Channel gle Output Port Mapping Binary Select ak
15. at Port 1 of Module 11 in the Control Room which now can be measured at Station I on Module O1 at Port 1 I O MXBMN Remote Station 1 Channel Device Output Port Mapping Binary Select ID SWt Module Address Binary SWt Port 1 ne gt Es Lo 1 Mxcc op2 sw2 1 1f1 1f1 1 0f0 FC swe A 1 o ajoj N ME ft ft lw TG aaf ee ee ee ee ee ee TNT TG Input Port 1 is Mapped to Output Port 1 default Table 27 Example 2 Remote Station 1 Switch Settings JE m m Remote Station 2 Moving to Remote Station 3 as shown in Figure 38 the output from the Control Room Port 2 input signal can be configured There is already another I O Module attached to the Multi Node Base at this station so the Channel Select switches for this 2 Port Output Module MXCC OP2 must change to 01 as shown in Table 28 Because this Input Module is now set to Module ID 01 the Multi Node Base 8 position switch SW2 is used to select a Module Address for Module 01 The matching Input Module for this Output Module is at the Control Room so the correct address to set at SW2 is also 1111 1100 Binary or FC Hex There is already an Address Match between the Control Room and Station 1 When adding this new Output Module Module ID 01 as shown in Table 28 to the same address as 49 EOTec 2000 Multi Node MX Multiplexer User Manual the Input Module confirm this module also has an address match The I O 01 Module Status LED Station
16. input signal by using a switch board system known Output Port Mapping By default the Output Port Mapping Switches are set to what is called a 1 1 configuration This default configuration connects Port 1 of the Input Module to Port 1 of the Output Module Port 2 input to Port 2 output and so forth for Port 3 and Port 4 By reconfiguring the default settings it is possible to take consolidated inputs from one location using a 4 Port Input module and distribute these signals to multiple locations where the more economical 2 Port Output Modules are used Or use the economical 2 Port Input Module to provide one signal to all 4 ports of an Output Module Or even one signal to multiple output Modules The uses of Output Port Mapping are explained in Chapter 3 2 5 and a good example provided in Chapter 3 2 7 3 1 6 Consider Using a Remote Alarm The remote alarm relay on each Multi Node Base Module activates whenever a Global Alarm occurs This alarm will activate during two conditions One when power is lost at one the dual power input terminals and the second is when the fiber optic receiver fails to receive a signal fiber break or bad data For more information on alarm conditions please see Table 33 in Chapter 3 4 35 EOTec 2000 Multi Node MX Multiplexer User Manual Once a global alarm occurs the remote relay on every Multi Node Base throughout fiber optic network becomes active This provides an alert of a fiber optic network problem fro
17. input signal to Port 1 of the Output Module by setting switches 7 amp 8 from the default setting of 00 to 10 Port 3 The some useful scenarios for Output Port Mapping are explained in Chapter 3 2 5 and a good example is provided in Chapter 3 2 7 For further information on configuring Multi Node Base operation settings refer to Chapter 3 2 2 1 5 MX Multi Node Base Master Slave Selection The Master Slave Jumper as shown in Figure 12 is used to select each Multi Node Base Module as a Slave Module or as the one Master Module to control a Redundant Ring Network All Multi Node Bases come configured from the factory as a Slave Module To reconfigure the Multi Node Base to be the one Master Module in your EOTec 2000 Multi Node MX Multiplexer system move the jumper from the Slave position to the Master position For more information on configuring the Master Slave Jumper to properly setup a fiber optic network refer to Chapter 3 2 1 6 MX Multi Node Base Fuse Replacement The MX Multi Node Base has 3 fuses The Control Board has a 0 5A fuse to protect against voltage surges on the Power In connection of the 10 2 Interconnection Bus A replacement fuse can be directly order from your Schurter distributor using part number 3403 0163 11 The Optical Board has two 1 25A fuses to protect against voltage surges on the dual power inputs at the 4 position terminal connector on the front of the Multi Node Base Module F1 is in lin
18. matching address location of the publisher for the attached output ports Remote Remote Remote Control Station I FC ry Station 2 FC vn Station 3 IC FF D Room LE PN soi MXCC OP2 MX420 IP2 MX420 OP2 A La ary A pe Fiber Link 1 ds Fiber Link 2 Fiber Link 3 Fx Module Address Hex Optional SFP to Create Ring Network Figure 1 Multi Node Daisy Chain Communication EOTec 2000 Multi Node MX Multiplexer User Manual 1 1 2 Ring or Redundant Communication Method The I O network shown in Figure 1 is a simple serial communication link or daisy chain All stations can pass information bi directionally between stations via Fiber Links 1 2 amp 3 However if one optical fiber in either the upstream or downstream communication link is broken network communication is disrupted and critical network functions fail to operate properly By adding another physical connection termed as the Virtual Link see Figure 2 aredundant or secondary pathway is created for use when a failure occurs in the primary communication link Remote Remote Remote Control Station I FC FE Station 2 FC pp Station 3 d F F FD Room m a a Master Module JE E he ee i 33 tte Bon seire nm las he Fiber Link 1 Fiber Link 2 Fiber Link 3 Virtual Link Fx Module Address Hex I Optional SFP to Create Ring Network Figure 2 Multi Node Ring Communication 1 1 3 Fiber Br
19. of the module set The DIN rail must be connected to Protective Earth in order to provide modules with a Protective Earth connection Do not disconnect equipment connections or modules when energized 3 3 3 Module Removal When working with this equipment in a hazardous location always remember that the power line must be de energized before connecting or disconnecting the terminal plugs on these devices Once this is done work the installation process backwards by first uninstalling all wiring from all I O modules and the Multi Node Base then disconnecting the fiber from the Base Module Next remove the two end clamps as shown in Figure 42 Now any module can easily be separated along the BUS connector from the others in the Multi Node Station To remove each module from the DIN rail place a screwdriver in the slot at the bottom of the spring clip as shown in Figure 43 and pry downward This compresses the spring and the module comes right off Figure 43 Module Removal 53 EOTec 2000 Multi Node MX Multiplexer User Manual 3 4 Diagnostic Indicators Diagnostic indicators are used for both setting up an I O network and troubleshooting any faults that may arise LEDs or local alarms are used on the front of each module to display the modules current status See Table 32 for all LED fault indicators associated with the MX Multi Node Base MXBMN and Table 34 for fault indicators associated with the I O modules A relay is als
20. place Input and Output Modules at any Multi Node station within the fiber optic network Each I O Module is plugged into the Base using the 10 2 Interconnection BUS see Figure 6 Select either 2 Port or 4 Port I O modules to form your solution As few as 2 or as many as 16 I O port connections can be supported by one Multi Node base unit DATA j i ques Interconnection p f POWER When the first two locations are connected and communicating then others can be added to the network one at a time until all Figure 5 Multi Node Fiber Optic Base Modules locations are communicating simultaneously Continue this practice for each additional I O station required 11 EOTec 2000 Multi Node MX Multiplexer User Manual Select VO modules to provide analog data 4 20mA or 0 10Vdc or digital data dry contacts I O links All 16 channels can be of the same I O type or you can combine all three module types in one module stack See the MX Multiplexer Hardware section in Chapter 2 for more information on module specifications Multi Node 4 20mA 0 10Vdc Dry Contact Input Fiber Optic Base Input Output Input Output Relay Output MAOLA TPA MR LT cos rs qe Figure 6 Multi Node Modular Solution For proper network communication each Input Module must have a unique Module Address This address can then be used to match Output Modules to this same address This match is created by setting internal s
21. switch marked SW1 Figure 22 As shown in Figure 23 there are 4 backplane I O communication REDES DS channels I O 00 01 10 11 Using Table 3 set the Channel OPTICAL FIBER BASE LINK Select Switches of each I O Module to a different selection This 4 creates a unique communication channel between Multi Node Base and the 4 possible I O modules that can be combined to create a module stack or Multi Node Station When an I O module is attached to a Multi Node base a corresponding Module Status LED will light on the Base module These LEDs or Diagnostic Indicators can help to install your I O network correctly All modules attached to the base must select a different channel If two I O modules have the same selection the base module will be confused and module LEDs will erratically flash red and green at the same time See Chapter 3 2 4 for more information on Channel Selection Figure 23 Channel Select Analog I O Interconnection BUS O a O D 3 h E DM Z a EL lt a oO 27 EOTec 2000 Multi Node MX Multiplexer User Manual 2 2 6 Current Voltage Conversions Using Analog Data Links All Analog Data Links are scaled properly to be compatible for current to voltage or voltage to current measurement conversions To make conversions between two analog data links at the same location or in two separate locations simply set the Module Addresses for both the Inp
22. 1 in the Control Room which now can be measured at Station 3 on Module O1 at Port 1 The I O Function for Module Address FC Hex has now been completed MXBMN Remote Station 3 Channel Output Port Mapping Binary LE ID Module Address Binary SVVH HEX Er EEEE E eE EE KAENI EZARREN we farao f d Input Port 3 is Mapped to Output Port 1 Table 29 Example 2 Remote Station 3 Switch Settings 50 EOTec 2000 Multi Node MX Multiplexer User Manual Configuration Work Sheet While it might be difficult to run back and forth between the 4 locations to setup this entire fiber optic network it may be simpler to add an additional I O Function in the field like the one explained here in Example 2 To assist in this effort the configuration worksheet used in Example 1 can be used again to add the additional I O Function as shown in Table 30 Use the I O Type field to enter the Dry Contact Closure model numbers MXCC xPx for each I O modules which is attached at that particular station Using Module Address field enter a unique address Hex for Input Module added at the Control Room In the Function field assign an incrementing I O Function number to each Input Module in this case 4 For all Output Modules use this same field to associate each Output Module which shares the same Module Address with the Input Module in the Control Room You now have a wiring list showing all the I O connections throughout your fiber opt
23. 2 will be solid green When the input signal is connected to Port 2 of the Input Module the Port 2 LEDs for the Input Module in the Control Room and the Output Module at the remote location will both turn solid green when the dry contacts are closed This indicates a proper Dry Contact Closure signal is entering the fiber optic network at the Control Room and is exiting the network at Station 2 The I O Function for Module Address FC Hex is still functional but has still not yet been completed Since both the input and the output signals are using Port 2 the default Output Port Mapping settings can be used see Table 28 Note that Port 2 is marked in yellow to match the color coding in Figure 38 There will be one dry contact signal connected at Port 2 of Module 11 in the Control Room which now can be measured at Station 2 on Module O1 at Port 2 Jie Remote Station 2 Channel Device Output Port Mapping Binary Select ID SW Module Address Binary SW HEX Lo EE ES EE MX4201P2 H meco Sw ME EO KE p Sws 1 1 11o W7 Input Port 2 is Mapped to Output Port 2 default Table 28 Example 2 Remote Station 2 Switch Settings Remote Station 3 Moving to Remote Station 3 as shown in Figure 38 the output from the Control Room Port 3 input signal can be configured There is already another I O Module attached to the Multi Node Base at this station so the Channel Select switches for this 2 Port Output Module MXCC OP2 must chan
24. 25V Quantity1 0 5A 125V Replacement fuses can be purchased from your Schurter distributor Part numbers 1 25A 3403 0167 11 0 5A 3403 0163 11 EOTec 2000 Multi Node MX Multiplexer User Manual Specifications Input Power Range Voltage Input 15 to 30VDC Input current 0 2A min to 1 25A max 0 to max I O Recommended Supply 24Vdc 40W Screw Terminals Pluggable Cage Clamp Screw Terminal Blocks 12 to 24 AWG ELECTRONICS N f CE marking per EN61326 1 T Weight lt 9 oz Enclosure Material Polyamide Flammability Rating UL 94V O re ESTE dala Input Fuses Quantity 2 1 25A 125V Quantity1 0 5A 125V Replacement fuses can be purchased from your Schurter distributor Part numbers 1 25A 3403 0167 11 0 5A 3403 0163 11 There are two versions of the Multi Node base which can be purchased The MX Base Multi Node MXBMN certified for use in hazardous locations both in North America and Europe The MX Base Multi Node Non Hazardous MXBMN NH has identical specifications but is not certified for use in any hazardous area Since each MX Multi Node Base can be connected via optical fiber to two other base stations two different transceivers can be selected to meet the fiber type and optical budget required to reach each location Your fiber optic network may require a multi mode transceiver with an 8db optical budget to reach one location while a single mode transceiver with a 14db optic
25. 43 Module Removal sies neo ee da oi Ge eed E N N De N Ges Ge ee so oe ne ei 53 FURAN AA FG ole oe AA EO ce ence ge vce eo EE EE EE EG 55 PUB liter PMC AGC JJ 55 ES EE HE EE AE N EE GN EE NE EN 55 Table of Tables Table 1 ESPN 14 Table 2 Default Port Settings oase ss kes Eg ads ee oos oi ee oes ode as RE ei ee Ge ae ee ee de 16 Table AIO 0 Channel Sell oo ER ER N EE a a ai 27 Table 4 DENNE ea Ge GR Ge a EGO Ge GE Ge ee 33 Table 5 PN CON NG 34 Table amp NANSEN 36 Table 7 MABMN Ne DO ea eee ana ad aa he nn nanas ue 36 Fible NN 37 FR NENNE 38 Table T0 RENN 40 Table 11 Module Address Assos a EEEE GR ee eg GR Re 40 Table 12 Output Port Mapping Default Settings ses 42 Table 13 Output Port Mapping ASSOCIATION ccccesecccssseccceesceccesececeeecessuaececsuucesseuecesenecessegecessuecessenees 42 Table 14 1 to 4 Output Port Mapping ss ee GEE ee SG Ge ke Ge ee ie ei di ev GE be ok oe GE 42 Fable 15 1 to 16 Output Port Wid DING ren 42 Table 16 Split Output Port Mapping sissies ses ede oe ee Ged Di Oe ee Re ek Oe Ge ee Ge ed Ge ed ee 43 Fable 17 Example 1 Ultra Parts Required scsssisincscrsdsuvacadabtnawossaetnainansdveandeavannaaarennbesiceteesadaddsasvadabaeatenwrineseas 43 Table 18 Example 1 Additional Parts Required ss 43 Table 19 Example 1 Remote Station 3 Switch Settings ss 44 Table 20 Example 1 Control Room Switch Settings ss 45 Table 21 Example 1 Remote Station 2 Switch Settings ss 45 Table 22
26. AG ee de de ee de AR AR AG ee Ee 22 Figure 19 MX010 IP Mating CONNECTIONS sies sesse se ee ee ee AE ee ee AR ee ee ee ee ee ee ee AR ee 24 Figure 20 MX010 OP Mating Connections se ss se see ee ee ee AE ee ee AE ee ee ee ee ee ee ee AR ee 26 ev 27 Per 27 Figure 23 Channel Select Analog VO osse Ge ER Ee Ee EEN Ge iN Be ee ee ee ed se Ge ee 27 Foure 24 Ge EE PAIN see EE EE ee EE Ge en a tt EE 28 VE CONSO Table a EE ee 28 Figure 26 MXCC IP Mating Connections cccccsccsscccscccseccsccesccesecsecesecesesasesseessecesecesceesecesecesecasseaeeeaes 31 Figure 27 MXCC OP Mating Connections rrrnnrrnerrnnrnnnennnvnnnvnnnennsennsrnnsnnnvennsnnnsennrnnnennnennsrnnnennsennsennsnnnsener 33 EU SNE 33 PG ES EEE DE en GR EE ER Ee 33 Figure 30 Channel Select Digital 1 0 sees een Ge EE de ee dae de eo Ge GE ee er de 34 EOTec 2000 Multi Node MX Multiplexer User Manual FEET NN NN 36 FIGURES IDE EEE EEE ee Gee 37 Fe 33 Master NN 37 Figure 34 1 O COMMUNICATION Channels issie is ed Re Es Ee N Ge oe ee Ge Ee ee ae ee vs 38 Figure 35 Module Address Switches ressens dee dee Ee ee RE ee ee Ee 39 Figure 36 Output Port Mapping Switches sees see ee ee ee ee ee ee ee ee RR ee ee Ee ee ee ee Re ee RE 41 Figure 37 Example 1 4 20MADalsSy Ci all Varese 43 Figure 38 Example 2 Add Contact Closure and Ring sise 48 PNG 52 EU A OE QUE CCC IO EEE ne eee 52 BUT BLS CS EE EE EN EE EE 53 eure a LE ge GENE ENE ee eee eee ree 53 Figure
