Device description
Contents
1. 3 3 6 Service Button and LED SV LED state Description off normal operation and for about 7 s after power on red booting approx 7 s blinking red 5 Hz Time slice of about 2 s after booting allows manual reset of IP 9 address and Niagara platform access credentials to state of delivery TO Time slice of about 2 s after red blinking allows manual reset of blinking greens Hz Sedona application and kits to state of delivery Table 3 3 6 1 Service LED How to reset IP address access credentials and Sedona The Service button can be used in interaction with the Service LED to manually reset IP address Niagara platform access credentials and Sedona to the state of delivery If the Service button is pressed when the Service LED is blinking red and is held pressed for at least 3 s the IP address of ethO and the Niagara platform credentials are reset to the state of delivery If the Service button is pressed when the Service LED is blinking green and is held pressed for at least 3 s the Sedona app and Sedona kits are reset to the state of delivery 3 3 7 Ethernet Status LEDs Each Ethernet port has two LEDs to signalize its link and communication state LEDs o Speed Ea Sai E E E E Link Fig 3 3 7 1 Ethernet status LEDs 26 sysmik de Manual SCA 340 SCA 340 L Installation and Commissioning LED State Description yellow 100 Mbps Speed ter ease off 10 Mbps if link is active green elect2. IO Errors Technical Data Order Information Scalibur and Accessories Supported Inline Automation Terminals Glossary Third Party Software Bibliography 39 39 40 40 40 40 40 41 42 45 45 46 48 49 49 SCA 340 SCA 340 L sysmik de Introduction 1 Introduction Scalibur is a powerful modular controller for Niagara and Sedona Scalibur stands for scalability a major characteristic of this controller Scalability comprises several aspects 1 Scalable lO A Scalibur station consists of the Scalibur controller and up to 63 terminals of the modular Inline system The terminals are available in a wide variety of types digital and analog inputs and outputs with different numbers of channels as well as functional terminals for DALI light control pulse metering MBUS or serial interfaces 2 Scalable software Scalibur has been developed primarily for the Niagara AX framework While Niagara AX is extremely powerful it is not very well suited for real time applications In order to realize such applications with Scalibur too the Sedona framework has been ported to Scalibur Sedona applications run with fixed cycle times in the millisecond range Niagara station and Sedona application are created with the same engineering tool Workplace AX Beside the separate exclusive use of either framework the parallel use of Niagara AX and Sedona with seamless integration of the Sedona data points in Niagara AX is
3. Scalibur Modular Controllers SCA 340 SCA 340 L Manual Ss AY A 7A Revision 12 GmbH Dresden Disclaimer Impressum This manual is intended to provide support for installation and usage of the device The information is believed to be accurate and reliable However SysMik GmbH Dresden assumes no responsibility for possible mistakes and deviations in the technical specifications SysMik GmbH Dresden reserves the right to make modifications in the interest of technical progress to improve our modules and software or to correct mistakes We are grateful to you for criticism and suggestions Further information device description available software can be found on our homepage www sysmik de Please ask for latest information SysMik disclaims all warranties in case of improper use or disassembly and software modifications not described in this document or when using improper or faulty tools Commissioning and operation of the device by qualified personnel only All applicable regulations have to be observed SysMik and the SysMik logo are registered trademarks of SysMik GmbH Dresden Networking Together is subject to copyright of SysMik GmbH Dresden All other trademarks mentioned in this document are registered properties of their owners These and further trademarks are used in this document but not marked for better readability No part of this document may be reproduced or modified in any form without prior
4. SCA 340 SCA 340 L sysmik de 23 Installation and Commissioning 3 3 3 3 1 3 3 2 3 3 3 Operating Elements Overview Service Button RS 485 Termination Fig 3 3 1 1 Front view with display and operating elements Inline Supply LEDs US UM UL State Description US green voltage at segment circuit 24 V DC off no voltage at segment circuit UM green voltage at main circuit 24 V DC off no voltage at main circuit green Usk 24 V supply U logic supply OK UL off Upx UL not OK Table 3 3 2 1 Inline supply LEDs Process Status LEDs PL ST SE LED Description status of Niagara platform status of Niagara station status of Sedona Virtual Machine incl O server Table 3 3 3 1 Process status LEDs In normal operation all three LEDs are using the same signalizing method 24 sysmik de Manual SCA 340 SCA 340 L Installation and Commissioning 3 3 4 3 3 5 LED status Description off The process has not been started The process is running and needs less than 10 of processor time da A J blinking yellow 50 on time The process is running and needs between 10 2 s period and 50 processor time The process is running and needs more than 50 processor time 10 on time 90 on time Table 3 3 3 2 Process status LED behavior D
5. power supply of these terminals and their connected sensors and actuators Scalibur is a controller for the Inline IO system and unlocks the rich pool of Inline 1O terminals for building automation Inline is a modular IO system by Phoenix Contact to flexibly and quickly build up space saving automation stations An Inline station consists of a bus controller and a set of lO terminals chosen freely in terms of numbers type and sequential arrangement The bus controller runs the Inline station and has interfaces to the higher level controller Up to 63 IO terminals can be connected to a bus controller There are lO terminals for almost any purpose digital inputs and outputs with 1 2 4 8 16 or 32 channels per terminal Triac and relay outputs for switching signals or for higher loads analog inputs for measuring voltage current resistance or temperature with 2 4 or 8 channels per terminal analog outputs for voltage or current with 2 4 or 8 channels per terminal function terminals for complex IO operations or gateway functions DALI M Bus SO pulse metering serial interface supply and support terminals e g to realize separated voltage domains within an Inline station The overall width of the Inline extension terminals is 1 2 or 4 DU 1 DU division unit 12 2 mm or approx 0 48 in Inline terminals are provided with a pluggable wiring level enabling pre wiring and easy module exchange The mechanics of the syste
6. 6 Technical Data Processing unit Processor clock ARM Cortex A8 32 bit RISC processor 1 GHz DDR3 SDRAM 512 MiB eMMC 1 8 GB NVRAM 512 KiB buffered for 5 days RTC buffered for 5 days Connections 4x 10 100BaseT MDI MDI X crossover automatic Aging time default 330 s Isolation LAN1 2 3 4 vs module test voltage 1500 V AC 1 min 1 LAN vs LAN test voltage 1500 V AC 1 min RS 485 COM1 COM2 Max number of bus devices 256 1 8 unit load Max data rate 200 kbps Isolation RS 485 vs module test voltage 500 V AC 50 Hz 1 min RS 485 Port 1 vs RS 485 Port2 test voltage 500 V AC 50 Hz 1 min LON TP FT 10 twisted pair bus connection for free topology Transceiver TP FT 10 Isolation LON vs module test voltage 250 V AC 50 Hz 1 min 42 sysmik de Manual SCA 340 SCA 340 L Technical Data Connecting Inline automation terminals Max number of I O terminals per Inline station Max load of logic supply UL 2A Max load of analog supply Uana 0 5 A Max ampacity of potential routing contacts Un Us and GND Derating of logic supply and USB supply depending on mounting position Isolation General electrical data Supply voltage Upx 24 V DC Absolute limits 19 2 V to 30 V DC Current drain at nominal voltage without local bus terminals lsk lt 170 mA Current drain at nominal voltage with local bus terminals without Um and Us ln 2 lt 1 5 A 7 5 V