27. Apz ol IBULUON IP Are LUE UO 8505 UDNPEuUUD ON mm a D O a 3 ie Control Board gt N Front Cover ransceivers 4 Guide Rails Figure 8 Mating Connections Figure 10 Module Assembly 15 EOTec 2000 Multi Node MX Multiplexer User Manual 2 1 4 MX Multi Node Base Operational Settings Up to four I O modules can be attached to each Multi Node Base These four modules communicate with the Base over four separate backplane Interconnection Bus I O communication channels Each channel is selected on the I O Module using a 2 position Channel Select Switch as explained further in Chapter 3 2 3 Once this selection is made the I O module is then identified by a Module ID as Module 00 01 10 11 Figure 12 The four I O Modules can be Input or Output Modules or a mixture of both Input and Output Modules locate each other over the fiber optic network via a Module Address Four 8 position Module Address switch banks can be shown in Figure 12 SW1 SW2 SW3 SW4 Each connected Input Module must select a different address using the 8 position Module Address Switch Figure 11 When using 8 switches a total combination of 256 different addresses can be selected Switch on to select a I value or switch off to select a 0 value An Output Module is matched with an Input Module by selecting the same Module Address Multiple Output Modules can be connected to communicate to a single Input Mod
28. ELECTRONICS Nuclear Sensors amp Process Instrumentation EOTec 2000 Multi Node MX Multiplexer User Manual for the Fiber Optic Base Original Instructions This page intentionally left blank EOTec 2000 Multi Node MX Multiplexer User Manual Table of Contents BAIS OF CONLC IVES OR EE EE EEEE en ton nel De dan cop iii Go 3 De 4 TapE OR PADES EE EE EE AS 5 SN 7 Le MONNA 9 1 1 Multi Node Communication Method iss ss GE ciudad iar e ge Ge ve Ee GE eN EIn EAE Es be ee ee Pe 9 1 1 1 Serial or Daisy Chain Communication Method sesse EE EG ee ee ke GN be ERG eb ek be de ke n bee tonte 9 112 Ring OF Redundant COMMUNICATION Method sies es es GE ee Ge EE Se A A Ee Ee be ee ES GN Ee tes 10 dil FD BON 40014910 2 0 n ENE de EEE ENE NE Ge 10 1 14 Power Fault Management Ese insek SN se de eg ie di ee es oi Ge eg ee Ge ed GE oa od ee Ge Ge esse 10 1 2 FUNN MSN 11 2 EOTec MX Multiplexer Hardwale aars 13 2 1 MX Multi Node Base Products Designed for Industrial Applications ee ee ee ee ee EE 13 2 1 1 MX Multi Node Base Power ConnectiOnS see ek AAR EE AR EE ee ARE ee ee ee ER Ee ee ee AR Ee ee ee AR ee ee ee ee ee ede RE 15 2 1 2 MX Multi Node Base Remote Alarm Connections sense 15 2 1 3 MX Multi Node Base Module Disassembly Ee ee ee Ee ee ee AR Ee ee ee AR ee ee ee Re ee ee ee RE 15 2 1 4 MX Multi Node Base Operational Settings ses 16 2 1 5 MX Multi Node Base
29. MX420 OP2 MX420 OP4 SW1 O O Channel Select SW1 1 SW1 2 MX Digital Data Link Modules Dry Contact Closures Module Type Model Number s MXCC MXCC IP2 MXCC IP4 MXCC OP2 MXCC OP4 SW1 O 0 Channel Select SW1 1 SW1 2 61 EOTec 2000 Multi Node MX Multiplexer User Manual 6 Product Dimensions MX Multi Node Base Modules Model Numbers MXBMN MXBMN NH 3 9 99 4 5 114 Inch mm Model Number s MX010 IP2 MX010 IP4 MX010 OP2 MX010 OP4 MX420 IP2 MX420 1P4 MX420 OP2 MX420 OP4 MXCC IP2 MXCC IP4 MXCC OP2 MXCC O P4 3 9 99 4 5 114 Inch mm 62 EOTec 2000 Multi Node MX Multiplexer User Manual 7 Glossary Glossary of MX Multiplexer Terms Binary A numbering system which uses a base of only two digits 0 amp 1 It s commonly used with computers and digital communications Binary Notation Binary Notation is used for expressing the difference between On I and Off 0 In this manual it is used to describe the current state of switches such as the ones used on the I O Modules for Channel Select and on the Multi Node Base for Module Address and Output Port Mapping communication channel on the Interconnection Bus with the Multi Node Base Channel Select Switch Two position switch used on all MX Multiplexer I O Modules Used to select 1 of 4 possible communication channels on the Interconnection Bus connect with the Multi Node Base For the Multi Node MX Mult
30. MXBMN RECEIVE STATUS Local receiver communication is good Marked Fiber 1 RX Fiber 1 transceiver not receiving data Loss of fiber optic light 1 Swap Fiber 1 transceiver with known good one Solid Red 2 Check transmit signal of transceiver on other end of Fiber 1 cable 3 Check Fiber 1 cable for a break or low optical power 4 If options 1 2 amp 3 do not work replace MXBMN ie Fiber 1 receiving bad data 1 Verify optical fiber type matches the transceiver type 2 Verify optical fiber and signal strength are both good k 3 Swap Fiber 1 transceiver with known good one 4 5 Flashing Red Swap transceiver on the other end of Fiber 1 cable If options 1 4 do not work replace MXBMN When Fiber 1 transceiver is plugged in the RX LED should be light 1 Swap transceiver Fiber 1 with known good one 4 If swapping Fiber 1 transceiver doesn t work check fuse F1 on the Control Board Replace if blown 5 If options 1 amp 2 do not work replace MXBMN RECEIVE STATUS Local receiver communication is good Marked Fiber 2 RX Fiber 2 transceiver not receiving data Loss of fiber optic light Swap Fiber 2 transceiver with known good one Check transmit signal of transceiver on other end of Fiber 2 cable Check Fiber 2 cable for a break or low optical power If options 1 2 amp 3 do not work replace MXBMN Solid Red v s Fiber 2 receiving bad data 1 Verify optical fiber type matches the transc
31. N N Oe d Station VO Module More MXBMN Base Module pu apping Function Describe Connection Pr men De 3 Output Mate Control Room Port Mapping n a TTT eee Pott pp pp S S d P pp Ep pb pp Port Mapping Defaults Port 4 11 Port 3 10 Port 2 01 Port 1 00 Hexidecimal E4 Module Address Default Binary 0000 0000 Hexadecimal 00 Table 23 Example 1 Network Configuration Worksheet 3 2 7 Network Installation Example 2 This example expands on the 4 20mA Daisy Chain network explained in Example 2 by adding a Dry Contact Closure application with a Redundant Ring fiber optic network configuration As shown in Figure 38 a 4 Port Dry Contact Close Input Module MXCC IP4 has been added to the Control Room This allows 3 switched signals such as a shut down operation to be sent back to the 3 remote stations All 3 of the remote stations have 2 Port Output Modules MXCC OP2 where these switch signals can be used in the remote areas As with Example 1 the same assumption that Fiber Links 1 2 and 3 are no more than two kilometers still applies and multi mode optical fiber will be used in these 3 fiber links However in this network application it is also assumed that all stations are connected from the Control Room out in one continuous direction until Remote Station 3 is reached Therefore to create a Ring network a new fiber link or Virtual Link will need to be added from Remote Station 3 back to the Cont
32. O module a Module ID is chosen for that module see Table 9 which will be used later in Chapter 3 2 to explain system communication Since each I O Module is shipped from the factory with a default setting of OO it is important to ensure this switch is changed when adding more than one I O Module to the base module MX MULTI NODE OPTICAL FIBER BASE Interconnection Interconnection 1 Interconnection BUS I 7 d s ME ET JE METS P Figure 34 I O Communication Channels Binary Notation To help in the discussion of channel selection it may be of value to have a quick review of Binary Notation Binary is a two digit numbering scheme which is used in describing the current state of a switch Since a switch is either On 1 or Off 0 binary notation is well suited to describe how to set SWI on each I O Module SVVI has two switches Each of these switches has two positions On Off so with two switches we can have 4 different selections as shown in Table 9 SW1 Channel Select Switch JO Channel Module ID 000 Module 00 001 Module 01 010 Module 10 YO11 Module 11 Table 9 Channel Selection Module Status When an I O module is connected to the Multi Node Base a Module Status LED will light up Each of the four I O channels shown in Table 9 has a status LED on the front of the Multi Node Base Given the status of the I O module connected there will be a status reported by these LEDs E
33. TS interconnection MXCC OP Form C Relay Output Foy UOL LLO Z FO UG LUO Ports 344 Only Available on 4 Port Model MXCC OP4 COM pasoja AJEULIOR Fon uadg Ae uuo Figure 27 MXCC OP Mating Connections 2 3 3 Digital Data Link Operational Settings Address Settings for Digital Data Link Use a small screwdriver to press on the latches Channel Select A two position DIP switch SW1 is used indentations at the top and bottom of the front housing to select a backplane channel to communicate with the cover Slide housing forward to open Multi Node Base module in a single module stack Do not set two I O modules in the same module stack to the same channel setting Each I O module in a module stack must have a different Channel Select to function properly The 4 possible channel selections are shown in Table 4 SVV1 Channel Select Switch Figure 28 Latches Figure 29 Channel Switch 10 ON OF um o ON Table 4 Digital I O Channel Select An I O communication channel must be selected for each Digital Data Link Open the module as shown in Figure 28 using a small screwdriver to release the front cover latches at both the top and bottom of the module Slide the housing front cover forward to reveal a small 2 position DIP switch marked SW1 Figure 29 33 EOTec 2000 Multi Node MX Multiplexer User Manual As shown in Figure 23 there are 4 backplane communication han Any aan pl sgh at DATA channel
34. TUS Power is good Marked IN2 Power input is lt 15Vdc or gt 30Vdc Solid Red 1 Verify power input is 215 to lt 30Vdc 2 If both power input is correct replace MXBMN Power has not been supplied Off 1 Verify power input is 215 to lt 30Vdc 2 Check fuse F2 on Optical Board Replace if blown 3 If both power and fuse are good replace MXBMN TRANSMIT STATUS Fiber 1 transceiver is good and plugged in Marked Fiber 1 TX Fiber 1 transceiver is not acknowledging it is plugged in Solid Red 1 Swap Fiber 1 transceiver with known good one 2 If swapping transceiver doesn t work replace MXBMN When Fiber 1 transceiver is plugged in the TX LED should be light Swap transceiver Fiber 1 with known good one Off If swapping Fiber 1 transceiver doesn t work check fuse F1 on the Control Board Replace if blown If options 1 amp 2 do not work replace MXBMN 56 EOTec 2000 Multi Node MX Multiplexer User Manual TRANSMIT STATUS Fiber 2 transceiver is good and plugged in Marked Fiber 2 TX Fiber 2 transceiver is not acknowledging it is plugged in Solid Red 1 Swap Fiber 2 transceiver with known good one 2 If swapping transceiver doesn t work replace MXBMN When Fiber 2 transceiver is plugged in the TX LED should be light Swap transceiver Fiber 2 with known good one If swapping Fiber 2 transceiver doesn t work check fuse F1 on the Control Board Replace if blown If options 1 amp 2 do not work replace
35. UGNISUUGT OP Ports 344 Only available on 4 Port Model MX010 0P4 PORT 2 PORT 3 PORT 4 Figure 20 MX010 OP Mating Connections The connections to a 0 10Vdc Output Module are shown in Figure 20 Power is connected through the 10 2 Interconnection Bus when attached to the MX Multi Node Base Each Pluggable Screw Terminal Block serves as a 0 10Vdc process management output or port A 0 10Vdc output can be created by connecting to each port as shown in Figure 20 All MX Multiplexer I O Modules are hot pluggable when used in a non hazardous area Damage will not occur to either the I O Module or the Multi Node Base Module when connected disconnected while power is on However do not separate the internal board assembly from the housing while power is on as this may damage the electrical circuits of this board For safety reasons always remember that connecting disconnecting modules in a hazardous area 1s not permitted 26 EOTec 2000 Multi Node MX Multiplexer User Manual 0 10Vdc Output Regulatory Markings The EOTec MX Multiplexer modular 0 10Vdc Output products MX010 i OP2 and MX010 OP4 comply with the essential requirements of the following applicable European Directives and carry the CE marking accordingly EMC Directive EN 61326 1 2006 M For Safety requirements these products comply with Canada CSA C22 2 ra n No 142 Process Control Equipment APPAOVED These products have been assessed against and found to be i
36. a aa dance anne nee a cette 34 3 1 2 Consider the Number of I O Connections cccccccccccccceeceeecceeeeceeesssseseeeseseseeseeseeseeeeeeeeeeeeeeeeceeeeeeceeeeeeeeeeeentneeeeeeeneteg 35 3 1 3 Consider Where the I O Signals Connect EE EE ee ee ee ee ee ee ee 35 3 4 4 Consider Adaress Scheme je 35 215 NNN NNN 35 3 1 6 Consider USING a Remote AlaFM eeue ek RR AR AR Ee AAR Ee ee ee AR Ee ee ede Ee ee ee AR Ee ee ee ee RE ee ee AAR ee ee ee EE 35 5 2 Network Configuration and Installation ss 36 32d PORT TONN PG 36 32 2 Master Slave UR CL EEE EEE ENE me ten 37 3 2 3 Channel Select Switches ccccccsssescccccneesececcncenseecscneeseeeesaenseeesssenseeeeesaeseesessauseesessaunesecessauasecsssaunseesssauaseceseesesaaegs 38 3 424 Module Address SV 39 325 Output Port Mapping SWILERES mea matant EE Ge ie ee ee ee ie aN TENE E R 41 34D Network instaladon 260100 DIR eee eee Ge Oe EEE Ee Re n ie test tt DE 43 SL MNetworkinstalaltion Example LP 47 EOTec 2000 Multi Node MX Multiplexer User Manual 3 3 Module Installation and Removal ees sesse ee ee dee ee de ee ed dee ee dd ee ee dd ee ee Ed dee ee Ed ed ee ee GE 52 Ad ENN 52 3 9 2 BUS Covers and End CIlAMPBS siese eo Ese Ge oe Ee ge ee ge ge ie ek ge ee ee ge ed Ee ede geo ee ee ei es De eg 52 i ie N RETO AE ee NEE EE EE N EER ER EE stament estem 53 3 4 BIE peke TC AON EEE ee 54 42 NONNE MOO UE dee ER n de Ne ee enteses 55 4 1 BIE ef oss Ne DEd NE ET eee EE RE ee ee ee
37. al budget might be required to reach another location To support these network requirements Ultra provides the transceivers as separate items To support varying customer needs Ultra Electronics NSPI offers the following Small Form factor Pluggable SFP transceivers to meet your specific needs See Table 1 to select SFP transceivers SFP Transceivers Part Number Optical Fiber Type Optical Dynamic Range SFP13 100M2K Multi Mode 1310nm 8db 62 5 125um fiber 2k SFP13 100M40K Single Mode 1310nm 29db 9 125um fiber 40k SFP15 100M80K Single Mode 1550nm 29db 9 125um fiber 80k Table 1 Select SFP Transceivers SFP13 100M15K Single Mode 1310nm 14db 9 125um fiber 15k All Small Form factor Pluggable SFP transceivers are IEC 60825 1 Class I Laser compliant Class I Lasers are safe under reasonably foreseeable conditions of operation including the use of optical instruments for intra beam viewing IEC 60825 1 Class 1 Laser Product FDA 21 CFR 1040 10 amp 1040 11 14 EOTec 2000 Multi Node MX Multiplexer User Manual 2 1 1 MX Multi Node Base Power Connections Connecting power to the Multi Node Base module can be done with ease As seen in Figure 8 DC power is connected through a removable cage clamp terminal block which will accept 12 to 24 gage wire Wire a single power supply or two redundant power supplies to meet your specific needs at terminals 1 2 3 amp 4 See Figure 8 The user is responsible for providin
38. ally at the Multi Node Station Ultra also provides some remote features to help diagnose failures when you re not in that particular location features such as contacts to alert you when a failure has occurred in the network or the Global LED indicator which tells the user there is a problem with a module stack or MX Multi Node Station in another area of the optical fiber network Fiber Optic Analog Digital Network Controller Data Links Data Links Multi Node 4 20mA 0 10Vdc Dry Contact Input Fiber Optic Base Input Output Input Output Relay Output MxOLO TP4 siese F er Figure 44 Advanced Figure 45 Intermediate Figure 46 Simple 55 EOTec 2000 Multi Node MX Multiplexer User Manual All MX Multiplexer modules fall into 3 basic categories of diagnostic features The MX Multi Node Fiber Optic Base or MXBMN is considered to have Advanced LED Diagnostics and provides the highest level of diagnostics available with the MX Multiplexer product line The MXBMN shown in Figure 44 not only tells the user it has good power and transceiver connections but can also notify the user of an input conflict a device conflict or an abandoned I O module For list of all Multi Node LED diagnostics see Table 32 The MX Analog Data Links shown in Figure 45 have intermediate level diagnostics They can inform the user when data is flowing between input and output ports but can also identify possible sensor failures by providing over range and u
39. an be repaired or replaced An off condition has also been provided so that in the case of an unused I O port the associated LED will remain off The scale for a current to voltage conversion is ImA 0 625Vdc or multiply the current input by 0 625 to calculate the proper voltage output The scale for a voltage to current conversion is 1 Vdc 1 6mA or multiply the voltage input by 1 6 to calculate the proper current output See Figure 25 for appropriate conversion scale 4 20mA Input Figure 24 Conversion Pair ER European Standard American Standard 4 20mA 3 36mA4 3 52mA 3 8mA 4mA 20mA UNDER RANGE NORMAL OPERATION SATURATION OFF FLASHING RED 0 10Vdc 400mV 300mV 125mV OV 10V 20 5mA 4 20mA IVER N die or SATURATION 10 3125V 0 10Vdc 4 20mA 4 20mA 0 10Vdc 0 125 0 1 2 3 a 5 6 7 8 9 10 10 3125 0 10Vdc Figure 25 Conversion Table 28 EOTec 2000 Multi Node MX Multiplexer User Manual 2 3 Digital Data Links Products Designed for Reliability Digital Data Links are also known as dry contact closures When the two signals going into an input port of an Input Module make contact shorted together they activate a relay on any Output Module at that same Module Address located anywhere in the fiber optic network Because these devices only have two states they are commonly called Digital Data Links These modules can be added to the MX Multi Node Station to con
40. ation aie t coup e ou que la zone est connue comme non dangereuse Copyright amp Trademarks Copyright 2014 ULTRA ELECTRONICS NSPI All Rights Reserved EOTec 8 is a registered trade mark of ULTRA ELECTRONICS NSPI EOTec 2000 Multi Node MX Multiplexer User Manual 1 Introduction This manual describes how to use the MX Base Multi Node MXBMN fiber optic modules in conjunction with the EOTec 2000 Multi Node MX Multiplexer product family The MXBMN or Multi Node Base Modules are specially designed to provide deterministic serial daisy chain or ring redundant communication for both analog devices such as 4 20mA or 0 10Vdc and digital devices such as dry contact closures for your industrial field applications Multi Node I O devices are swiftly being adopted by the industrial automation and control industry when seeking an inexpensive solution for I O network communication requirements Industrial applications often demand rugged robust equipment that can provide high reliability in settings far removed from a comfortable climate controlled office environment The EOTec 2000 Multi Node MX Multiplexer can meet all of these needs The EOTec MX Multiplexer fiber optic technology provides many advantages for industrial control applications These include EMI RFI immunity the ability to run fiber optic cable through hazardous areas and the ability to connect long distance communication links Typical modem devices attached to a ne
41. ched to a module of the same device type Analog or Digital 2 Has one Input Module with at least one Output Module at the same Module Address The I O module associated with this LED has no matching I O Module at this same Module Address 1 If this is an Input Module select the same Module Address on the Output Module you wish to communicate with 2 If this is an Output Module select the same Module Address on the Input Module you wish to communicate with The I O Module associated with this LED is using the same Module Address as another I O Module with a different device type 1 For an Analog Module locate the Digital Module with a solid red LED and change the Module Address to another setting This can occur in the same module stack or between two module stacks in two different Solid Red locations For a Digital Module locate the Analog Module with a solid red LED and change the Module Address to another setting This can occur in the same module stack or between two module stacks in two different locations The Input Module associated with this LED is using the same Module il F Address as another Input Module in the optical fiber network Flashing Red 1 Select an unused Module Address for the Input Module displaying a 7 flashing red LED Any associated Output Modules will also need to i change to this new Module Address selected No I O Module has selected this backplane channel to communicate over Off the Inter
42. communicate the Multi Node Base Interconnection Bus An MX Multiplexer Input Module is used to connect a 4 20mA 0 10Vdc or Dry Contact Closure signal into the MX Multiplexer fiber optic network Channel communication channel on the Interconnection Bus to talk to the Base Module I O Function An I O Function is created by setting one Input Module and one or multiple Output Module to the same Module Address All modules using this Module Address are considered to be part of one I O Function An LC connector is a standard type of termination used on optical fiber cables These connectors plug directly into SFP transceivers used on the Multi Node Base Module 63 EOTec 2000 Multi Node MX Multiplexer User Manual Module Address Module Address Switch Module ID MXBMN Output Module Output Port Mapping Output Port Mapping Switch Publisher Subscriber A separate Module Address is selected for each Input Module in the network No other Input Module in the optical fiber network can have the same Module Address This same Module Address is then selected for an Output Module at the location where this signal is needed Located on the MX Multi Node Base Module is an 8 postion Module Address Switch associated with each of the 4 I O communication channels of the Interconnection Bus A total of 4 I O Modules can be connected via this bus so there are four 8 postion Module Address Switches on every Multi Node Base Module Ev
43. connection Bus to the Multi Node Base This is an invalid state caused by setting two I O Modules to the same Channel Select setting Solid Red MASTER STATUS Marked Master MODULE STATUS Marked I O 00 I O 01 I O 10 I O 11 Flashing Red 1 Choose a different Channel Select setting for each I O Module 58 EOTec 2000 Multi Node MX Multiplexer User Manual MX Analog Data Links Intermediate Diagnostics am MX010 IP2 MX010 IP4 MX010 OP2 MX010 OP4 Model No MX420 Mixaz0 1P2 MX420 IP4 MX420 OP2 MX420 OP4 Power has not been supplied Off Check power light on MXB If off go to MXB diagnostics Check power output from MXB on interconnection BUS see Figure 17 If both power input and fuse are good but output bad then replace MXB If both power input and fuse are good but output bad then replace MXB Check I O module fuse Replace if blown If both power input and fuse are good but I O module not energized then replace I O module Input or Output is within normal operation See Figure 25 PORT 1 4 Over Range Input or Output is above normal operation Solid Red 1 Check input sensor or output device for proper functionality 2 If external devices are functioning properly then swap Input or Output Modul with known good module Under Range Input or Output is below normal operation 1 Check input sensor or output device for proper functionality a Fl losing Red 2 If external
44. de Base from off to green See the diagnostic dashboard in Chapter 3 4 for more information about LED indicators Figure 33 Master Slave Jumper 37 EOTec 2000 Multi Node MX Multiplexer User Manual If a ring configuration is setup and no Multi Node Base has been selected to operate as the master the Global LED will turn red on all Multi Node Bases connected in a fiber optic ring network Select one module as the Ring Master and this type of fault will be eliminated When more than one Multi Node Base has been selected as a Master there will be additional virtual links breaks in the fiber optic line of communication If this occurs Module Status lights should be flashing green because some input and output function cannot identify a mating module at their same Module Address This type of diagnostic fault is termed an Abandoned I O When multiple masters cause this condition identify the additional master module s and by changing the unneeded masters into slave modules this fault will clear 3 2 3 Channel Select Switches Inside each I O module can be found a two position switch marked SW1 This switch is used to select a communication channel with the Multi Node Base Module As shown to the left on Figure 34 there are four I O communication channels I O 00 I O 01 I O 10 I O 11 to support the 4 possible I O Modules which can be attached to each Multi Node Module Upon selecting a communication channel for each I
45. de Base meets the requirements for CE marking per EMC Directive requirements for CE marking per EMC Directive EN61326 1 2013 and CISPR 11 2009 A1 2010 EN61326 1 2013 and CISPR 11 2009 A1 2010 Product for use in Hazardous Locations pending CE CE 18 EOTec 2000 Multi Node MX Multiplexer User Manual 2 2 Analog Data Links Products Designed for Flexibility Analog Data Links can be added to create an MX Multi Node Station to measure control or report status to and from a local area to multiple remote sites Analog Modules are provided in either a 4 20mA or 0 10Vdc version and are available in either 2 Port or 4 Port varieties A maximum of four modules can be stacked together with an MX Multi Node Base MX Multiplexer I O Modules can be stacked together to provide from a minimum of 2 ports one 2 Port module to a maximum of 16 ports four 4 Port modules to support your solution Analog Data Links are capable of either current to voltage or voltage to current conversions to meet your specific needs Figure 25 Analog Data Link I O modules update the MX Multi Node Base module at a rate of 57 6 KHz 17 36us The MX Multi Node Base in turn updates the fiber optic network every 2 3 milliseconds with the most recent I O data gt High Performance Reliable Technology o Update Rate 57 6KHz independent of number of modules or channels utilized 0 01 25 C Reference Accuracy 0 08 50 C Change Ambient Temperature Effect 16 Bit
46. devices are functioning properly then swap Input or Output Module with known good module ran Normal operation with no connection See Figure 25 MX Digital Data and Communication Data Links Simple Diagnostics Model No MXCC MXCC IP2 MXCC IP4 MXCC OP2 MXCC OP4 Power has not been supplied Off Check power light on MXB If off go to MXB diagnostics Check power output from MXB on interconnection BUS see Figure 17 If both power input and fuse are good but output bad then replace MXB Check I O module fuse Replace if blown If both power input and fuse are good but I O module not energized then replace I O module Input or output port has an active data signal Input or output port has no active data signal 1 Check input or output device for proper functionality 2 If external devices are functioning properly then swap Input or Output Modul with known good module 59 EOTec 2000 Multi Node MX Multiplexer User Manual 4 3 Interrupting Remote Relay Diagnostics The Multi Node Base provides a relay that can be connected to a remote alarm There are 2 fault conditions that can set off an alarm Also see section 2 1 2 for more information on remote alarms MXBMN Multi Node Base Module Remote Alarm Model No MXBMN MXBMN NH Failure Action A unit with this fault has a power fault IN 1 or IN 2 LED has turned red or both LEDs are off Refer to MXBMN Diagnostics in Chapter 4 2 for further tr
47. ding at the same Module Address can be considered as one I O Function Establish every I O device working at one address or one function before moving to the next address and the next function 3 2 5 Output Port Mapping Switches Output Port Mapping Switches are only used by Output Modules When configuring an Input Module these switches should be left in the default position Table 12 as the Multi Node Base controller ignores these settings Inside the Multi Node Base Module are four 8 Position j Module 00 switch banks marked SW5 SW8 Figure 36 These T o ho EE SW5 switch banks are associated with the four possible I O ut EEE eigde Module which can be attached to the Base AR Es OG Output Port Mapping _ Switches rrr EET 0 METTET ll UDE TT TT TE Each 8 Position switch bank is split into 4 parts for the 4 Ton AE ee 3 possible output ports on each Output Module Each o ninja EE ape output port is represented by 2 switches as shown in ae al Table 12 Each set of 2 switches works similarly to a oar ae telephone switch board in that any input port can be patched through or connected to any output port Setting the switches of the desired input port connects it to the associated output port see Table 12 Remember that each Module ID has a Module Address and an Output Port Mapping 8 Position switch bank associated with it This means Port Mapping is only used to route input signals from the one Input Module to on
48. e ae 55 4 2 LOGO EE UD at oa By oy BMD JF NOS CCS pee eee a OE 56 4 3 Interrupting Remote Relay Diagnostics sise 60 So iS ae OE OE RE OE N OE N 61 0 ee ie MR ed OR IE RE EE gel 62 Ze GOSI a da E E de N Ge ee ae 63 o oe RE RE ER AE EO ets 65 Table of Figures Figure 1 Multi Node Daisy Chain Communication esse see ee ee ee ER ee ee ee ee ee ee RR ee 9 Figure 2 Multi Node Ring Communication see ER ee ee ee ee Re ee Re ee RE ee ee ee RR ee RE 10 PIOUS MINNET 10 ETT MINN 11 Figure 5 Multi Node Fiber Optic Base Modules sise 11 Figure 6 MultNode Modular SOR 12 Figure 7 Multi Node 1 O Network ss es ER a ed RD de ee Ge Ge GEE AA RD EG Ge GN ee ie 12 FIC ULE 8 Nating COMM SCIONS ie ei ie RE RE Ge ee NE 15 PICS 9 BS OAC ES ee ee Ge GE OE EE ee EG RE DR ee AE N ee soe IE ie 15 ee 10 Modules sseim DR Es EG RR RD EG DE GE Da suse AE EG De EG en metes 15 Feure CL Module NNN 16 Figure PE EN rate cs ina SEE Ee EE GE AD ie GR Oe ee Ge ENE 16 Figure 13 Output Port Mapping ss sesse se ss ee de de AE AG de de a Ge AR Ge ee de de AG AG de de ee 16 Figure 14 MX Multi Node Board Assembly sise 17 Figure 15 Control Board FUSE SO SA EG OE uen de AEO 17 Figure 16 Dual Optical Board FUSES 1 25A ees ee ee RE ee ee ee ee ee ee ee ee ee ee RA ee RR ee RE 17 Figure 17 MX420 IP Mating CONNECTIONS sesse ss se se ee de AE AA AR AG ee de de AG de de AE AG ee Ee 21 Figure 18 MX420 OP Mating Connections iss sesse ss se se ee de ee AG Ge AR
49. e with the IN Iterminals and F2 is in line with the IN 2 terminals These replacement fuses can be directly order from your Schurter distributor using part number 3403 0167 11 After following the disassembly instructions in Section 2 1 3 the fuse on the Control Board can easily be replaced as shown in Figure 15 However if a fuse is blown on the dual power input further disassembly will be necessary The two boards can be separated by pulling the two boards apart at the inter board connector shown in Figure 14 Once separated the two fuses can now be easily accessed Figure 16 1 Control Board 2 Optical Board J F Pr 9 3 canola Connector Optical Board Front Cover 5 Control Board Front Cover Figure 15 Control Board Fuse 0 5A Figure 16 Dual Optical Board Fuses 1 25A 17 EOTec 2000 Multi Node MX Multiplexer User Manual 2 1 7 MX Multi Node Base Module Reassembly The Multi Node Base can be reassembled by connecting the Control Board to the Optical Board via the inter board connector shown in Figure 14 Leave the Control Board Front Cover to the side until after installing the dual board assembly into the housing as indicated in Figure 10 The separation between these two assembled boards is important as both boards must slide into housing uses both guide rails Figure 10 Be aware that each guide rail has a top and bottom slide 4 total slides are used to insert the dual board assembly When these boards ha