7. also supported 3 Scalable licensing The license model for Scalibur is very flexible a license comprises a certain number of devices and data points which are integrated with Scalibur These license packs contain 50 data point licenses per device license and are available as first time license 5 10 25 100 200 devices or as upgrade license 10 25 50 devices Sedona as open source project doesn t have any license fees 4 Scalable IP network Scalibur contains two logically separated IP interfaces and an integrated Ethernet switch with four external ports The configurable assignment of the Ethernet ports to the separate IP interfaces and the usage of the spanning tree protocol allows flexible topologies like daisy chain and redundant ring structures for both the backbone and the local control network 1 available Q1 2016 SCA 340 SCA 340 L sysmik de 6 Device and System Overview 2 2 1 2 1 1 Device and System Overview Hardware Functional Overview E Micro SD Local i gt Aye ocal bus a H c 0 ue LAN1 L 4 xx xx tt tt gt ES LAN2 f AV AV AV LAN3 RS 485 RS 485 on ak Al USB Y 24V U LON Bl Y y 24V U O i USB 0 FTA A Fig 2 1 1 1 SCA 340 L basic circuit d
8. logic supply loaded with 2 A and 24 V PK analog supply with 0 5 A no USB devices Connections Supply RS 485 TP FT 10 Type Spring cage terminals Rated cross section 0 08 mm to 1 5 mm 24 16 AWG Ampacity 8A Ethernet Type RJ45 shielded Width x height x depth 80 mm x 119 8 mm x 71 5 mm Weight approx 230 g 8 oz Environmental conditions Operating temperature 25 C to 55 C 32 F to 122 F Storage max 25 C to 85 C 4 F to 158 F temperature recommended 25 C to 35 C 4 F to 95 F Rel humidity 0 to 75 non condensing SCA 340 SCA 340 L sysmik de 43 Technical Data Protection standard IP20 EMC conformity IEC 61000 4 2 ESD 6 kV contact discharge 8 kV air discharge CENON A IEC 61000 4 3 immunity field 10 V m criterion A IEC 61000 4 4 burst 1 kV 2 2 kV criterion A criterion B IEC 61000 4 5 surge 0 5 kV asymmetric criterion A IEC 61000 4 6 conducted immunity 10 V m criterion A EN 55011 emission of ISE devices EN 55022 emission of ITE devices class A2 1 Functional isolation The isolation is bridged by an RC filter for EMC reasons Safety agency hazardous voltage barrier requirements are not supported 2 Functional isolation The isolation is bridged by a 300 V varistor for protection of the device Safety agency hazardous voltage barrier requiremen
9. of the device entry chose Browse my computer for driver software chose Let me pick from a list of device drivers on my computer select Network adapters as device type select Microsoft Corporation as manufacturer and Remote NDIS Compatible Device as network adapter and click Next pass warning Update driver warning with Yes close the notification window after successful device driver installation E Update Driver Software Unknown Device Select Network Adapter Ae Click the Network Adapter that matches your hardware then click OK If you have an par installation disk for this feature click Have Disk Manufacturer 2 Network Adapter Marvell EQ Remote NDIS based Internet Sharing Device Microsoft Remote NDIS Compatible Device Microsoft Corporation Matarala Tne 4 m E This driver is digitally signed Have Disk Tell me why driver signing is important Fig 3 2 6 1 Selecting device driver The Scalibur is now located under Network adapter as RNDIS Ethernet Gadget This acts as additional network interface which provides a local network access to the Scalibur 22 sysmik de Manual SCA 340 SCA 340 L Installation and Commissioning 3 2 6 USB The USB type A socket accepts USB end devices according to the standard USB 1 0 and USB 2 0 Beside this the device must also be supported by software esp driver
10. software components can access the lO terminals of the Inline system For reading input data this poses no problems For outputs and configuration however the different program parts could work against each other In order to achieve a predictable behavior of the lOs there is a channel wise priority control Each source can set a value with its source specific priority or release its access This release is using technology specific values Type Comissioning website Sedona AECE Digital output bool auto null null Analog output DALI control float auto nan not a number null Measuring range enum auto auto auto Table 4 5 1 Release values of priority control If several sources try to access the same IO channel the following ranking applies Rank Component 1 Comissioning website i e manual override in test mode 2 Sedona 3 Niagara local access 4 Niagara remote access Table 4 5 2 Ranking of priority sources The comissioning website has highest priority Manual override is always possible regardless of the other program components By leaving the comissioning page all overrides are automatically released Sedona and Niagara components do by default release their priority Only if they are configured or connected to other components the priority is actually used SCA 340 SCA 340 L sysmik de 37 Software Note Deleting or re addressing components does not automati
11. written agreement with SysMik GmbH Dresden Copyright O 2015 by SysMik GmbH Dresden SysMik GmbH Dresden Tel 49 0 351 43358 _0 Bertolt Brecht Allee 24 Fax 49 0 351 4 33 58 29 01309 Dresden E Mail Sale sales sysmik de E Mail Support service sysmik de Germany Homepage www sysmik de 2 sysmik de Manual SCA 340 SCA 340 L Contents Contents 1 Introduction 6 2 Device and System Overview 7 2 1 Hardware 7 2 1 1 Functional Overview 7 2 1 2 Processor Core 7 2 1 3 Ethernet 7 2 1 4 Serial Ports 7 2 1 5 USB 7 2 1 6 LON 8 2 1 7 Inline Local Bus Interface Modular IO Terminals 8 2 2 Software Overview 9 2 2 1 Scalibur System Shell 9 2 2 2 IO Server 9 2 2 3 Commissioning Web Server 9 2 2 4 Sedona Virtual Machine 10 2 2 5 Niagara Framework 10 3 Installation and Commissioning 11 3 1 Assembly 11 3 1 1 Dimensions 11 3 1 2 Mounting 12 3 1 3 Adding Inline Terminals 13 3 2 Connections 14 3 2 1 Connectors 14 3 2 2 Power Supply 15 3 2 2 1 How to Connect Power 15 3 2 2 2 Power Dissipation Calculations for a Scalibur Controller 17 3 2 2 3 Current Consumption Calculation for a Scalibur Station with Terminals 18 3 2 2 4 Derating of Terminal and USB Supply 18 3 2 2 5 Protective Devices of 24 V Main and Segment Supply Uy and Us 20 3 2 3 RS 485 and LON 20 3 2 4 Ethernet 21 SCA 340 SCA 340 L sysmik de 3 Contents 3 2 5 3 2 6 3 3 3 3 1 3 3 2 3 3 3 3 3 4 3 3 5 3 3 6 3 3 7 3 3 8 4 4 1 4 1 1
12. 1 1 N Device Manager of the SysmikScaloNetwork In the N Point Manager the default view of the points folder the available 1O channels can be displayed via Discover These can be inserted as proxy points to the station via Add Some data points have specific functions Measurement ranges of the analog input terminals can be configured with the additional property Ai Type of the proxy extension Counter values of the pulse metering terminal can be initialized with the action Init Counter of the proxy extensions sanma C NiagaraNetwork 1 objects Name Tye Out channel lel Di4 Boolean Point true ok 4 Fig 4 4 1 2 N Point Manager of a terminal component 4 4 2 Serial Interfaces The Scalibur has two serial RS 485 interfaces that are available as COM1 and COM2 for any serial protocols 34 sysmik de Manual SCA 340 SCA 340 L Software Further universal serial interfaces can be added via lO terminals of type IB IL RS UNI These terminals support the interface types RS 232 RS 485 and RS 422 which can be configured with Workplace AX via their associated terminal component in SysmikScaNetwork The serial interfaces of the IO terminals support all serial protocols except BACnet MS TP Terminals of type IB IL MBUS extend the Scalibur by serial interfaces according to the M Bus standard for connection of up to 30 M Bus slaves and are controlled with the Niagara AX M Bus driver The interface names of the seri