50. eak Management Should a failure occur with a communication link between two stations Fiber Link 2 as shown in Figure 3 the Virtual Link opens a communication path and the two stations on either side of the break begin to initiate upstream and downstream data packets communication continues uninterrupted Once the broken link is repaired the fiber optic network returns to the original communication configuration shown in Figure 2 Remote Remote Remote Control re rr Station 1 FC FE Station2 FC pp Station 3 FC FF FE FD Room N N Aa A Master Module 1 I lt OS ep 2 ser ps Fi F2 AI AR 08 n i EER EE EER EER Fiber Link 1 Fiber Link 2 Fiber Link 3 Virtual Link Fx Module Address Hex ak Optional SFP to Create Ring Network Figure 3 Multi Node Fiber Break 1 1 4 Power Fault Management Similar to an optical fiber break is a power failure to a Multi Node Base MXBMN as shown in Figure 4 Remote Station 3 has lost power or failed to power up This unit can no longer communicate with the Control Room however Stations I and 2 can still operate properly while repairs are being conducted at Station 3 Once Station 3 is repaired the fiber optic network returns to the original communication configuration shown in Figure 2 10 EOTec 2000 Multi Node MX Multiplexer User Manual Remote Remote Remote Control FC FF Station pp Station 2 Station 3 Room
51. ed at each screw terminal block or port as shown in Figure 18 All MX Multiplexer I O Modules are hot pluggable when used in a non hazardous area Damage will not occur to either the I O Module or the Multi Node Base Module when connected disconnected while power is on However do not separate the internal board assembly from the housing while power is on as this may damage the electrical circuits of this board For safety reasons always remember that connecting disconnecting modules in a hazardous area 1s not permitted 2 2 3 The 0 10Vdc Process Management Input 0 10Vdc Input Model 2 Port Specifications Input Power Range 15 to 30VDC via the interconnection Bus from an MX Multi Node Base Module MXBMN or MXBMN NH Current Rating 50mA 24Vdc Input Impedance 7G Ohms Operating Range 125mV to 10 3125Vdc Voltage Conversion OVdc 4mA 10Vdc 20mA Scale 1Vdc 1 6mA Screw Terminals 2 0 10Vdc Process Measurement Ports Pluggable Cage Clamp Screw Terminal Blocks 12 to 24 AWG Weight lt 9 oz Enclosure Material Polyamide MXO10 IP2 Flammability Rating UL 94V 0 Input Fuse 500mA 125V Replacement fuses can be purchased from your Schurter distributor Part number 3403 0163 11 23 EOTec 2000 Multi Node MX Multiplexer User Manual 4 Port Specifications Input Power Range Current Rating Input Impedance Operating Range Voltage Conversion Screw Terminals Weight Enclosure Material Flammabil
52. eiver type Flashing Red 2 Verify optical fiber and signal strength are both good d N 3 Swap Fiber 1 transceiver with known good one 4 Swap transceiver on the other end of Fiber 1 cable 5 If options 1 4 do not work replace MXBMN When Fiber 2 transceiver is plugged in the RX LED should be light 1 Swap transceiver Fiber 2 with known good one 2 If swapping Fiber 2 transceiver doesn t work check fuse F1 on the Control Board Replace if blown 3 If options 1 amp 2 do not work replace MXBMN No Global Fault has occurred in the optical fiber network 1 No power fault Both IN 1 amp IN 2 LEDs are green 2 No fiber fault Both RX TX LEDs for Fiber 1 amp 2 are green or off GLOBAL STATUS Marked Global 57 EOTec 2000 Multi Node MX Multiplexer User Manual A Global Fault has occurred 1 Check IN 1 amp IN 2 LEDs on all Multi Node Base modules If one or both is red follow Power Status troubleshooting tips Check RX TX LEDs for Fiber 1 amp 2 transceivers on all Multi Node Base modules If one is red follow Transmit Receive Status troubleshooting tips This module has been selected as a Master Module 1 Ifthe Master select jumper is set in the Slave position and this LED is still green replace MXBMN This module has been selected as a Slave Module 1 Ifthe Master select jumper is set in the Master position and this LED is still off replace MXBMN The I O module associated with this LED is 1 Mat
53. emote Alarm MX Multi Node Base MXBMN Relay Function Fault Description Relay Global Fault No Power default Inactive Power Fault on either IN 1 or IN 2 Active Fiber break disconnect or data error on RX Active The alarm relays active state can be open or closed based on user wiring terminals 5 6 7 of the module Table 33 Remote Alarms 54 EOTec 2000 Multi Node MX Multiplexer User Manual Local Alarms Analog 1 0 Modules MX420 8 MX010 Power Status Solid Green Marked Power Port Status Input Output signal is within normal operational range See Figure 25 Solid Green Marked Port1 4 Over Range Input or output signal is above normal operating range Solid Red Under Range Input or output signal is below normal operating range er Red Normal operation with no connection Local Alarms Digital 1 0 Modules MXCC Power Status Marked Power Port Status Marked Port 1 4 Table 34 I O Module Local Alarms 4 Troubleshooting Ultra Electronics NSPI provides several solutions to help you diagnose trouble that may occur in a Multi Node MX Multiplexer fiber optic network Understanding the information in this section will greatly help you to find the root cause of the problem and resolve it quickly 4 1 Diagnosing Failure All MX Multiplexer modules have LED indicators to help you diagnose a functional failure when trouble occurs Understanding the indicators will help you identify the problem loc
54. ery I O Module set to the same Module Address will communicate across the fiber optic network Each address must have only one Input Module and at least one Output Module A Module ID is chosen for each I O Module when setting the Channel Select Switches inside each unit This selects I of 4 channels to communicate with the Multi Node Base over the Interconnection Bus This is a module number for a MX Base Multi Node module Also referred to herein as a Multi Node Base or Base Module A node is referring to a fiber optic interface point Each Multi Node Base Module is considered one node An MX Multiplexer Output Module is used to connect a 4 20mA 0 10Vdc or Dry Contact Closure signal coming from the MX Multiplexer fiber optic network Output Port Mapping is used to map an input signal coming across the optical fiber to any output port on the receiving Output Module This mapping scheme routes a specified input port to a specific output port Located on the MX Multi Node Base Module is an 8 postion Output Port Mapping Switch associated with each of the 4 I O communication channels of the Interconnection Bus A total of 4 I O Modules can be connected via this bus so there are four 8 postion Output Port Mapping Switches on every Multi Node Base Module Output Port Mapping is only used by Output Modules Input Modules associated with the I O channel selected will ignore the settings of this 8 postion switch Output Modules are available with e
55. ether either analog or digital control signals and provide noise immune communications over long distances 2 1 MX Multi Node Base Products Designed for Industrial Applications GLOBAL MASTER savas JIN COM re ESTE AE GIE gt gt High Performance Reliable Technology o Update Rate 2 3ms independent of number of modules or channels utilized o Small Form factor Pluggable SFP LC type optical connectors Industrial Design for High Reliability o Modular flexible scalable o Operating temperature range 40 to 85C o FM approved for Class I Div 2 Groups A B C amp D T4 o ATEX listed II 3 G Ex nA nC IC T4 Ta 40 C to 85 C o Standard 35 mm DIN rail mounting Optional SFP Transceivers o Select from 4 optical fiber transceiver types gt Additional Features o Remote alarm relay Form C SPDT 30Vdc IA o Local and remote diagnostic LEDs o Patch cords available to convert optical connectors to various types of your choice Specifications Input Power Range Screw Terminals C GLOBAL MASTER Weight Enclosure Material Flammability Rating Input Fuses 13 Hazardous Locations Voltage Input 15 to 30VDC Input current 0 2A min to 1 25A max 0 to max I O Recommended Supply 24Vdc 40W Pluggable Cage Clamp Screw Terminal Blocks 12 to 24 AWG CE marking per EN61326 1 Product for use in Hazardous Locations pending lt 90z Polyamide UL 94V 0 Quantity 2 1 25A 1
56. ff for the Fiber Port that is unused Es Global Green No Power Fiber fault Master Off Not Master Default Module I O 00 Off Status I O 01 Off Master LED is also still off Default unless There are still no I O modules connected yet so the Module Status LEDs I O 00 11 are still not applicable in this situation The I O 10 Off VO 11 Off l be the one Master in your Ring network No 1 0 connected configuration Table 8 Fiber Installed Figure 32 Fiber OK this module has been selected via jumper to When fiber optic cable has been correctly installed between this Multi Node Module and another Both the TX and RX LEDs will turn green When the second SFP Transceiver is installed and connected to a third Multi Node module then all LEDs for Fiber 1 and Fiber 2 functions will be green 3 2 2 Master Slave Jumper Since all Multi Node Base Modules ship from the factory set to work as a Slave Module they can be used right out of the box to form a fiber optic serial communication string or daisy chain network without changing this setting as shown in Figure In this configuration the master LED on each Multi Node Base will be off see Figure 32 To setup a fiber optic redundant ring network change the Master Slave Jumper Figure 33 on one module to perform the Master function to control ring communication as shown in Figure 2 A module set to the master setting will turn the Master LED on the Multi No
57. g a 15 to 30Vdc power source to power each MX Multiplexer module stack Ultra Electronics NSPI does not sell a DC power supply for the MX Multiplexer product line 2 1 2 MX Multi Node Base Remote Alarm Connections The remote alarm relay activates whenever a Global Alarm occurs It can be wired directly to the front of the Multi Node Base Module to activate as either a closed or open relay To make this selection simply wire your alarm to either the Open on Alarm terminals 5 amp 6 or Close on Alarm terminals 6 amp 7 terminal connections See Figure 8 Alarm conditions are No Power and or Fiber Break disconnected For more information on alarm conditions please see Table 33 in Chapter 3 4 2 1 3 MX Multi Node Base Module Disassembly To gain access to the internal jumpers switches and fuses the Multi Node Base must first be disassembled To do this first use a small screwdriver as shown in Figure 9 to press on the latches indentations at the top and bottom of the housing front cover 4 Total As shown in Figure 10 slide the two front covers item 2 forward to remove the two Printed Circuit Boards PCBs from the housing item 1 The front cover of the Control Board item 3 does not attach directly to the board and can be set aside once the latches are free MXBMN Connections MXBMN Module Disassembly N Ll Figure 9 Base Latches Housing 2 Dual Board Assembly U013 23UU092193U 0L d uimey op
58. ge to 01 as shown in Table 29 Because this Input Module is now set to Module ID 01 the Multi Node Base 8 position switch SW2 is used to select a Module Address for Module 01 The matching Input Module for this Output Module is at the Control Room so the correct address to set at SW2 is also 1111 1100 Binary or FC Hex There is already an Address Match between the Control Room and Stations I and 2 When adding this new Output Module Module ID 01 as shown in Table 29 to the same address as the Input Module ensure this module also has an address match The I O 01 Module Status LED Station 3 will be solid green to confirm a match has occurred The input signal enters the network at Port 3 of the Input Module however the Output Module is only a 2 Port device This situation is where Output Port Mapping comes in handy As shown in Table 29 the Output Port Mapping switches for Port 1 are changed from the default of 00 to Port 3 10 to match Port 3 of the Input Module in the Control Room Note that Port l is marked in orange to match the color coding in Figure 38 When the dry contacts are closed Port 3 LED of the Input Module in the Control Room and the Port 1 LED for Output Module at the remote location will both turn solid green This indicates a proper Dry Contact Closure signal is entering the fiber optic network at the Control Room and is exiting the network at Station 3 There will be one dry contact signal connected at Port 3 of Module 1
59. gnals can help to identify and remedy setup errors If an I O module is connected into the network without a mate the Module Status LED will be flashing green for this Module ID This only means that the connected module does not have another matching module at the same address so this condition is termed an Abandoned I O This condition can be quickly corrected by putting the two intended matching modules on the same Module Address setting If a Module Status LED is flashing red this means that two Input Modules are set to the same Module Address and is termed an Address Conflict This condition can very easily happen when none of the Module Addresses have been changed during setup as all Module Address Switches are delivered from the factory with all switches set to O all off This indicator can occur either locally or remotely When occurring locally there will be at least two Module Status LEDs flashing red for each Module ID on a single Multi Node Module When occurring remotely all Multi Node Modules with a connected Input Module set to that same Module Address will have a flashing red Module Status LED for each conflicting Module ID This conflict can be easily resolved by selecting different Module Addresses for all Input Modules involved Remember each Input Module must have its own unique Module Address When setting up a new MX Multiplexer fiber optic network it is recommended to setup one address at a time All I O modules resi
60. gule Address Binary o cs es k EN EN EN EN EN EN EN EE LS Lo REEE o o ca mC sw of of oO of of of oo oo swe EMEN o OE 0 0 s Eo sw olo jo olo ol o o oo sw7 EMEN o KHEN o o 4 Ban sw fofogojogojojojoj oo swe ETES 1 o MEE o 0 ea Grayed out switch settings are unused for this scenario Table 19 Example 1 Remote Station 3 Switch Settings Control Room Moving to Control Room as shown on the right of Figure 37 the output for Remote Station 3 can be configured There will be 3 total Output Modules at this station when it is complete but let s first configure an Output module to work with Station 3 Again the Channel Select switches can be left in the default setting of 00 for this the first Output Module MX420 OP2 to be setup in the Control Room see Table 20 Because this Output Module is set to Module ID 00 the Multi Node Base 8 position switch SW1 is used to select a Module Address for Module 00 The matching Input Module for this Output Module is at Station 3 so the correct address to set at SW1 is 1111 1111 Binary or FF Hex There will be one 4 20mA signal connected at Station 3 which now can be measured in the Control Room With both the Input Module and Output Module set to the same address an Address Match now exists for this I O Function so the I O 00 Module Status LED in both locations is solid green When the input signal is connected to Port 1 of the Input Modu
61. ic network Also switch settings for all the added I O Modules plus all previously installed modules are displayed here for easy use in configuring each station A description section is also provided in the configuration worksheet to add any helpful comments that might apply for this network configuration For this example one Output Module required a change to port mapping setting The default setting E4 Hex was changed to E6 for the Output Module at Station 3 Station Control Room VO Module MXBMN Base Module io Wese GS a a ut Mate 0 1 Mx420 0P2 re Je T ng ut M 4 I hor F LE 1 4 154 lun ME mel Pels 4 Output Mates ale Remote Station 1 MXBMN Base Module VO Module MXBMN Base en EE a SE 2E D a un Output Mate F 4 3 I Port Mapping Defaults Port 4 11 Port 3 10 Port 2 01 Port 1 00 Hexidecimal E4 Module Address Default Binary 0000 0000 Hexadecimal 00 Table 30 Example 2 Network Configuration Worksheet 51 EOTec 2000 Multi Node MX Multiplexer User Manual 3 3 Module Installation and Removal Each MX Multiplexer Module can be installed Figure 39 and removed Figure 43 with ease Bus Covers are shipped with every MX Multi Node Base Module for use in covering the Interconnection Bus once a module stack or station is fully assembled as shown in Figure 41 Each MX Multi Node Base Module also comes with two End Clamps for any protective earth ground connections that may be needed
62. iplexer fiber optic network a data packet contains data for all 256 possible Module addresses Packets are initiated by the Multi Node Module at each end of the fiber optic network Decimal is a numbering system which uses a base of ten digits 0 1 2 3 4 5 6 7 8 9 A bi directional communication link created using fiber optic cable between two Multi Node Base stations Hexadecimal is a numbering system which uses a base of sixteen digits 0 1 2 3 4 5 6 7 8 9 A B C D E F Hexadecimal Notation Hexadecimal Notation is used for expressing the current state of each channel associated with a digital communication bus In this manual it is used to show the state of the Module Address and Output Port Mapping Switches used on the MX Multi Node Base Hot pluggable All MX Multiplexer I O Modules are hot pluggable when used in a non hazardous area Damage will not occur to either the I O Module or the Multi Node Base Module when connected disconnected while power is on However do not separate the internal board assembly from the housing while power is on as this may damage the electrical circuits of this board For safety reasons always remember that connecting disconnecting modules in a hazardous area is not permitted This communication bus is created when plugging MX Multiplexer I O Modules into a Multi Node Base Module There are 4 communication channels so only 4 modules can be added Channel Select Switches on all I O Modules choose a channel to
63. iring methods and in accordance with the authority having jurisdiction Ces produits ne doivent pas tre utilis s pour remplacer le verrouillage de s curit appropri Ce produit ne devrait jamais tre utilis pour la conception de tout logiciel ou tout autre dispositif solide pour tre responsable du maintien de la s curit du personnel ou de tout autre quipement associ En particulier Ultra Electronics NSPI d cline toute responsabilit pour dommages directs ou indirects resultant de l utilisation de cet quipement dans n importe quelle application Toute alimentation c blage d entr e et de sortie I O doivent tre conformes la classe Division 2 des m thodes de c blage et en accord avec l autorit comp tente WARNING EXPLOSION HAZARD AVERTISSEMENT Danger d explosion SUBSTITUTION OF COMPONENTS MAY IMPAIR SUITABILITY FOR CLASS 1 DIVISION 2 ZONE 2 La Substitution de composants peut nuire a la conformit pour Classe 1 Division 2 ZONE 2 WARNING EXPLOSION HAZARD AVERTISSEMENT Danger d explosion WHEN IN HAZARDOUS LOCATIONS DISCONNECT POWER BEFORE REPLACING OR WIRING UNITS En cas de zones dangereuses couper le courant avant le remplacement ou le raccordement d unit s WARNING EXPLOSION HAZARD AVERTISSEMENT Danger d explosion DO NOT DISCONNECT EQUIPMENT UNLESS POWER HAS BEEN SWITCHED OFF OR THE AREA IS KNOWN TO BE NONHAZARDOUS NE PAS d connecter l quipement a moins que l aliment
64. isconnecting modules in a hazardous area is not permitted 30 EOTec 2000 Multi Node MX Multiplexer User Manual Contact Closure Input Connections DRY CONTACT INPUT PORT TERMINAL port 1_ 1 2 3 4 PORT Crorrz e elr e El ports o holai BEE SS ms Interconnection Bus K ugaauuo N OP MXCCAP Dry Contacti Input 10 2 Interconnection LONISULO O Ports 3 amp 4 Only Available on 4 Port Model MXCC IP4 10942 ETH Bus lt PORT 3 PORT 4 N Figure 26 MXCC IP Mating Connections 2 3 2 The Contact Closure Output Contact Closure Output Model Input Power Range Current Rating Output Relay Switching Voltage Contact Current Rating Switching Power Screw Terminals Weight Enclosure Material MXCC OP2 Flammability Rating Input Fuse 31 2 Port Specifications 15 to 30VDC via the interconnection Bus from an MX Multi Node Base Module MXBMN or MXBMN NH 60mA 24Vdc Form C SPDT 220Vdc 250Vac 2A Continuous 2A Switching 60W 62 5VA 2 Relay Contact Ports Pluggable Cage Clamp Screw Terminal Blocks 12 to 24 AWG lt 9 oz Polyamide UL 94V 0 500mA 125V Replacement fuses can be purchased from your Schurter distributor Part number 3403 0163 11 EOTec 2000 Multi Node MX Multiplexer User Manual Contact Closure Output Model Input Power Range Current Rating Output Relay Switching Voltage Contact Current Rating Switching Powe
65. ither 2 or 4 output ports Each 8 position switch split into the 4 possible output port available 2 positions for each port Set these switches to the input port signal to be received at that output port OO port 1 01 port 2 10 port 3 11 port 4 An Input Module is considered a Publisher in the Multi Node MX Multiplexer fiber optic network A publisher writes data onto the data packet for the Module Address selected for the Input Module Only one Input Module can occupy any Module Address Abbreviation for Small Form factor Pluggable transceiver Each Multi Node Base Module has two optical fiber ports which accept this type of transceiver An Output Module is considered a Subscriber in the Multi Node MX Multiplexer fiber optic network A subscriber reads data from the data packet for the Module Address selected for the Output Module Multiple Output Modules can occupy the same Module Address 64 8 Service Our professionals will guide you through the installation of your new product so that it is operational in the minimum amount of time http ultra nspi com contact us tech support installation operation Should you have a question regarding the operation of your instrument or its perceived malfunction the technical support experts will help you determine the issue and offer you the best possible solution Before contacting us please go to our website to prepare yourself with all the appropriate information to he
66. iting the network at the Control Room The I O Function for Module Address FE Hex has now been completed Jie Remote Station 2 Channel Device Output Port Mapping Binary 0 o Mx420 P2 swi 1 1 1 1 1 111707 FE Sws Mo 1 CT sw2 fof of of ojo Grayed out switch settings are unused for this scenario Table 21 Example 1 Remote Station 2 Switch Settings Remote Station 1 Setting up Remote Station 1 again will be very similar to the configurations used at Station 2 amp 3 Here again the Input Module selects the use of I O Channel 00 so the Module ID of Module 00 On the Multi Node Base the 8 position switch SW 1 will be used to select a Module Address for Module 00 As shown in Table 22 the Module Address for this new Input Module must be different than the ones used at Station 2 amp 3 so 1111 1101 Binary or FD Hex is chosen As an Input Module the Output Port Mapping switches will have no effect on this module so can be left in the default positions The Multi Node Base at this location again shows a green 45 EOTec 2000 Multi Node MX Multiplexer User Manual flashing LED for I O 00 Module ID 00 as the matching Output Module in the Control Room for address FD Hex has not been setup yet Our final setup step in the Control Room is to configure the output for Remote Station 1 Figure 37 This third Output module can now be configured to work with Station 1 This time the Channel Select switches wi
67. ity Rating MX010 IP4 810 Es va gt 0 10Vdc Input Connections 09060 EOI TERMINAL Porta 12134 porT 2 5 6 7 3 PORT 3 9 10 11 12 18 N TT OPAC LO Ports 344 Only available on 4 Port Model MX010 IP4 LGNJSULOS LIDIEI A LILICI GOOG Input Fuse 15 to 30VDC via the interconnection Bus from an MX Multi Node Base Module MXBMN or MXBMN NH 65mA 24Vdc 7G Ohms 125mV to 10 3125Vdc OVdc 4mA 10Vdc 20mA Scale 1Vdc 1 6mA 4 0 10Vdc Process Measurement Ports Pluggable Cage Clamp Screw Terminal Blocks 12 to 24 AWG lt 9 Oz Polyamide UL 94V 0 500mA 125V Replacement fuses can be purchased from your Schurter distributor Part number 3403 0163 11 4 FE GND EJF TOHLE Sigal Inter connec tion Bus Interconnection Bus Figure 19 MX010 IP Mating Connections The connections to a 0 10Vdc Input module are shown in Figure 19 Power is connected through the 10 2 Interconnection Bus when attached to the MX Multi Node Base Each Pluggable Screw Terminal Block serves as 24 EOTec 2000 Multi Node MX Multiplexer User Manual a 0 10Vdc process management input or port 0 10Vdc inputs can be created by connecting to each port as shown in Figure 19 All MX Multiplexer I O Modules are hot pluggable when used in a non hazardous area Damage will not occur to either the I O Module or the Multi Node Base Module when connected disconnected while powe
68. lay Switch Max Input Resistance 1K Ohm ELECTRONICS Input Contact Rating 3 3Vdc 1mA minimum POWER PORT 1 Screw Terminals 2 Dry Contact Ports Pluggable Cage Clamp Screw PORT 2 Terminal Blocks 12 to 24 AWG Weight lt 9oz Enclosure Material Polyamide Flammability Rating UL 94V 0 MXCC IP2 Input Fuse 500mA 125V Replacement fuses can be purchased from your Schurter distributor Part number 3403 0163 11 29 EOTec 2000 Multi Node MX Multiplexer User Manual Contact Closure Input Model Input Power Range Current Rating Input Max Input Resistance Input Contact Rating Screw Terminals Weight Enclosure Material Flammability Rating MXCC IP4 Input Fuse 4 Port Specifications 15 to 30VDC via the interconnection Bus from an MX Multi Node Base Module MXBMN or MXBMN NH 50mA 24Vdc Dry Contacts Relay Switch 1K Ohm 3 3Vdc 1mA minimum 4 Dry Contact Ports Pluggable Cage Clamp Screw Terminal Blocks 12 to 24 AWG lt 9 oz Polyamide UL 94V 0 500mA 125V nevne Oder Replacement fuses can be purchased from your Schurter distributor Part number 3403 0163 11 Contact Closure Input Regulatory Markings CE The EOTec MX Multiplexer modular Contact Closure CC Input products MXCC IP2 and MXCC IP4 comply with the essential requirements of the following applicable European Directives and carry the CE marking accordingly EMC Directive EN 61326 1 2006
69. le the Port 1 LEDs for the Input Module at the remote location and the Output Module in the Control Room will both turn solid green This indicates a proper 4 20mA 44 EOTec 2000 Multi Node MX Multiplexer User Manual signal is entering the fiber optic network at Station 3 and is exiting the network at the Control Room The I O Function for Module Address FF Hex has now been successful completed I O Control Room Channel Device Output Port Mapping Binary Mol Mo MX420 0P2 Sw1 1f1f1 1f1f1 1f 1 FF sws i o SOS o o fs Mol 1 Mx420 0P2 sw2 11111 1 111 1 0 FE swe OM 1 o PAEH o jo 4 NOM MX420 0P2 sw3 1 1f1 1f1 1 0f1 Fo sw7 EDEN o AEN o o E4 swa ofofo o ofo o o oo sws EEEN 1 o EE o o E4 Grayed out switch settings are unused for this scenario Table 20 Example 1 Control Room Switch Settings Remote Station 2 Setting up Remote Station 2 is very similar to the configuration used at Station 3 Here again the Input Module selects to use I O Channel 00 so now has the Module ID of Module 00 On the Multi Node Base the 8 position switch SW1 will be used to select a Module Address for Module 00 As shown in Table 21 the Module Address for this new Input Module must be different than the one used at Station 3 so 1111 1110 Binary or FE Hex is chosen Since this is an Input Module the Output Port Mapping switches will have no effect on an Input Module
70. le are shown in Figure 27 Power is connected through the 10 2 Interconnection Bus when attached to the Multi Node Base As each module is stacked together the 10 data signals and 2 power signals are passed to the newly connected module Each Pluggable Screw Terminal Block serves as a Contact Closure output or relay port When a contact closure is created by connecting or shorting terminals 1 and 4 together on an input port of the Input Module then a relay on the Output Module will energize The relay for each output port can be wired on each terminal connector of the front cover to select either opened or closed contacts when the relay is energized The relay diagram in Figure 27 is shown in the de energized state All MX Multiplexer I O Modules are hot pluggable when used in a non hazardous area Damage will not occur to either the I O Module or the Multi Node Base Module when connected disconnected while power is on However do not separate the internal board assembly from the housing while power is on as this may damage the electrical circuits of this board For safety reasons always remember that connecting disconnecting modules in a hazardous area is not permitted 32 EOTec 2000 Multi Node MX Multiplexer User Manual Contact Closure Output Connections Relay State When De Enargized UDI PORT TERMINAL rors 1l2 3 4 ve LJ io e d 0 6 ro gt oa selle 7 PORT2 de fo EE als Interconnection E
71. ll be changed from the default setting of 00 to10 see Table 20 setting up the third and final Output Module MX420 OP2 in the Control Room Because this Output Module is set to Module ID 10 the Multi Node Base 8 position switch SW3 is used to select a Module Address for Module 10 The matching Input Module for the third Output Module is at Station I so the correct address to set at SW3 is 1111 1101 Binary or FD Hex as shown in Table 20 There will be one 4 20mA signal connected at Station I which now can be measured in the Control Room With both the Input and Output Modules set to the same address an Address Match now exists for this I O Function so the I O 10 Module Status LED in both locations is solid green When the input signal is connected to Port 1 of the Input Module the Port 1 LEDs for the Input Module at the remote location and the Output Module in the Control Room will both turn solid green This indicates a proper 4 20mA signal is entering the fiber optic network at Station 1 and is exiting the network at the Control Room The I O Function for Module Address FD Hex has now been completed I O MXBMN Remote Station 1 Output Port Mapping Binary Channel Device SRE EE ve ds ID BON MOM Mxa204P2 swi 1 1 1 1 1 1 1 0 FE sws EMEN 1 o OE o o E BON Mn sw of of of of of ol olo oo swe EMEN 1 o MM 0 0 ro 2 Jswsfolofolo ol ofol o oo sw7 EMEN o MON o o 4 Ban swa fofogojog
72. lp Ultra assist you with your troubleshooting needs htto ultra nspi com contact us tech support troubleshootin pe ENTER T2 A IT elle ICV iC t Giiu If you need service or repair please visit our website and follow the directions provided at this link http ultra nspi com contact us tech support rma request For any other questions please call 512 434 2850 or send e mail to fibersales ultra nspi com 65 i 1 ELECTRONICS Ultra Electronics Nuclear Sensors amp Process Instrumentation 707 Jeffrey Way PO Box 300 Round Rock TX 78680 0300 USA Tel 1 512 434 2850 Fax 1 512 434 2851 e mail fibersales ultra nspi com www ultra nspi com Approval Agency Controlled Document No changes authorized without prior agency approval Publication Number 01 Nov 2014 Ultra Electronics reserves the right to vary these specifications without notice Ultra Electronics 2014
73. ly the Output Modules at the same Module Address or within the same I O Function Figure 36 Output Port Mapping Switches ftirerceee EEGEN TT 2 NNN TITLE era dee EE MEES N The default settings shipped from the factory are 1110 0100 Binary or E4 Hex as shown in Table 12 The default setting selects Port 1 of the Input Module to be connected to Port 1 of the Output Module by setting switches 7 amp 8 to 00 Port 2 01 of the Input Module to be connected to Port 2 of the Output Module switches 5 amp 6 Port 3 10 input to Port 3 of the Output Module with switches 3 amp 4 and Port 4 11 input in the same fashion using switches I amp 2 This switch configuration is known as 1 1 port mapping 41 EOTec 2000 Multi Node MX Multiplexer User Manual DEFAULT SWITCH SETTINGS PORT 4 PORT 3 PORT 2 PORT 1 Switch Position 1 2 3 4 5 6 7 8 1 po po j ij o jo Table 12 Output Port Mapping Default Settings The Channel Select Switches create an association between the I O Module and the Multi Node Base Module called Module ID this association is used by Output Port Mapping to route an input port to any output port As Shown in Table 11 Module ID associates an I O Communication Channel with a Module Address and a Module Status LED This association also holds true for Output Port Mapping for these switches that are also on Multi Node Base Module as shown in Table 13 I O Module Multi N