13. 2B010 Figure 3 1 3 1 Installation on the mounting rail A connection of Inline components to each other B connection check C plugging of the wiring level D Note While connecting the components to each other and to the mounting rail later please make sure that all feather keys and latches are properly snapped in Note Please consult the User Manual with regard to configuration and installation of the Inline product family see 3 SCA 340 SCA 340 L sysmik de 13 Installation and Commissioning 3 2 Connections 3 2 1 Connectors D 1 Micro SD card slot 8 Switches for RS 485 termination bias 2 Type label with device specific 9 Service interface information 3 Service button 10 Bus interface connector 4 Ethernet 4x 10 100BaseT 11 Supply connector 5 FE connector 12 Labeling field 2x 6 USB 1 mini USB USB OTG 13 Diagnostic indicators 7 USB2 14 End plate The FE connector is placed at the rear side of the controller it is not visible in the sketch Fig 3 2 1 1 Overview device connections 14 sysmik de Manual SCA 340 SCA 340 L Installation and Commissioning 3 2 2 3 2 2 1 Power Supply How to Connect Power The bus controller is operated with 24 V DC The bus controller is powered from this source and it generates the logic voltage for the logic circuit and the analog voltage for the analog circuit The logic circuit supplies the internal bus including the com
14. 3 SH1 G LON TP FT 10 NT1 Fig 3 2 4 1 RS 485 LON Interface terminal connections 20 sysmik de Manual SCA 340 SCA 340 L Installation and Commissioning 3 2 4 1 1 COM1 COM1 RS 485 data signal positive 1 2 COM1 COM1 RS 485 data signal negative 1 3 SH1 COM1 shield 2 1 COM2 COM2 RS 485 data signal positive 2 2 COM2 COM2 RS 485 data signal negative 2 3 SH2 COM2 shield E Ns LON TP FT 10 SCA 340 L only polarity independent Fig 3 2 4 2 Terminal assignment of interface connector For RS 485 the proper polarity has to be observed and bias and termination resistors have to be chosen properly Scalibur has fitting built in resistors which can be used via DIP switches The shield connections are internally capacitive connected to FE functional earth The connection is pluggable and includes two terminal points connected inside the plug for each bus line Thus the TP FT 10 bus can be wired in one line without additional terminals and the ICS can be removed without bus interruption While connecting LONWORKS technology based devices to the bus the LONMARK wiring guidelines 3 must be observed According to the network topology one or two network terminators such as SysMik ACC BT have to be attached If shielded cables are used the shield can be connected to the SH connector in order to avoid electrostatic charging The data bus is polarity independent More detailed inform
15. 4 1 2 4 1 3 4 2 4 2 1 4 2 2 4 2 3 4 3 4 3 1 4 3 2 4 3 3 4 4 4 4 1 4 4 2 4 4 3 4 4 4 4 5 5 1 USB OTG for local Access USB Operating Elements Overview Inline Supply LEDs US UM UL Process Status LEDs PL ST SE IO Status LED IO Communication LEDs COM1 COM2 LON Service Button and LED SV Ethernet Status LEDs RS 485 Termination Software Configuration Tools SCA System Shell Comissioning Website File Access via FTP Comissioning Scalibur IP Addressing Time and Time Zone Hardware Data Point Test Real Time Control with Scalibur and Sedona IO Access Modbus Platform Service Integration with Scalibur and Niagara Framework Local lO Access Serial Interfaces IO Remote Control Sedona Integration Concurrent Access to the lO Terminals Best Practices and Troubleshooting Performance and Resource Management 22 23 24 24 24 24 25 25 26 26 27 28 28 28 29 29 29 30 30 30 31 31 32 32 33 33 34 36 37 37 39 39 sysmik de Manual SCA 340 SCA 340 L Contents 5 2 5 3 5 3 1 5 3 2 5 3 3 5 3 4 5 3 5 5 3 6 7 1 7 2 10 Reliability of Nonvolatile Memory Diagnosis and Troubleshooting SCA System Shell Comissioning Website is not accessible IP Address unknown No IP Communication Unknown Niagara Platform Access Credentials Sedona Virtual Machine is not Starting
16. L DALI PWR DALI master with DALI supply 2897813 IB IL DALI DALI master extension terminal 2897910 IB IL DALI MM ROE ee DA SUP pim 2700605 IB IL DI 8 SO 8 SO counter inputs digital inputs 2897020 IB IL MBUS M Bus master for up to 30 meters 2701927 IB IL RS UNI serial interface 2700893 Power and segment terminals IB IL 24 PWR IN R supply of bus electronics UL Uana 2861674 46 sysmik de Manual SCA 340 SCA 340 L Order Information IB IL 120 PWR IN 120 V feed in 2861454 IB IL 230 PWR IN 230 V feed in 2861535 E spacer terminal to separate 120 V or IB IL DOR LV SET 230 V and 24 V 2861645 1 Part numbers of Phoenix Contact apply Table 7 2 1 Inline automation terminals supported by Scalibur 47 SCA 340 SCA 340 L sysmik de Glossary 8 Glossary FTP File Transfer Protocol to transfer files over IP network State less protocol for data transfer from a webserver to a web HTTP browser Channel for the communication of the Inline bus controller with the Localbus ee automation terminals within an Inline station Software framework Tridium Inc for web based automation and NiagaraAX management systems Sedona System platform to develop use integrate and manage embedded Framework devices Seamlessly integrated into Niagara framework Sedona Virtual Machine VM The Sedona Virtual Machine VM is an interpreted which is designed for portability It ex
17. a platform connection with the Niagara daemon under TCP IP Configuration Workplace AX via device connection with the Sedona application there App service gt plat only for primary interface as Sedona uses always only the primary interface Time and Time Zone The internal time is derived from a buffered RTC At delivery the buffer capacitor is usually discharged and the time at the first start of the Scalibur is set to midnight 2000 01 01 Time and time zone default Central European Time CET or Central European Summer Time CEST can be configured in several ways SCA System Shell see 4 1 1 Comissioning website via Settings gt Date Time see 4 1 2 Workplace AX via platform connection with the Niagara daemon under Platform Administration gt Change Date Time Workplace AX via device connection with the Sedona application there App gt service gt plat only time zone The time can be set by the Sedona application using the component DateTimeServiceStd from the kit datatimeStd Hardware Data Point Test Usually the electrical connection and the software integration of control stations are done by different persons and at different times Ideally the electrical installation mounting and cabling should be finished with a data point test and its according documentation This is supported by the comissioning webserver which clearly visualizes all input and output signals of the lO terminals If required output channels an
18. al terminals are assigned according to their position starting with COM3 A summary of all serial interfaces including their current use owner is available at Station Config Services PlatformServices SerialPortPlatformServiceNpsdk Example The screenshot shows an overview for a Scalibur controller with 4 serial ports total two from the controller itself and two added via serial terminals COM1 The first built in RS 485 interface is used by the MS TP port of the BacnetNetwork COM2 The second built in RS 485 interface is assigned to the ModbusSlaveNetwork COM3 The IB IL MBUS terminal at Inline position 7 is used as interface for the MbusNetwork COM4 The IBILRS UNI terminal at Inline position is used by the ModbusAsyncNetwork To this end the property RsType of the terminals PropertySheet in SysmikScaNetwork is set to RS 485 8 WorkPlace AX lola Ea Fie Edit Search Bookmarks Tools Window Help 4 gt a DEAR ojo Hill JEE Services E SerialPortPlatformServiceNpsdk Serial Port Platform Service Npsdk O Platform Service Description O O Min Timeout kd Station empty E O comi Serial Port Npsdk E ea Config O Owner mstp1 EH services O O OsPortName dev tty02 amp UserService O O Port Index E com2 Serial Port Npsdk O Owner O O Os Port Name JobService Sa AlarmService G HistoryService AS AuditHistory O O Port Index EA LogHistory E O com3 ae ProgramService O O Owner plis Backu