74. m one location such as a control room An investigation can then begin by analyzing the diagnostic LEDs at each location 3 2 Network Configuration and Installation This section will help clarify all the features of the MX Multi Mode Base and provide examples on how to configure and install a Multi Node MX Multiplexer fiber optic network While reviewing this material please keep in mind the design and planning considerations suggested in Chapter 3 1 Each Multi Node Base Station should be setup in stages to ensure proper operation for each location throughout your fiber optic network By following the installation steps in Table 6 a network can be installed with very few mistakes When mistakes are made they will be quickly identified by fault indicators on the front of both Multi Node Base Module and each I O Module Installation Steps Connect power to the Multi Node Base Install SFP Transceiver s Determine network configuration type Daisy Chain or Ring Step 5 Setup I O modules to communicate across the Interconnection Bus terme mutenese as amat el Attach an Input Module with a unique address Module Address to be identified by Output Modules throughout the entire fiber optic bi network 7 Create an 1 0 Function by attaching Output Modules using the same MM address Module Address as one Input Module Finish attaching all Outputs to this I O Function before moving on to the next function If needed remap 1 0 signal t
75. n conformity with approvals for hazardous locations and explosive atmospheres for USA and Canada Also the Essential Health and Safety Requirements EHSR s of the ATEX Directive 94 9 EC for use in potentially explosive atmospheres FM11ATEX0067X and display the adjacent markings as shown to the left in 0 10Vdc Output II 3 G Ex nA IIC T4 Ta 40 C to 85 C Regulatory Markings 2 2 5 Analog Data Link Operational Settings Channel Selection for Analog Data Link Use a small screwdriver to press on the latches indentations Channel Select A two position DIP switch SW1 is used to at the top and bottom of the housing front cover Slide the select a backplane channel to communicate with the Multi front cover forward to open Node Base Module in a single module stack Do not set two I O modules in the same module stack to the same channel setting Each I O module in a module stack must have a different I O Channel selected to function properly The 4 possible channel selections are shown in Table 3 SVV1 Channel Select Switch 00 OFF om 10 ON OFF Figure 21 I O Latches Figure 22 Channel Switch Table 3 Analog I O Channel Select An I O communication channel must be selected for each Analog Data Link Open the module as shown in Figure 21 using a small screwdriver to release the front cover latches at both the top and bottom of the module Slide the housing front cover forward to reveal a small 2 position DIP
76. nder range indications The lowest level of diagnostics is used in the MX Digital Data Links Figure 46 These modules provide a very simple service so only a simple form of diagnostic is provided to maintain these devices For complete list of all I O LED diagnostics see Table 34 Take care when connecting a module stack MX Multi Node Station to ensure that each Input Module has a unique address device types are matched accordingly and each Input Module has at least one Output Module The LED diagnostics on I O modules only indicates that data is flowing through an I O port and not that it is being routed correctly Only the Module Address Channel Select and Output Port Mapping switches can ensure the data routes correctly through a Multi Node MX Multiplexer fiber optic network 4 2 Interrupting LED Diagnostics The following troubleshooting suggestions have been provided to assist you should you have trouble with your EOTec Multi Node MX Multiplexer fiber optic network MX Multi Node Fiber Optic Base MXBMN Modules Advanced Diagnostics Model No MXBMN MXBMN NH POWER STATUS Power is good Marked IN1 Power input is lt 15Vdc or gt 30Vdc Solid Red 1 Verify power input is 215 to lt 30Vdc 2 If both power input is correct replace MXBMN Power has not been supplied Off 1 Verify power input is 215 to lt 30Vdc 2 Check fuse F1 on Optical Board Replace if blown 3 If both power and fuse are good replace MXBMN POWER STA
77. o provided with each Multi Node Base Module which can also be used as a remote alarm Table 33 Upon resolving one LED fault another lower priority fault might still exist for a particular Module Status LED These indicators are prioritized by their level of importance If an Input Conflict exists at a particular Address this primary fault identified by a flashing red LED can be resolved by removing one of the Input Modules from this Module Address However a secondary Device Fault may then be identified if this LED turns to solid red Upon resolving this fault a tertiary I O Abandoned fault may be identified with a flashing green LED By following this prioritized fault process systematically all faults can be resolved resulting in a solid green LED For more information on interrupting these diagnostic indicators see Chapter 4 2 Local Alarms MX Multi Node Base MXBMN Power Status Marked IN 1 IN 2 Transmit Status Marked Fiber1 TX Transmit Fault SFP no data from module Red Fiber2 TX Off Receive Status Green Marked Fiber1 RX Fiber2 RX Flash Red Solid Green Marked Global Solid Red Master Status Master jumper set Solid Green Marked Master Module Status Solid Green Marked 1 0 1 Solid Green 0 2 Flash Green 0 3 Flash Green WO Solid Red Flash Red Flash Red Off Superscript 43 is the order of the fault priority level 1 being the highest priority Table 32 Multi Node MXBMN Local Alarms R
78. o the Multi Node Base at this station so the Channel Select switches for this 2 Port Output Module MXCC OP2 changed to 01 as shown in Table 27 Because this Input Module is now set to Module ID 01 the Multi Node Base 8 position switch SW2 is used to select a Module Address for Module 01 The matching Input Module for this Output Module is at the Control Room so the correct address to set at SW2 is 1111 1100 Binary or FC Hex With both this Input Module Module ID 11as shown in Table 26 and Output Module Module ID 01 as shown in Table 27 set to the same address an Address Match now exists for this I O Function The I O 01 Module Status LED Station 1 and the I O 11 Module Status LED Control Room are now both solid green When the input signal is connected to Port 1 of the Input Module the Port 1 LEDs for the Input Module in the Control Room and the Output Module at the remote location will both turn solid green when the dry contacts are closed This indicates a proper Dry Contact Closure signal is entering the fiber optic network at the Control Room and is exiting the network at Station 1 The I O Function for Module Address FC Hex is now functional but has not yet been completed Since both the input and the output signals are using Port 1 the default Output Port Mapping settings can be used see Table 27 Note that Port 1 is marked in green to match the color coding in Figure 38 There will be one dry contact signal connected
79. o use Output Modules more effectively Es Output Port Mapping Table 6 Network Installation Stages 3 2 1 Power and Fiber Connections The MX Multi Node Base has redundant power inputs This allows the base unit to support a primary power source and a secondary or backup source of power If a secondary power source is not required the primary IN 1 and secondary IN 2 can be strapped together to avoid a Power amp Global fault indicator The power LEDs IN 1 IN 2 for the Multi Node Base will be solid green when a correct power source gt 15Vdc and lt 30Vdc has been connected to both the primary and secondary input terminals as shown in Figure 31 If only one power input is connected a power fault will be indicated For more information on diagnosing power faults see Chapter 4 Without a Small Form factor Pluggable SFP transceiver installed in the Multi Node Base unit both TX and RX LEDs will be off as shown for Off Not Master Default the Fiber 2 transceiver port in Figure 31 Upon installing each SFP the TX will be green and Module I O 00 Off Status I O 01 Off I O 10 Off VO 11 Off No 1 0 connected the RX red as shown for the Fiber 1 transceiver port in Figure 31 Figure 31 MXBMN Table 7 MXBMN No Fiber Label Diagnostic Indicators Povver IN 1 Green Power Good Real IN 2 Green Power Good Fiber 1 TX Green RX Red ECS Fiber 2 TX Off RX Off LT osent O Global Red
80. ociated with Module ID 00 and switch bank SW1 and is now known as Module 00 Figure 35 Table 11 further shows this association of all I O Modules There are 256 possible Module Addresses available in an MX Multi Node fiber optic network This allows 256 Input Modules to be attached into the network so care should be taken when setting up or modifying your network configuration I O Module Multi Node Base Module Channel Select Module ID Module Status I O 00 Module 00 I O 00 I O 01 Module 01 SVV2 I O 01 I O 10 Module 10 SW3 I O 10 I O 11 Module 11 SW4 I O 11 Table 11 Module Address Association Also shown in Table 11 is an association of the status LEDs on the front of the Multi Node Base Figure 32 Given the status of the I O module connected there will be a status reported by these LEDs Every I O module must have a mating module at the same address Each Input Module must have at least one Output Module at the same Module Address This match is known as an Address Match All modules residing at the same address must also be of the same device type Analog Digital This match is known as a Device Match When both these matches occur the Module Status LED for that connected I O module will be green for this Module ID 40 EOTec 2000 Multi Node MX Multiplexer User Manual There are Mismatch faults that are associated with the Module Address and can occur when setting up a Multi Node network These diagnostic si
81. ode Base Module Channel Select Module ID Module Status I O 00 Module 00 SW5 1 0 00 I O 01 Module 01 SW6 I O 01 I O 10 Module 10 SW7 I O 10 I O 11 Module 11 SVV8 I O 11 Table 13 Output Port Mapping Association Output Port Mapping can be used in some very useful scenarios One way is to select one input port to go to all four output ports or 1 4 Port Mapping as shown in Table 14 In this example all 4 output ports of Module ID 00 are set to connect to the input signal from Port 1 00 of the Input Module The input signal Port 1 can now be measured all output ports 1 4 Additionally by using the same Module Address on the remaining 3 Output Modules the 3 remaining input ports can be connected in a similar fashion As shown in Table 14 Input Port 2 01 is shown connected to all 4 output ports of Module 01 input Port 3 10 to all 4 output ports of Module 01 and input Port 4 11 to all 4 output ports of Module 11 Similarly 1 16 Port Mapping can be created by setting all 4 Output Port Mapping Switches to input Port 1 00 as shown in Table 15 Now all 16 output ports 4 Output Module can output the same signal from Port 1 to all 16 output ports on the 4 Output Modules PORT 4 Module 00 Module 00 o Module po 0 0 0 0 0 0 0 Table 14 1 to 4 Output Port Mapping Table 15 1 to 16 Output Port Mapping Another useful scenario is when the input signals of one Input Module are required to be split between two separate
82. ode Base Module or optical node provides a maximum of 16 input or output I O signal connections 34 EOTec 2000 Multi Node MX Multiplexer User Manual 3 1 2 Consider the Number of I O Connections The number of I O connections at a given location will determine the number of I O modules required to connect each signal into the fiber optic network The type of I O connections at these locations will determine which I O module type input or output the technology required MX420 MX010 MXCC and the number of connected signals required at each module 2 or 4 port modules See Chapter 2 to understand the specifications for selecting I O hardware The number of I O modules needed determines the number of fiber optic nodes or MX Multi Node Base Modules required at each location Only a total of 4 I O modules can be attached to any Multi Node Base Module A Multi Node Base can connect up to 16 I O when using 4 Port modules but each module only allows either input or output signals to be connected To mix input and output signals at one optical node both module types must be connected to the Multi Node Base It may be necessary to deploy multiple Multi Node Bases to connect all I O connections at a given location When multiple Multi Node Bases are required at one location each can be added to the fiber optic network using a short fiber optic patch cord 3 1 3 Consider Where the I O Signals Connect Creating a list of input to output connecti
83. ojojojoj oo swe ETES 1 o EE o Oo ea Grayed out switch settings are unused for this scenario Table 22 Example 1 Remote Station 1 Switch Settings Configuration Work Sheet It would of course be difficult to run back and forth between these 4 locations to setup this fiber optic network It is recommended that all modules be configured on a test bench and tested in this fashion explained in this example before installation at any field locations To assist in this effort a configuration worksheet has been developed as shown in Table 23 This worksheet has a Station identifier for each Multi Node Base Station and a row provided to identify the Channel Select setting for the 4 possible I O Modules just like the tables presented in this example By using the I O Type field enter all the model numbers for each I O modules which is attached at that particular station Now use the Module Address field to enter a unique address Hex for each Input Module in the fiber optic network In the Function field assign an incrementing I O Function number to each Input Module For all Output Modules use these same fields to associate each Output Module with the matching Module Address which are to be connected to each Input Module You now have a wiring list showing the I O connections throughout your fiber optic network Also switch settings for all Multi Node Base Modules plus all the I O Modules are displa
84. ons or a wiring diagram helps to understand where an input signal enters into the fiber optic network and at what location or locations this signal will need to be taken from the network Formulating and visualizing this will help to create an address scheme for connecting these devices across this network 3 1 4 Consider Address Scheme Only Input Modules are considered addressable where the Output Modules simply receive input data from an Input Module by selecting the same Module Address as the require Input Module This type of address scheme is considered a Publisher Subscriber relationship By selecting an input address on the fiber optic network an Input Module is the Publisher of up to 4 input signals at that address An Output Module selecting this address is now a Subscriber to the data signals published at that address There is no limit to the number of subscribers Output Modules that can connect to a Module Address It may be necessary for multiple input signals to enter the fiber optic network using multiple Input Modules As each Input Module must have a unique address it may make since to group input signals which are going to the same output location This may save on the total number of I O modules required See Chapter 3 2 4 for more information on Module Addressing 3 1 5 Consider Output Port Mapping Since multiple Output Modules can address the same Input Module it may be cost effective to remap or reroute the
85. oubleshooting advice Fiber Break A unit with this fault is not receiving fiber transmissions The RX LEDs can solid red or flashing red to cause this fault condition Refer to MXBMN Diagnostics in Chapter 4 2 for further troubleshooting advice 60 EOTec 2000 Multi Node MX Multiplexer User Manual 5 Default Settings This chapter shows the factory default settings for all EOTec MX Multiplexer modules as they are shipped from the factory It is likely these settings will require changes to tailor the Multi Node MX Multiplexer fiber optic network to your exact needs For more information on the use of all switches and jumpers consult Chapter 2 for each device For information on reconfiguring switches and jumpers to properly install your fiber optic network see Chapters 3 MX Multi Node Base Modules Module Type Model Numbers MXBMN MXBMN MXBMN NH Made D Pair Module Address Switches TT BIT SW1 0000 0000 Binary 00 Hex we x we SW2 0000 0000 Binary 00 Hex deter DETTE SW3 0000 0000 Binary 00 Hex SW4 0000 0000 Binary 00 Hex Output Port Mapping Switches SW5 1110 0100 Binary E4 Hex SW6 1110 0100 Binary E4 Hex SW7 1110 0100 Binary E4 Hex SW8 1110 0100 Binary E4 Hex Master Slave Select Jumper J5 Slave MX Analog Data Link Modules 4 20mA 0 10Vdc Module Type Model Number s MxX010 MX010 IP2 MX010 IP4 MX010 OP2 MX010 OP4 MX420 MX420 IP2 MX420 IP4