19. ation can be found in the manual of the used transceiver 2 Ethernet The Scalibur provides four Ethernet interfaces with built in switch and the following properties shielded RJ45 connectors 10 100BaseT automatic detection automatic MDI MDI X crossover detection Pint RD Pin2 RD Pin3 TD Pin4 not used Pin5 not used Pin6 TD Pin7 not used Pin8 not used Figure 3 2 5 1 Terminal assignment of Ethernet connector SCA 340 SCA 340 L sysmik de 21 Installation and Commissioning The 10 100BaseT Ports are able to recognize and to correct an interchanged receive path pair RD RD Thus either crossover or patch cable can be used no matter if the remote station is another end device a switch or a hub Note The maximum distance of 100 m between Ethernet devices can only be achieved using cables from category 5 on 3 2 5 USB OTG for local Access The local access is a connection between Scalibur and a PC which works regardless of the device settings especially IP address Simply connect a Windows PC to the Scalibur with a standard Mini USB cable Installation of PC driver If you connect the Scalibur to your PC for the first time Windows detects a new device and shows this in the Device Manager as RNDIS Ethernet Gadget below Other devices Now the proper driver has to be installed manually select Update driver software in the local menu
20. available data point integration over a plethora of open automation protocols LON BACnet M Bus Modbus and others with data normalization system functions scheduler alarming trend log web visualization enterprise interfaces oBIX data bases and many more 10 sysmik de Manual SCA 340 SCA 340 L Installation and Commissioning 3 Installation and Commissioning 3 1 Assembly 3 1 1 Dimensions Width x Height x Depth 80 mm x 119 8 mm x 71 5 mm 3 15 inch x 4 72 inch x 2 81 inch A SCALIBUR SCA 340 GmbH Dress RS 485 Termination 21 y wu g6 71 5 mm 2 81 80 mm 3 15 lt gt lt Fig 3 1 1 1 Scalibur dimensions SCA 340 SCA 340 L sysmik de 11 Installation and Commissioning 3 1 2 Mounting Preferred mounting position is horizontal i e on a horizontal DIN rail which is attached to a vertical wall For all other mounting positions a derating has to be observed see chapter 9 Note The air vents have to be kept free with a sufficient spacing to other components to ensure optimal air ventilation The device is designed for easy snap in mounting on 35mm x 7 5 mm DIN EN 60715 rails formerly DIN EN 50022 Note The DIN rail should be attached to a mounting plate or an even back plane for best stability Suitable fixtures like end
21. cally release the priority of this channel Of course a priority could be manually released by setting explicitly to the release value Restarting the Scalibur re initializes releases the complete internal priority array Depending on the data point type the following default values apply if all priorities are released that is no software component accesses this channel Digital output output signal off Analog output output signal 0 0 V DALI control ballast 0 0 Analog input measurement range 0 10 V if applicable Table 4 5 3 Default values of priority control Some actions have command character These do not change the priority level but are processed in their order of occurrence or suppressed completely in case of insufficient priority Such commands are Initialization of counter values of the pulse metering terminal DALI lighting control commands Initialization read and write operations of serial terminals For these cases it is up to the application programmer to prevent unwanted concurrent accesses from different sources 38 sysmik de Manual SCA 340 SCA 340 L Best Practices and Troubleshooting 5 1 5 2 5 3 Best Practices and Troubleshooting Performance and Resource Management All software processes share the common resources processor time memory The available resources can be shown in Workplace AX using all accesses Platform Platform A
22. clamps or grounding terminals have to be used at both ends of the station to prevent sliding off the rail Note To ensure easy unlocking of the Ethernet connectors use only clamps at the bus controller side of the station that do not protrude more than 30 mm from the rail Note Only use clean and corrosion free mounting rails in order to ensure a safe contact between the FE terminals 12 sysmik de Manual SCA 340 SCA 340 L Installation and Commissioning 3 1 3 Adding Inline Terminals An Inline station is assembled by plugging the individual components to each other thus establishing the potential and bus signal connection between the individual components of the station Figure 3 1 3 1 shows the procedure of mounting a terminal Disconnect power to the entire station Mount the electronics base onto the rail A Adjacent terminals are interlocked by their feather keys keyways B First insert the feather keys of the local bus into the keyways of the preceding terminal B1 Guide the feather keys along the keyways until they lock appropriately B2 Ensure that the feather keys are properly connected C2 C1 shows the common mistake that the feather keys are not inside their keyways After mounting all electronics bases install the connectors onto their respective bases First insert the front detent D1 Then push the connector onto the electronics base until the rear detent locks properly 645
23. d also their configuration like measuring ranges can be manually overridden Thus a data point test doesn t need any application software By leaving the comissioning page either manually or by timeout all overrides are reverted 30 sysmik de Manual SCA 340 SCA 340 L Software 4 3 4 3 1 e D 10 0 7 115 sca ilt_visual html lang en SCA Manual Override 3 AO 4 U SF 4 AI TEMP 4 RTD lt lt Back Terminals DI 32 DO 16 AO 4 U SF AI TEMP 4 RTD DO 4 DI 4 Table 4 2 1 Testing data points via comissioning webpage Real Time Control with Scalibur and Sedona Sedona allows to program control applications that run with configurable cycle times Niagara Workplace AX is used as engineering tool The programming follows a component based approach The application consists of components which are parameterized and connected with each other With the textual programming language Sedona similar to C and Java it is even possible to create own Sedona components An introduction to Sedona offers 4 while further more detailed information can be found in 6 IO Access Hardware data points can be accessed via the terminal components of the SysMikScalo kit There is a component for each terminal type with its specific slots that allow to access inputs and outputs and to parameterize the terminal The component Scalo works as folder into which the hardware related component
24. dministration Station Views gt Resource Manager Sedona App gt service gt plat The system load should be below 100 because otherwise the relevant timing cycle times can t be ensured Optimize in this case your application i e by increasing Sedona task cycle time or intervals of the Niagara station e g poll intervals Please be aware that every kind of communication creates processor load too so leave a margin for that Reliability of Nonvolatile Memory Scalibur contains a highly integrated Flash memory for use in the industrial temperature range Physically caused the reliability is depending on the number of writes and the environmental temperature frequent writing of large data blocks wears out the memory and a high environmental temperature reduces the guaranteed data retention time The stress on the memory depends heavily on the application Occasional write accesses due to programming and software upgrades cause writing of large data blocks to the Flash However these are almost negligible in comparison to the amount of data which is written in regular intervals like logging of history data or StationSave The write load caused by history data can be shown via Station gt Config gt Services gt PlatformServices gt DataRecoveryService Size and write frequency of history data should be configured in such a way that writing of a data recovery block happens less than once a minute StationSave should be perfo
25. ecutes code created by the Sedona programming language Device to connect several network segments Each port can receive Switch data and forward it selectively to other ports based on source and target address DU Division unit 12 2 mm in the Inline system Telnet Network protocol for character based data exchange in IP networks TP FT 10 Channel type specified by LonMark twisted pair technology with free topology based on CEA 709 most common channel type 78 kBit s Webserver Server service making the protocols of the Internet technologies available e g HTTP Webservices Workplace AX Services based on Internet technologies which use XML documents for data exchange e g XMP SOAP Graphic configuration system for Niagara AX Table 8 1 Glossary 48 sysmik de Manual SCA 340 SCA 340 L Third Party Software 9 Third Party Software This product contains open source software and other third party software A document with a list of embedded software components according to the documentation obligations of the respective license conditions is on the web server of the device The document can be accessed from the device with a Web browser by using the URL lt device IP address gt lt HTTP Port gt licenses htm On delivery those reads URL 192 168 1 1 81 licenses htm 10 Bibliography 1 2 S 4 5 6 7 8 User manual Automation terminals of the I