86. output locations As an example of Split Port Mapping the Output Module 00 in Location 1 is shown in Table 16 connecting Port 1 00 of the Input Module to Port 1 of the Output Module and Port 2 01 of the Input Module to Port 2 of the Output Module Port 3 and Port 4 of Module 00 at Location are unused in this scenario so Location 1 can use the more economical 2 Port Output Module here In Location 2 Output Module 00 connects Port 3 10 of the Input Module to Port 1 of the Output Module and Port 4 10 of the Input Module to Port 2 of the Output Module Table 16 Again Port 3 and Port 4 of this Output Module so again the more economical 2 Port Output Modules can be used at Location 2 as well 42 EOTec 2000 Multi Node MX Multiplexer User Manual LOCATION 1 OUTPUT PORT MAPPING Output Port PORTA PORT 3 PORT 2 PORT 1 1 213 4 5 n a L N 2 LOCATION 2 OUTPUT PORT MAPPING Output Port PORT 4 PORT 3 PORT 2 PORT 1 Module 00 1210337 485 6 7 8 Module 00 n a n a 1 1 fi jo Table 16 Split Output Port Mapping Care must be taken when using Output Port Mapping No diagnostics are provided to alert the user to mapping errors When the input signal is mapped correctly to the desired output port the signal can be measured there for verification See Example 2 in Chapter 3 2 7 for more details on how to correctly setup port mapping 3 2 6 Network Installation Example 1
87. ow has the Module ID of Module 11 On the Multi Node Base an 8 position switch SW4 is used to select a Module Address for Module 11 As shown in Table 26 the Module Address has been set to address 1111 1100 Binary or FC Hex Since this is an Input Module the Output Port Mapping switches will have no effect on an Input Module so can be left in the default positions All other switches for the Multi Node Base Module in the Control Room were already been setup in Example 1 so are shown grayed out and left alone The Multi Node Base at this stage of the setup shows a green flashing LED for I O 11 Module ID 11 as the matching Output Modules in the remote locations have not been setup yet This Input Module in the Control 48 EOTec 2000 Multi Node MX Multiplexer User Manual Room is shown to be Abandoned until one the modules at a remote location can be setup with the same Module Address MXBMN Control Room Output Port Mapping Binary Channel ae l I DE OA ees e ER LE Pees ae ae BON Mx420 0P2 sw3 1 1 1f1 1 1l0 1 Fo sw7 EE 1 0 fo o o e 4 2 sep swa 1 1 1 2 111 0 0 rc sws aja 110 Fo pag o o Output Port Mapping is not used for Input Modules Table 26 Example 2 Control Room Switch Settings Remote Station 3 Moving to Remote Station 3 as shown on the left of Figure 38 the output from the Control Room Port 1 input signal can be configured There is already another I O Module attached t
88. power signals are passed to the newly connected module Each Pluggable Screw Terminal Block serves as a 4 20mA process loop input or port A current loop can be created by wiring a loop transmitter to each port as shown in Figure 17 All MX Multiplexer I O Modules are hot pluggable when used in a non hazardous area Damage will not occur to either the I O Module or the Multi Node Base Module when connected disconnected while power is on However do not separate the internal board assembly from the housing while power is on as this may damage the electrical circuits of this board For safety reasons always remember that connecting disconnecting modules in a hazardous area is not permitted 20 EOTec 2000 Multi Node M 4 20mA Input Connections Hot POWER SUPPLY NOM 24Vdc 4 20mA LOOP TRANSMITTER PE GND OPTIONAL PORT TERMINAL rer i PoR 1 1 2 3 41 PORT 1 erz lslelrle J i 6 PORT 2 N 10 2 ELECTRONICS 10 de 2 Zz lez a br i o oO A EG TRONIG pe I LES 2 ES Ports 3 amp 4 PORT 1 Only Aavailable on ee Bus Interconnection POWER Interconnection 4 Port Model MX420 IP4 WIDE EE PORT 3 PORT 4 MX420 IP4 IK er ES LA w Figure 17 MX420 IP Mating Connections 2 2 2 The 4 20mA Process Loop Output A Output Model 2 Port Specifications Input Power Range 15 to 30VDC via the interconnection Bus from an MX Multi Node Base Module MXBMN or MXBMN NH
89. pter 2 for each model number Approvals Lightning Danger Do not work on equipment during periods of lightning activity Danger de Foudre Ne pas travailler sur l quipement pendant les p riodes d activit de foudre All Small Form factor Pluggable SFP transceivers are IEC 60825 1 Class 1 Laser compliant Class 1 Lasers are safe under reasonably foreseeable conditions of operation including the use of optical instruments for intra beam viewing IEC 60825 1 Class 1 Laser Product FDA 21 CFR 1040 10 amp 1040 11 EOTec 2000 Multi Node MX Multiplexer User Manual ULTRA ELECTRONICS Statement of Terms and Conditions ULTRA ELECTRONICS NSPI Standard Terms and Conditions of sale apply unless otherwise expressly agreed in writing all sales are subject to the following terms and conditions www ultra nspi com information central terms conditions INSTALLATION AND HAZARDOUS AREA WARNINGS Avertissements pour installation et zones dangereuses These products should not be used to replace proper safety interlocking No software based device or any other solid state device should ever be designed to be responsible for the maintenance of consequential equipment or personnel safety In particular ULTRA ELECTRONICS NSPI disclaims any responsibility for damages either direct or consequential that result from the use of this equipment in any application All power input and output I O wiring must be in accordance with Class I Division 2 w
90. r Screw Terminals Weight Enclosure Material MXCC OP4 4 Port Specifications 15 to 30VDC via the interconnection Bus from an MX Multi Node Base Module MXBMN or MXBMN NH 80mA 24Vdc Form C SPDT 220Vdc 250Vac 2A Continuous 2A Switching 60W 62 5VA 4 Relay Contact Ports Pluggable Cage Clamp Screw Terminal Blocks 12 to 24 AWG lt 902 Polyamide UL 94V 0 Flammability Rating Gene eo 500mA 125V Replacement fuses can be purchased from your Schurter distributor Part number 3403 0163 11 Input Fuse Contact Closure Output Regulatory Markings The EOTec MX Multiplexer modular Contact Closure CC Output products MXCC OP2 and MXCC OP4 comply with the essential requirements of the following applicable European Directives and carry the CE marking accordingly EMC Directive EN 61326 1 2006 For Safety requirements these products comply with Canada CSA C22 2 No 142 Process Control Equipment These products have been assessed against and found to be in conformity with approvals for hazardous locations and explosive atmospheres for USA and Canada Also the Essential Health and Safety Requirements EHSR s of the ATEX Directive 94 9 EC for use in potentially explosive atmospheres and display the adjacent markings as shown to the left in Contact Closure Out Regulatory Markings FM11ATEX0067X II 3 G Ex nA IIC T4 Ta 40 C to 85 C The connections to a Contact Closure Output Modu
91. r is on However do not separate the internal board assembly from the housing while power is on as this may damage the electrical circuits of this board For safety reasons always remember that connecting disconnecting modules in a hazardous area is not permitted 0 10Vdc Input Regulatory Markings The EOTec MX Multiplexer modular 0 10Vdc Input products MX010 IP2 and MX010 IP4 comply with the essential requirements of the following applicable European Directives and carry the CE marking accordingly EMC Directive EN 61326 1 2006 For Safety requirements these products comply with Canada CSA C22 2 No 142 Process Control Equipment These products have been assessed against and found to be in conformity with approvals for hazardous locations and explosive atmospheres for USA and Canada Also the Essential Health and Safety Requirements EHSR s of the ATEX Directive 94 9 EC for use in potentially explosive atmospheres and display the adjacent markings as shown to the left in 0 10Vdc Input Regulatory Markings FM11ATEX0067X Il3 G Ex nA IIC T4 Ta 40 C to 85 C 2 2 4 The 0 10Vdc Process Management Output 0 10Vdc Output Model 2 Port Specification 15 to 30VDC via the interconnection Bus from an MX Multi Node Base Module MXBMN or MXBMN NH Input Power Range Current Rating Output Impedance Operating Range Voltage Conversion Screw Terminals Weight Enclosure Material Flammability Rating
92. rol Room This distance is now well beyond 2 kilometers and will require single mode fiber optic cable to complete the ring network topology In this installation the objective is still to provide three 4 20mA signals from three remote locations to one Control Room but as that installation was fully explained in Example 1 this example will focus solely on the Dry Contact Closure application Thus the 4 20mA application is shown as an active part of this network but will also be shown as gray out in Figure 38 will not be further discussed in this example The additional Multi Node MX Multiplexer part numbers required to build this particular fiber optic network are listed in Table 24 Additional parts are also needed to complete this fiber optic network but not supplied by Ultra Electronics NSPI See Table 25 The parts grayed out in these two tables are shown to provide a complete list for this network topology but were installed into the network in Example 1 47 EOTec 2000 Multi Node MX Multiplexer User Manual Remote Remote Remote Control Station 1 Ci Station 2 Station 3 Room Master Viodule PORT 2 OUTPUT Li den MXCC OP2 gt s gt Fiber Link I Fiber Link 2 Fiber Link 3 MXCC OP2 Virtual Link Fx Module Address Hex 1 Optional SEP to reate Ring Network Figure 38 Example 2 Add Contact Closure and Ring Example 1 Ultra Electronics NSPI Required Pa
93. rts Ultra Part Number MXCC IP4 Dry Contact Closure Input Module 4 Port MXCC OP2 Dry Contact Closure Output Module 2 Port SFP13 100M15K Single Mode SFP Transceiver 1310nm 14db 9 125um fiber 15k Table 24 Example 2 Ultra Parts Required Example 1 Additional Required Parts Quantity Single mode 9 125um fiber optic cables Table 25 Example 2 Additional Parts Required As the initial 4 Multi Node stations were installed in Example 1 this example begins with an operational 4 20mA multi mode daisy chain network as shown in Figure 37 As this example is a Redundant Ring network configuration the first task is to create a Master Multi Node Module to control the ring functions of the fiber optic network The Multi Node Base for the Control Room in Figure 38 is shown as the Master but any other module could be selected instead Set up the Master Module as described in Chapter 3 2 2 All other modules should be left in the default setting Slave to work in this network configuration Next install the 2 single mode transceivers shown in Table 24 at Station 3 and the Control Room then add the single mode fiber cable Table 25 connecting these two stations together Figure 38 Control Room We begin this installation in the Control Room as shown to the right in Figure 38 There are already 3 I O Modules connected to this Base Module so the first task is to change the Channel Select switch of the MXCC IP4 to 11 and n
94. s Also if the Module ID Status LEDs are flashing both green and red erratically this indicates that more than one I O Module is communicating on same I O Channel To correct this problem turn the power off and recheck the Channel Select Switches of each I O Module Since each I O Module is shipped from the factory with a default setting of OO it is important to ensure these switches are changed when adding more than one I O Module to the Multi Node Base Avoid this situation by checking each I O module before attaching it to the Multi Node Base Also find a summarized dashboard on all diagnostic indicators in Chapter 3 4 and a complete guide to troubleshooting in Chapter 4 3 2 4 Module Address Switches Inside each Multi Node Base Module can be found four 8 Position switches marked SW1 SW4 Figure 35 Once the Channel Selection Switches have set up a Module ID the Module Address Switches are used to select a Module Address to match one Input Module to one or more Output Modules over the fiber optic network Module Address Switches Module 00 f s SY vr biked 14914444 Module 01 ETE Hat SW2 We iiiiiiii mr Module 10 ol SW3 q 1441513 ER Ra 13 LEE z di ae Ed E en fe ULLE y 3 i 4 7 di 1 f L AT De UP vinn li LC a aa Ca dE La Pi ed Module 11 EE da e ta Ll i SWa W eres WE by LATE Tu vy r JER ERE EE Are hi r mi r ha il Tr ATED ultra i 3 a pr L MH gt
95. s I O 00 01 10 11 Using Table 4 set the Channel Select switches of each I O Module to a different selection This creates a unique communication channel between MX Multi Node Base and the 4 possible I O modules that can be combined MOT to create a module stack or Multiplexer Station Vo VO 00 ai When an I O module is attached to a Multi Node base a Snyc corresponding Module Status LED will light on the Base module 24 These LEDs or Diagnostic Indicators can help you to install your I O network correctly All modules attached to the base must select a different channel If two I O modules have the same selection the Base module will be confused and module LEDs will flash erratically See Chapter 3 2 3 for more information on channel selection Figure 30 Channel Select Digital I O 3 Network Planning Configuration and Installation Without much difficulty a Fiber Optic I O Network can be planned by considering some basic design steps as shown below in Chapter 3 1 By taking this organized approach your network can be easily configured Also when understanding the considerations discussed in Chapter 3 1 and the installation options explained in Chapter 3 2 you can quickly gain the knowledge needed to plan your own fiber optic network Once understanding the material presented here you will have all the information you need to order configure and install a Multi Node MX Multiplexer fiber optic network The MX M
96. so can be left in the default positions The Multi Node Base at this point again shows a green flashing LED for I O 00 Module ID 00 as the matching Output Module in the Control Room for address FE Hex has not been setup yet Moving back to Control Room as shown on the right of Figure 37 the output for Remote Station 2 can be configured The second Output module can now be configured to work with Station 2 This time the Channel Select switches are changed from the default setting of 00 to OI see Table 20 setting up this second Output Module MX420 OP2 in the Control Room Because this Output Module is set to Module ID 01 the Multi Node Base 8 position switch SW2 is used to select a Module Address for Module 01 The matching Input Module for this second Output Module is at Station 2 so the correct address to set at SW2 is 1111 1110 Binary or FE Hex as shown in Table 20 There will be one 4 20mA signal connected at Station 2 which now can be measured in the Control Room With both the Input and Output Modules set to the same address an Address Match now exists for this I O Function so the I O 01 Module Status LED in both locations is solid green When the input signal is connected to Port 1 of the Input Module the Port 1 LEDs for the Input Module at the remote location and the Output Module in the Control Room will both turn solid green This indicates a proper 4 20mA signal is entering the fiber optic network at Station 2 and is ex