26. formation 7 2 Supported Inline Automation Terminals Digital input terminals IB IL 24 DI4 ME 4 inputs 24 V 2863928 IB IL 24 DI8 HD 8 inputs 24 V 1 DU 2700173 IB IL 24 DI16 ME 16 inputs 24 V 2897156 IB IL 24 DI32 HD 32 inputs 24 V 2862835 IB IL 120 DI 1 1 input 120 V 2861917 IB IL 230 DI 1 1 input 230 V 2861548 Relay terminals IB IL 24 230 DOR 1 W PAC 1 change over contact 230 V 3A 2861881 IB IL 24 48 DOR 2 W PAC 2 change over contact 48 V 2 A 2863119 IB IL 24 230 DOR 4 W PAC 4 change over contact 230 V 3A 2861878 IB IL 24 230 DOR 4 HC PAC Sa nap ear ONT OT 2897716 Digital output terminals IB IL 24 DO 4 ME 4 transistor outputs 24 V 0 5 A 2863944 IB IL 24 DO 8 HD 8 transistor outputs 24 V DC 0 5 A 1 DU 2700172 IB IL 24 DO 16 ME 16 transistor outputs 24 V DC 0 5A 2897253 IB IL 24 DO 32 HD 32 transistor outputs 24 V DC 0 5 A 2862822 TRIAC terminals IB IL DO 1 AC 1x TRIAC 12 253 V AC 0 5 A 2861920 IB IL DO 4 AC 1A 4 x TRIAC 12 253 V AC 1 A 2861658 Analog input terminals IB IL Al 2 SF ME 2 x voltage current 2863944 IB IL Al 8 SF 8 x voltage current 2861412 IB IL TEMP 2 RTD 2 x resistance temperature 2861328 IB IL Al TEMP 4 RTD 4 x voltage resistance temperature 2897952 Analog output terminals IB IL AO 2 U BP ME 2 x voltage 2863957 IB IL AO 4 U SF 4 x voltage 2692050 IB IL AO 4 8 U BP 8 x voltage 2878036 Function terminals IB I
27. iagram Processor Core The processor core is made up of a 1 GHz ARM Cortex A8 CPU 512 MiB RAM 1 8 GB Flash 512 KiB SRAM and an RTC SRAM and RTC are buffered for a power failure of 5 days The internal Flash memory can be extended with a microSD card Ethernet The integrated Ethernet switch has 4 external ports which can be assigned independently to one of the two separate IP interfaces By default delivery en0 is assigned to LAN3 and LAN4 and en1 with LAN1 and LAN2 Serial Ports Both RS 485 ports have switches for bias and terminating resistors and are galvanically isolated from each other and the rest of the circuit Further serial interfaces may be added using modular IO terminals M Bus RS 232 RS 485 RS 422 USB USB 1 is a USB OTG port with Mini USB socket and is used for installation and maintenance Connected to a PC it allows to control the device via console and to access the internal installation web site for device configuration and data point test SCA 340 SCA 340 L sysmik de 7 Device and System Overview The second USB port USB 2 allows to connect USB end devices LON The SCA 340 L has a LON interface according to the CEA 709 standard to connect directly to LonMark TP FT 10 networks Inline Local Bus Interface Modular lO Terminals The local bus interface allows to connect up to 63 modular lO terminals This interface comprises the communication channel to the lO terminals as well as the
28. imited to 87 which means 2 35 W Supposed is fully loaded with the max allowed 2 A then the USB ports can support a maximum of 0 5 A p O87 Pv 1V h USB 0 7 V 235W 2W lat SGA 0 7 V SCA 340 SCA 340 L sysmik de 19 Installation and Commissioning Example 2 Other mounting positions For an environmental temperature of 45 C 113 F and non horizontal mounting using additionally a USB device with 200 mA the power dissipation is limited to 70 i e 1 89 W Therefore the max current from U is _ 0 7Py 0 7 V x lysg ee 1V 1 89 W 0 14 W hs 1 754 3 2 2 5 Protective Devices of 24 V Main and Segment Supply Uy and Us Surge overvoltage Input protective diodes can be destroyed by permanent overload Polarity reversal Parallel diodes In case of wrong polarity a high current is flowing which is blowing the external fuses Segment supply and main supply are related to the same ground potential Note Each 24 V voltage supply must be fused externally The power supply unit must be capable of supplying a current four times the nominal value of the external fuse to reliably blow the fuses in case of an error 3 2 3 RS 485 and LON The interface connector provides terminals for both RS 485 interfaces and for SCA 340 L only the LON TP FT 10 interface AAA COM 12 E RS 485 24 RS 485 COM1 56 COM2 12 22 comi G COM2 13 2
29. is automatically receiving IP settings from the Scalibur DHCP server The IP address of the Scalibur is 172 16 0 10 in this virtual network The local access offers several services and protocols to the PC for configuration and diagnosis Telnet 23 Telnet client SCA system shell HTTP 8080 Web browser comissioning website FTP 21 FTP client file transfer Table 4 1 1 Protocols of local access 4 1 1 SCA System Shell The SCA System Shell allows to configure fundamental settings of the Scalibur To this end the PC is connected via USB OTG to the Scalibur and then a Telnet client is used on the PC to establish a Telnet session with the Scalibur address 172 16 0 10 port 23 The SCA System Shell shows host ID version information of several software components the current time and the IP addresses of the Scalibur A number based menu allows to perform different actions 1 Update System Time configure current system time 2 Update IPv4 Settings configure IP addresses 3 Ping IPv4 Host ping an IP address from the Scalibur 4 Update IPv6 Settings configure IPv6 addresses 5 Start Ftp start FTP server 6 Sedona Niagara Enable activate deactivate Niagara and Sedona 7 IO Server configure IO server port number remote address 8 Reboot reboot Scalibur 9 Sedona Factory Default reset Sedona app and Sedona kits to state of delivery 28 sysmik de Manual SCA 340 SCA 340 L Software 4 2 10 Reset Platform Credentials reset platform crede
30. lable in the Scalibur too BACnet IP BACnet MS TP only at COM1 and COM2 LonWorks IP852 LonMark TP FT 10 only SCA 340 L Modbus TCP Modbus RTU M Bus KNX IP SNMP oBIX Sedona and many more Data points from different sources can be integrated and connected using these communication protocols Niagara offers a rich set of processing and system functions like trend log alarming scheduling web visualization report generators and interfaces to e mail SMS data bases and other All the engineering is done with a single tool Workplace AX Local lO Access The components of the module sysmikScalo allow to access the lO terminals This follows consequently the approach of the Niagara Driver Framework Network Device Point SysMikScaNetwork Terminals Data points IO channel From the Driver Manager the default view of Station gt Config gt Drivers a SysmikScaloNetwork is created via New In the N Device Manager the default view of the SysmikScaloNetwork the connected terminals can be detected via Discover The detected terminals can be inserted to the station via Add SCA 340 SCA 340 L sysmik de 33 Software E 8 objects Discovery Base Name Terminal TerminalType rl m 132 1 m D016 Ed a04 H A4 DO4 DI4 E MBus RsUni Database 3 objects Name e DI4 6 Sysmik Sca Io Di4 ok 6 E RsUni_8 Sysmik Sca lo Rs Uni ok 8 DO4_5 Sysmik Sca Io Do4 fol 5 J Add Fig 4 4
31. m also allows exchanging terminals without complete dismantling of the station Scalibur determines type and function of all supported terminals automatically thus certain in and output functions can also be created without a previous configuration of the station which is especially helpful for commissioning tests sysmik de Manual SCA 340 SCA 340 L Device and System Overview 2 2 Software Overview Scalibur is using a Linux operating system which runs several applications in parallel Niagara Eco System niagara Supervisor remote engineering WM WorkPlace local engineering operation Niagara network FOX SOX local installation gt ES Web Server sedona PEZ opacnet AI gt oabus pa KNX Manual Override Real Time Processing Station Integration 10 server Inline Modular and more functional drivers analoglO digitallO seriallO maki Bus MP2 8uS Fig 2 2 1 Scalibur software structure 2 2 1 Scalibur System Shell The Scalibur System Shell is accessible only via the local USB OTG port and is used during comissioning to configure basic settings like IP address or as maintenance access if IP address or passwords have been lost 2 2 2 IO Server The lO server controls the modular Inline terminals of the Scalibur station and manages concurrent accesses to the hardware data points Niagara and the IO server communicate via an TCP connection This allows to control lOs rem