97. there 2 or 256 different combinations to select This very large number of possible combinations can make it difficult to discuss switch settings using just a 0 or I 39 EOTec 2000 Multi Node MX Multiplexer User Manual Binary Notation However by splitting the switches into two more manageable chunks called bytes we can use Hexadecimal Notation to easily discuss these setting As shown in Table 10 the eight switch positions are split into an upper byte and a lower byte Four switches will only have sixteen different combinations so by using two Hex numbers to represent these two bytes will make it easier to show all 256 combinations A setting of all switches to the off position all O s as shown in Binary Notation would be 0000 0000 or as shown in Hex as 00 Conversely a setting of all switches to the on position all 1 s as shown in Binary Notation would be 1111 1111 or as shown in Hex as FF Using Hex simplifies the discussion allowing Module Address settings to be more easily explained Upper Byte Lower Byte Hex Hex Position a Postion2 postions Postiona postions postions Position 7 Poston FE Table 10 Hexadecimal Equivalent Module Status When an I O module is connected to the Multi Node Base a Module Status LED will light up Each of the four I O Modules have a unique Module ID once the Channel Select Switches are set If the Channel Select Switches of an I O Module are set to 00 then it is ass
98. ting Range 3 8 to 20 5mA Voltage Conversion 4mA OVdc 20mA 10Vdc Scale Ima 0 625Vdc Screw Terminals 4 4 20mA Process Loop Ports Pluggable Cage Clamp Screw Terminal Blocks 12 to 24 AWG Weight lt 9 oz Enclosure Material Polyamide Flammability UL 94V 0 Rating MX420 IP4 AKK Input Fuse 500mA 125V Replacement fuses can be purchased from your Schurter distributor Part number 3403 0163 11 The EOTec MX Multiplexer modular 4 20mA Input products MX420 IP2 and MX420 IP4 comply with the essential requirements of the following k applicable European Directives and carry the CE marking accordingly EMC Directive EN 61326 1 2006 For Safety requirements these products comply with Canada CSA C22 2 APPROVED No 142 Process Control Equipment These products have been assessed against and found to be in conformity with approvals for hazardous locations and explosive atmospheres for USA and Canada Also the Essential Health and Safety Requirements EHSR s of the ATEX Directive 94 9 EC for use in potentially explosive atmospheres and display the adjacent markings as shown to the left in 4 20mA Input Regulatory Markings FM11ATEX0067X Il 3 G Ex nA IIC T4 Ta 40 C to 85 C The connections to a 4 20mA Input Module are shown in Figure 17 Power is connected through the 10 2 Interconnection Bus when attached to the MX Multi Node Base As each module is stacked together the 10 data signals and 2
99. trol or report status from a local area to multiple remote sites Modules are available in either 2 Port or 4 Port varieties A maximum of four modules can be stacked together with a Multi Node Base Module MX Multiplexer I O Modules can be stacked together to provide from a minimum of 2 ports one 2 Port module to a maximum of 16 ports four 4 Port modules to support your solution Digital Data Link I O modules update the MX Multi Node Base module at a rate of 57 6 KHz 17 36us The Multi Node Base in turn updates the Fiber Optic Network every 2 3 milliseconds with the most recent I O data gt High Performance Reliable Technology o Update Rate 57 6Khz independent of number of modules or channels utilized o Input Dry Contacts Relay Switch o Output Form C Relay SPDT gt Industrial Design for High Reliability o Modular flexible scalable Operating temperature range 40 to 85C FM approved for Class I Div 2 Groups A B C amp D T4 In ATEX listed II 3 G Ex nA IIC T4 Ta 40 C to 85 C eeee Out ATEX listed II 3 G Ex nA nC IIC T4 Ta 40 PC to 85 C de dl o Standard 35 mm DIN rail mounting gt Additional Features o Replaceable Fuse MKCC 0P3 MXCC IFA Oo Oo 2 3 1 The Contact Closure Input Contact Closure Input Model 2 Port Specifications Input Power Range 15 to 30VDC via the interconnection Bus from an MX Multi Node Base Module MXBMN or MXBMN NH Current Rating 45mA 24Vdc Input Dry Contacts Re
100. twork normally cannot tell the user what is happening elsewhere on the system The EOTec MX Multiplexer has real time alarms that are a vital feature to keep system administrators and operators informed when a problem exists in their network 1 1 Multi Node Communication Method The Multi Node optical fiber base for the EOTec 2000 Multi Node MX Multiplexer allows Input Devices to communicate directly to Output Devices through multiple I O stations existing in the same fiber optic network By creating a unique address for each Input Module I O signals connected to this module can be shared with an infinite number of Output Modules throughout the fiber optic network 1 1 1 Serial or Daisy Chain Communication Method As shown in Figure 1 the two ends of the communication chain send out a data packet with a data location for all 256 Input Module Addresses An upstream data packet is sent from one end Remote Station 1 while a downstream data packet is sent from the other direction Control Room New data packets are initiated every 2 3 milliseconds As each data packet arrives at a Multi Node Base Station MXBMN Input Modules will update the packet and Output Modules will be updated from the packet An Input Module entering an input signal into the fiber optic network can be seen as a Publisher which writes new data at a specified address location of each data packet while Output Modules can be considered Subscribers who will read from the
101. uired Example 1 Additional Required Parts Quantity 4 EN 15 30Vdc power supply 6 Multi mode 62 5 125um fiber optic cables Table 18 Example 1 Additional Parts Required 43 EOTec 2000 Multi Node MX Multiplexer User Manual To begin any installation of a Multi Node MX Multiplexer fiber optic network always start by powering the Multi Node Bases MXBMN and verifying the fiber communication connections as discussed in Chapter 3 2 1 When this part of the network is connected correctly the Multi Node Bases diagnostic LEDs on the front of each station will be green or off as shown in Figure 32 Note in Figure 1 that Remote Station I is not using an SFP transceiver in Fiber Port Fl and the Control Room station is not using an SFP transceiver in Fiber Port F2 For this network configuration the TX RX LEDs associated with these transceiver ports will be off Since this example is a daisy chain configuration there is no need to setup a Master module as the default setting Slave will work in this network configuration for all modules Each Multi Node Base will be set up in the fiber optic network per the switch settings provided in the tables below The power and fiber optic cables have all been installed to the Multi Node Base Modules as explained in Chapter 3 2 1 and all fault indicators show the fiber optic network to be installed correctly The I O modules are now ready to be connected Remote Station 3
102. ule Only one Input Module can occupy any given Module Address but there is no limit to the number of Output Modules at the same address See Chapter 3 2 4 for more information on Module Addressing Module Address CEPTEN Mata Output Port Mapping vi AAAAAAAA RAL La uhh ND Te MODULE ADDESS zasszatd OUTPUT PORT MAPPING Porr 4 PORT PORT 2 PORT 1 NTT 233483424 11148288 taaceser 343333934 ES EN KM Figure 11 Module Address Figure 12 Jumper amp witches Output Port Mapping From To Port Svvitches Input Port Output Port Setting Used IE 1 o 78 Table 2 Default Port Setting There are also four 8 position Output Port Mapping switch banks for the four possible Output Modules which can be attached to the Multi Node Base These 4 Output Port Mapping switch banks can be shown in Figure 12 SW5 SW6 SW7 SW8 These switches can only be used in conjunction with an Output Module Set the switches to the desired input port you wish to be received by each output port as shown in Figure 13 Switch on to select a 1 value or switch off to select a 0 value 16 EOTec 2000 Multi Node MX Multiplexer User Manual Table 2 shows the default settings for all Output Port Mapping Switches as shipped from the factory As an example to map Port 3 of the Input Module to Port 1 of the Output Module first both modules must be set to the same Module Address then map Port 3
103. ultiplexer product line was designed with straightforward installation in mind Diagnostic LEDs have been provided to aid in the installation of the product By understanding the information provided by the diagnostic indicators your network can effortlessly be installed and maintained For an at a glance dashboard of all the diagnostic features refer to the Chapter 3 4 To learn more about diagnosing failures refer to the Chapter 4 1 3 1 Network Design and Planning When designing and planning a Multi Node MX Multiplexer fiber optic network there are import considerations to weigh while reviewing the Multi Node feature set and learning how to configure and install a network Network Considerations Consider the number of I O locations to support Consider the number input and output signals at each location Consider how the I O signals connect Consider an addressing scheme Consider changing the mapping to the output ports 6 Consider using the Global Alarm Table 5 Planning Considerations 3 1 1 Consider Number of I O Locations An I O location is anyplace where one or more I O connections will enter the fiber optic network The MX Multi Node Base provides a fiber optic node to connect each I O signal into this network At least one Multi Node Base will be required at each I O location and possibly multiple optical nodes may be required depending on the number of I O signal required to enter the fiber optic network Each Multi N
104. ut amp Output Modules to the same address As shown in Figure 24 two 4 20mA signals are applied to input ports 1 amp 2 4 20 Input Module in the local area The 0 10Vdc module in the remote area is set to the same Module Address as the 4 20mA module in the local area The Output Module receives digital data from the Input Module over the fiber optic network and coverts that data into a voltage signal equivalent to that of the current signal provided from the local area Conversions can be performed at one Multi Node Station as well Attach both a MX010 Input Module and a MX420 Output Module to the same Multi Node Module As usual select a separate I O communication channel for each I O module Now set the Module Address of each module to the same address The Multi Node Base will now pass the data between the two modules to complete a voltage to current conversion All Ultra Analog Data Links use the global standard scale as illustrated in Figure 25 and shall have a linear signal from 125mVdc to 10 3125Vdc for voltage data links and 3 8mA to 20 5mA for current data links As long as the signal at each I O port is within these parameters the diagnostic LED shall be light solid green There is one LED for each I O port Should your sensor malfunction and go to an over range condition the LED shall light solid red until that condition is remedied Should your sensor break and go to an under range condition the LED shall blink red until that sensor c
105. ve the proper separation and properly guided into each slide the dual board assembly will easily enter the housing To begin a proper insertion first ensure the housing is rotated into the proper position as shown in Figure 8 inter connection bus connector to the left If problems arise do not force the boards into the housing as damage may occur Check the housing rotation and if needed realign the two boards to the proper distance and try again Once the two boards have slid completely into the housing the latches of the Optical Board Front Cover will snap into place Finally snap the Control Board Front Cover over the exposed board to properly seal the unit 2 1 8 MX Multi Node Base Product Regulatory Markings MXBMN The EOTec MX Multiplexer Multi Node Base Module MXBMN complies with the essential requirements of the following applicable European Directives and carries the CE marking accordingly EMC Directive EN 61326 1 2013 and CISPR 11 2009 Al 2010 This product with Hazardous Location certification for North America and Europe is pending MXBMN NH The EOTec MX Multiplexer Multi Node Base Module MXBMN NH complies with the essential requirements of the following applicable European Directives and carries the CE marking accordingly EMC Directive EN 61326 1 2013 and CISPR 11 2009 A1 2010 MXBMN Regulatory Markings MXBMN NH Regulatory Markings The MX Multiplexer Multi Node Base meets the The MX Multiplexer Multi No
106. very I O module in the fiber optic network must have a mating module at the same address A match occurs when one Input Module has at least one Output Module at the same Module Address and is termed an Address Match When these modules are also of the 38 EOTec 2000 Multi Node MX Multiplexer User Manual same device type Analog Input Modules are matched with Analog Output Modules or Digital Input Modules are matched with Digital Output Modules this condition is termed a Device Match When connected I O modules have an Address Match and a Device Match the associate Module Status LED will be solid green for this Module ID When an I O module is connected into the network without a matching module the Module Status LED will be flashing green for this Module ID This only means that the connected I O module does not have an Address Match with another I O module so the diagnostic term Abandoned I O is used Correct this condition by putting the two intended matching modules on the same Module Address setting There are also other address conflicts which can be reported by the Module Status LEDs which will be discussed further in Chapter 3 2 4 If Analog and Digital module types are mixed MX420 with MXCC this creates a Device Conflict and the LED will be solid red for this Module ID Device conflicts can be corrected by matching Input and Output Modules of the same device type and using the same Module Addres
107. witches inside the Multi Node Base Module The Base module uses this address to properly route data flowing between all base stations in the fiber optic network as shown in Figure 7 I O modules can be assembled on either side of the Base module and in any order within each module stack See Chapter 3 2 for more installation information Multi Node pre Dry Contact Fiber Optic Base PY Relay Output Dry Contact I 4 20mA iti Relay Input 4 20mA Multi Mode Input Multi Node Dry Contact Fiber Optic Base Fiber Optic Base 420mA Output Relay Output Remote de aN Remote Figure 7 Multi Node I O Network Each EOTec MX Multiplexer module comes with LED indicators for local determination of system status In addition the Multi Node Base Module comes with alarm relay contacts that can be wired to provide status information at a remote location See Chapter 3 4 for more information on diagnosing failure 12 EOTec 2000 Multi Node MX Multiplexer User Manual 2 EOTec MX Multiplexer Hardware This chapter provides the specifications for all EOTec MX Multiplexer hardware and shares how it is designed to provide reliable operation in harsh industrial environments The MX Multi Node Base Module or Multi Node Base MXBMN is the brain of the module stack or Multi Node Station and provides a direct fiber optic connection between your local site and remote areas to be controlled or monitored It can be used to link tog
108. yed here for easy use in configuring each station A description section is also provided in the configuration worksheet to add any helpful comments that might apply for this network configuration For this example no Output Modules require any changes to port mapping The default setting E4 Hex will work on all Output Modules for this network example However if the need arises the Output Port Mapping field can be used to note and organize switch changes Output Port Mapping is demonstrated in Example 2 Chapter 3 2 7 46 EOTec 2000 Multi Node MX Multiplexer User Manual Station VO Module MXBMN Base Module hannel Select N Type Module Address Output Port Mapping Function Describe Connection gm oy a Manor D FE 2 1 inp Mare Remote 1 Den PotMagng 0 1 mxa200P2 F E E 4 21 Input Mate Remote 2 Default Port Mapping OO 1 0 MX420 OP2 F D E 4 34 Input Mate Remote 3 Default Port Mapping OO aa EE MA Station Remote Station 1 VO Module EE MXBMN Base Module Module Address Output Port Mapping Function Describe Connection 02 N N N Output Mate Control Room Port Mapping n a EE GR RE ee CRE I Station VO Module MXBMN Base Module Channel Select VO Type Module Address Output Port Mapping Function Describe Connection 0 xapa F E E 4 2 Output Mate Control Room Port Mapping na EE N EN ON N PS PS SE A PE EE P PS PS PS PS PS

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