32. munication chips of all connected automation I O terminals The analog circuit provides an auxiliary supply for analog signals Note While connecting the automation terminals please observe the derating of the logic voltage the supply of the analog terminals and the maximum ampacity of the terminals Furthermore the bus controller includes connections for the supply of the mains and segment voltage of the Inline station Fig 3 2 2 1 1 shows the basic circuit for the connections of the power supply A B _ re Br cke Jumper 3 Ug Fig 3 2 2 1 1 Supply of Un Usx and Us from different sources A and from a common source B Note If Us Un and Us are to be supplied from a common source the fuse protection of the individual sections with regard to their supply requirements has to be observed Note The current passing through terminals and potential routing contacts must not exceed 8A The Functional Earth ground FE is connected to the potential routing contacts and is automatically grounded if the bus controller is snapped on a grounded mounting rail The function of FE is to discharge interferences SCA 340 SCA 340 L sysmik de 15 Installation and Commissioning Note Functional earth ground 1 4 and 2 4 has to be connected additionally via 1 5 mm wire AWG 15 and grounding terminal to the mounting rail see Fig 3 2 2 1 2 Fig 3 2 2 1 2 Connecting functional earth g
33. n lysg luss1 lusp2 0 24 The current consumption of the connected terminals can be found in their manuals The following rules of thumb apply The current provided by Uana influences the total current directly The current provided by U applies to the total current with a factor of 0 36 The following formula applies Ik la l x 0 36 la current from Uana max 500 mA I current from U max 2 0 A See the according datasheets in order to determine the current consumption of the connected actuators and sensors For an estimation it is often sufficient to check whether the supply can be provided completely by the Scalibur that is without power or boost terminals Without power and boost terminals and regardless of the circuits Uy und Us the maximum current consumption of the Scalibur with connected terminals is 1 7 A In addition there are the current requirements of the sensors and actuators whereas the current through feather keys and keyways is limited to a maximum of 8 A Note When selecting an external power supply plan sufficient reserves also into account that it could come to a current increase to a multiple of the rated current in the moment of turn on caused by input capacities Power supplies with over current shut down must have a sufficient response delay to avoid start up problems Derating of Terminal and USB Supply Because USB and the Inline terminals are supplied by Scalibur s internal power s
34. nline product range IL SYS INST UM E Phoenix Contact LONWORKS FTT 10A Free Topology Transceiver User s Guide Echelon Corporation LONWORKs Wiring Guidelines SysMik GmbH Dresden First Steps with Sedona 1 2 SysMik GmbH Dresden www tridium com www sedonadev org www phoenixcontact com www sysmik de SCA 340 SCA 340 L sysmik de 49
35. ntials to default user sysmik password intesa x Exit exit Telnet session Comissioning Website The comissioning website allows to configure the Scalibur and to access data points of connected IO terminals To this end a PC is connected via USB OTG to the Scalibur and the following URL is entered in the address field of the web browser 172 16 0 10 8080 The page Overview shows host ID and version information of several software components Page Settings allows to configure several settings Network to configure IP addresses Webserver to configure the port at which the restricted webserver without device settings is accessible Date Time to configure current time and time zone O Server to configure the lO server port number remote access Run to activate deactivate Niagara and Sedona On the page Terminals the data points of the connected IO terminals can be observed and manually overridden see 4 2 3 The webserver hosts further web pages which are alternatively also available via Ethernet DALI configurator to assign addresses to DALI ballasts connected via DALI terminals and configure them User defined visualization pages which are created using Sedona programming 4 File Access via FTP The Scalibur has an FTP server to access the file system This can be used to load software updates from the PC to the Scalibur The FTP server can only be activated from the SCA System Shell see chapte
36. oller caused by the load on USB1 and USB2 max 500 mA each Puss 0 7 V x lusg1 lussz Prer power dissipation of the bus controller caused by the Inline lO terminals Pperi 10 Vx l I current consumption of UL Note The factors 1 1 V und 0 7 V result from the electrical efficiency of the internal power supply unit Sample calculation Power dissipation of a Scalibur in case of the maximum possible current drawn from U and a USB memory stick with 0 1 A current consumption Psca 4 1W 0 7Vx0 1A4 10Vx20A Psca 4 1 W 0 07 W 2 0 W Psca 6 17 W SCA 340 SCA 340 L sysmik de 17 Installation and Commissioning 3 2 2 3 3 2 2 4 Current Consumption Calculation for a Scalibur Station with Terminals To find a suitable external power supply the current consumption of the entire Scalibur station has to be considered lis Isca lusg k las lis current consumption of the entire Scalibur Inline station Isca current consumption of the Scalibur lysg current consumption of connected USB devices lx current consumption of connected terminals las current consumption of sensors and actuators fed by the Inline station The current consumption of a Scalibur without terminals is maximum 170 mA Isca 0 17 A Please consult the manual of the connected USB device to find out the actual current draw from USB The respective USB currents luse and luss2 are weighted by a factor of 0 24 resulting in the equatio
37. otely from another Niagara station The remote access can be limited or disabled by the setting of the IP address of the controlling station 2 2 3 Commissioning Web Server The commissioning web server is exclusively accessible via the local USB OTG port It presents web pages to commission the device setting IP addresses and time zone reading state of inputs and setting output states of the data points of the local IO terminals for test purposes SCA 340 SCA 340 L sysmik de 9 Device and System Overview 2 2 4 2 2 5 Sedona Virtual Machine The Sedona virtual machine SVM runs the Sedona application in real time with configurable cycle time The engineering tool Workplace AX connects to the SVM to modify the application load updates or create backups of the application Platform specific kits provide access to the lO terminals and also to system settings like IP addresses and Modbus settings A Modbus TCP server and a Modbus TCP client Modbus RTU master are integrated and are used to exchange data with other Sedona controllers Also Niagara can be deactivated here Niagara Framework Scalibur can be parameterized with Workplace AX and a platform connection to the Niagara daemon This includes loading of software updates and of a station Niagara application which can be run automatically by the Niagara daemon A Workplace AX connection to a station is used to modify the station All features of the Niagara framework are
38. pService O O OsPort Name pE la O Port Index E PlatformServices cs E O coms loe 0 Ove nipservice D O OsPortName raunioe i bal DataRecoveryService O Port Index i imag SerialPor tPlatformServiceNpsdk E Drivers io Fig 4 4 2 1 SerialPortPlatformServiceNpsdk SCA 340 SCA 340 L sysmik de 35 Software 4 4 3 WE Drivers WE SysmikScaloNetwork E RsUni_8 Sysmik Sca lo Rs Uni 0 Suns 0 O Enabled O tue 7 SN E Health Ok 23 Jul 15 11 15 AM CEST E A Alarm Source Info Alarm Source Info E Patrreaenc Points Sysmik Sca Io Point Device Ext CA le O O RsType Rs485 gt Er Fig 4 4 2 2 Interface configuration of IB IL RS UNI IO Remote Control The SysmikScaNetwork sets up a TCP connection to an lO server to access the IO terminals The property Address defines address and port of this server Default is the local address 127 0 0 1 2015 which establishes contact to the local lO server But it is also possible to connect to an lO server of a different device by configuring its address here sE WorkPlace AX E File Edit Search Bookmarks Tools Window Help 4 a D 0 i 2 0 B a ig LB oe 10 0 7 115 empty Station empty aF Drivers WE SysmikScaloNetwork 127 0 0 1 2015 O Ip Address C wrspeated gars 465536 ca lo Di4 Fig 4 4 3 1 Configuration of the IO server to be contacted To prevent unwanted remo
39. r 4 1 1 and is exclusively accessible via the USB OTG virtual network connection IP address 172 16 0 10 port 21 After restart of Scalibur the FTP server is always inactive Comissioning Scalibur Scalibur comes with a default configuration and settings like IP addresses time time zone and others have to be specifically configured The following Scalibur software components are active The SCA System Shell expects input The IO server detects the connected lO terminals and opens its interface for comissioning website Sedona and Niagara The comissioning webserver hosts the comissioning website A minimum Sedona application provides a SOX server to allow a device connection from Workplace AX user admin no password SCA 340 SCA 340 L sysmik de 29 Software 4 2 1 4 2 2 4 2 3 The Niagara daemon is ready for a platform connection with Workplace AX user sysmik password intesa Though there is no station running these can be loaded later during the Niagara AX commissioning Changing IP addresses or time zone becomes effective only after reboot IP Addressing Scalibur s default IP address of the primary IP interface eth0 is 192 168 1 1 the subnet mask 255 255 255 0 The secondary IP interface eth7 is deactivated by default There are several ways to configure the IP settings SCA System Shell see 4 1 1 Comissioning website via Settings Network see 4 1 2 Workplace AX vi
40. rical connection to network Link short off packet transmission permanent off no electrical connection to network Table 3 3 7 1 Ethernet port LEDs 3 3 8 RS 485 Termination RS 485 networks are using bus topology and are terminated at both ends with a termination resistor Additionally the data lines are pulled once with bias resistors to a defined idle state The Scalibur has built in resistors for termination 120 Q and biasing 510 Q of COM1 and COM2 according to the BACnet MS TP specification Each resistor can be separately activated via DIP switches NS ft RS 485 gt Termination Fig 3 3 8 1 Assignment of DIP switches to RS 485 termination SCA 340 SCA 340 L sysmik de 27 Software 4 Software Note Scalibur factory defaults Ethernet ethO LAN3 LAN4 eth1 LAN1 LAN2 Platform Credentials Sedona Credentials 192 168 1 1 subnet mask 255 255 255 0 disabled sysmik intesa admin no password 4 1 Configuration Tools Fundamental device settings are vital to the device operation and should be protected carefully To prevent unwanted accesses from the network while offering a stable configuration access which is independent of the current IP settings the Scalibur offers a local access via USB OTG see chapter 3 2 5 The connected PC is getting another virtual network adapter which is connected to the Scalibur and
41. rmed much less than once per hour Regarding the environmental temperature the defined maximum values in chapter 6 must not be exceeded and the mounting position has to be observed see chapter 3 1 2 Diagnosis and Troubleshooting Scalibur is a very complex device with many functions and interfaces This complexity leads to many possible misconfigurations in practical use Most mistakes arise from connections with other devices or components Therefore the controller should not be diagnosed isolated but in context with the complete system Several tools allow to locate possible reasons for failures power LEDs see 3 3 2 software status LEDs see 3 3 3 O status LED see 3 3 4 SCA 340 SCA 340 L sysmik de 39 Best Practices and Troubleshooting 5 3 1 5 3 2 5 3 3 5 3 4 5 3 5 communication LEDs see 3 3 5 diagnosis LEDs of the connected IO terminals Service LED see 3 3 6 Ethernet status LEDs see 3 3 7 Additionally Niagara provides powerful tools to analyze the communication in connected automation networks Before starting a detailed analysis make sure that the device is properly wired supplied and has finished booting Check especially fall lO terminals are properly interlocked and connected by their feather keys keyways if the mounting rail is properly grounded if the functional earth connector of the device is connected using a 1 5 mm AWG wire with the mounting rail via a ear
42. round FE of Scalibur Manual SCA 340 SCA 340 L 16 sysmik de Installation and Commissioning 3 2 2 2 24 V DC segment supply segment circuit The supplied voltage 1 1 Us is lead to the automation terminals via the potential routing contacts Ugk 24 V DC bus controller supply logic supply UL and analog 21 supply Uana 12 22 Usk Um Uy 24 V DC main voltage main circuit The supplied voltage is Eip lead to the automation terminals via the potential routing contacts Reference ground for the internal bus and automation terminals 1 3 2 3 GND logic and analog circuit and for the main and segment supply main and segment circuit Functional ground Connecting the functional ground to this terminal point is mandatory see above The terminal point is internally connected to the potential routing contacts and the FE contact at the back side of the enclosure 1 4 2 4 FE Table 3 2 2 1 1 Terminal assignment of supply connector Power Dissipation Calculations for a Scalibur Controller The power dissipation of the bus controller equals the sum of the power requirements of the bus controller itself and the power loss of the internal power supply for the whole Inline station Psca Pot Pusat Ppenri Psca power dissipation of the bus controller Po power requirements for operating the bus controller without terminals and any external load 4 1 W Puss power dissipation of the bus contr
43. s are added Furthermore it provides an Action Restart JO to restart the lO server Each terminal component has a property Terminal which defines the terminal position The first terminal directly at the Scalibur has position 1 and so on Some terminal components contain further parameters e g measuring ranges for analog input terminals or actions e g counter initialization of pulse metering terminals SCA 340 SCA 340 L sysmik de 31 Software Fr AE WorkPlace AX Fie Edit Search Bookmarks Tools Window Help il App a Pee fe es esscro 008 I R B gt O my nemork 0 O veta O O Terminal E Sedona Tools O O uti App O O out2 HD service Er Scalo O outs Soma O O outs 3 Scalo 36 B Table 4 3 1 PropertySheet view of a terminal component 4 3 2 Modbus Via Platform Service a Modbus TCP server can be started for the Sedona Virtual Machine which hosts the following data points 10 000 coils digital outputs 10 000 discrete inputs digital inputs 10 000 holding registers analog outputs 10 000 input registers analog inputs The Sedona application has access to these data points via components of the kit SysMikModbusServer Additionally with components of the kit SysMikModbusClient the Sedona application can act as Modbus TCP client or Modbus RTU master to read and write data points of remote Modbus devices 4 3 3 Platform Service The platform
44. service Sedona gt App gt service gt plat is a mandatory element of any Sedona application and allows device specific configurations Timezone time zone e g Europe Berlin P Addressing p Addressing static or DHCP Ip Address Ip Net Mask subnet mask Ip Gateway gateway address Ip Dns1 Ip Dns2 lp Dns3 Domain Name Server Sntp Address SNTP server address Modbus TCP server Modbus Port 0 to deactivate Modbus server Unit ID 32 sysmik de Manual SCA 340 SCA 340 L Software 4 4 4 4 1 Modbus RTU Modbus Rtu Enabled Modbus Rtu Baud Modbus Rtu Parity Modbus Rtu Stop Bits Niagara enabled in case the parallel operation of Niagara and Sedona is not wanted Niagara can be deactivated or again be enabled loPort TCP port number of the lO server loRemoteAddr to prevent an unwanted remote control of Scalibur IOs by other Niagara stations a remote control address can be configured Default is 255 255 255 255 which allows remote control from any IP address It is possible to allow remote control only for a specific IP address by setting the entry to this specific IP address An invalid IP address empty string deactivates remote control completely All configurations require a restart of the Scalibur to become effective Integration with Scalibur and Niagara Framework The Niagara framework contains many communication protocols which are automatically avai
45. te control accesses configure the allowed remote control address in Workplace AX via Station gt Config gt Drivers gt SysmikScaloNetwork gt localPlatform gt loRemoteAddr Address setting Description 255 255 255 255 any IP address can access the lO server default valid IP address IO server accepts only accesses from this IP address invalid address empty string remote control deactivated Table 4 4 3 1 Address settings for IO server access Furthermore the port number of the lO server can be defined via Station gt Config gt Drivers gt SysmikScaloNetwork gt localPlatform gt lo Port 36 sysmik de Manual SCA 340 SCA 340 L Software 4 4 4 4 5 Fe WorkPlace AX oje Fie Edit Search Bookmarks Tools Window Help 4 gt O M2 20 Hih 3 e 10 0 7 115 empty Station empty E Config TiDrivers Fi SysmikScaloNetwork 2 localPlatform E localPlatform Sysmik Sca Io Platform O O Sedona Enabled Orue v 4 0 O loPort 1o Remote aer E D04_5 O locala tform Fig 4 4 3 2 Configuration of IO server Sedona Integration Data points of the local Sedona application can be added to Niagara via the Sedona driver If a parallel operation of Niagara and Sedona is not desired Sedona can be deactivated via Station gt Config gt Drivers gt SysmikScaloNetwork gt localPlatform gt SedonaEnabled Concurrent Access to the IO Terminals Several
46. thing clamp if the LEDs UM US UL are permanently on if the power supply voltage is within the allowed tolerance range A good indicator are the tree software status LEDs see 3 3 3 Only if they are regularly blinking the boot process has finished SCA System Shell Comissioning Website is not accessible Both of these need an USB cable from the PC USB port to the Mini USB port of the Scalibur Please verify that the cable is not damaged and is properly plugged into both sockets Check if the Device Manager shows the device Remote NDIS Compatible Device is shown as Network adapter If not re install the device driver see 3 2 5 IP Address unknown The IP addresses of the Scalibur can be shown and modified via the SCA System Shell or the comissioning website Both accesses work independent of the current IP settings via a local USB connection see 4 1 No IP Communication The command ping allows to test the Ethernet connection between two devices The SCA System Shell provides a ping function Please check first the proper connection of the Scalibur to the Ethernet using the Ethernet status LEDs Then the IP addresses and subnet masks of all devices that shall communicate with each other Especially ensure unique IP addresses and proper subnet settings Unknown Niagara Platform Access Credentials If the access credentials are lost they can be reset to their default value user sysmik password intesa with the Service b
47. ts are not supported 3 The data retention time of the Flash memory depends on the temperature Longer storage periods weeks at higher temperatures should be avoided Table 6 1 Technical data 44 sysmik de Manual SCA 340 SCA 340 L Order Information 7 Order Information 7 1 Scalibur and Accessories SCA 340 no Niagara license 1226 100550 04 0 SCA 340 005 Niagara license for 5 devices 250 data points 1226 100550 10 1 SCA 340 010 Niagara license for 10 devices 500 data points 1226 100550 11 8 SCA 340 025 Niagara license for 25 devices 1250 data points 1226 100550 12 5 SCA 340 100 Niagara license for 100 devices 5000 data points 1226 100550 13 2 SCA 340 200 Niagara license for 200 devices 10000 data points 1226 100550 14 9 SCA 340 L ee 1226 100550 06 4 no Niagara license SCA 340 L 005 SCA 340 L 010 LON TP FT 10 Niagara license for 5 devices 250 data points LON TP FT 10 Niagara license for 10 devices 500 data points 1226 100550 15 6 1226 100550 16 3 SCA 340 L 025 SCA 340 L 100 LON TP FT 10 Niagara license for 25 devices 1250 data points LON TP FT 10 Niagara license for 100 devices 5000 data points 1226 100550 17 0 1226 100550 18 7 SCA 340 L 200 LON TP FT 10 Niagara license for 200 devices 10000 data points 1226 100550 19 4 Table 7 1 1 Order information for Scalibur SCA 340 SCA 340 L sysmik de 45 Order In
48. upply unit an increased load there increases Scalibur s internal power dissipation Therefore a derating has to be observed which is depending on the mounting position see Fig 3 2 2 4 1 The recommended mounting position with least derating is horizontally that is clipped to a horizontal DIN rail on the wall 18 sysmik de Manual SCA 340 SCA 340 L Installation and Commissioning The internal power dissipation caused by USB loads Puss and the connected Inline terminals Pperi is calculated according to chapter 3 2 2 3 Pv 100 80 60 horizontal mounting other mounting positions 40 20 0 25 15 5 5 15 25 35 45 55 Pv Power dissipation of internal Scalibur supply in Tenv C Tenv C environmental temperature in C Fig 3 2 3 2 1 Derating diagram of maximum internal power dissipation Please refer to the manuals of the Inline terminals to find out the load of the logic supply Maximum load on the logic supply 2 A and on USB 2 x 500 mA leads to a 100 power dissipation of 2 7 W Py 1 0 V x1 0 7 V x lysg Py 10Vx20A 0 7Vx1 0A 2 7W This power dissipation can be maintained up to a maximum environmental temperature of 40 C 104 F For higher temperatures the load Peer and Puses must be reduced according to Fig 3 2 2 4 1 Example 1 Horizontal mounting position For an environmental temperature of 55 C 131 F and horizontal mounting the power dissipation is l
49. uring a software update the process status LEDs signalize the programming process as a running light IO Status LED IO The communication state of the lO terminals is signalized by a dual colored lO LED located at the supply connector State Description off The IO server is not running green Communication with Inline terminals is OK Communication with the Inline Terminals is not working Possibly there are no terminals attached or the terminals are not snapped in properly Table 3 3 4 1 lO status LED Communication LEDs COM1 COM2 LON Located at the interface connector the Scalibur has LEDs which signalize the data transmission of their respective interface The layout of the LEDs resembles the layout of the terminals COM1 upper left COM2 upper right and LON below only SCA 340 L yellow com __ Iai com BT Rx I LON Fig 3 3 5 1 COM LEDs SCA 340 SCA 340 L sysmik de 25 Installation and Commissioning COM1 Rx Description Data are being received via COM1 COM1 Tx Data are being sent via COM1 COM2 Rx green Data are being received via COM2 COM2 Tx yellow Data are being sent via COM2 LON Rx green Data are being received via LON only SCA 340 L LON Tx yellow Data are being sent via LON only SCA 340 L Table 3 3 5 1 Inline supply LEDs
50. utton see 3 3 6 The Scalibur has to be restarted and the Service button must be pressed at the right moment Sedona Virtual Machine is not Starting If the Scalibur Sedona files app sab and kits scode are corrupted or inconsistent the SVM can not start In this case a device connection from Workplace AX to the Sedona controller is not possible Consequently Sedona tools cannot be used to fix this situation 40 sysmik de Manual SCA 340 SCA 340 L Best Practices and Troubleshooting Instead the Service button offers a way to overwrite these files with default files see 3 3 6 The Scalibur has to be restarted and the Service button must be pressed at the right moment 5 3 6 IO Errors Important indicators for the state of the lO terminals are Scalibur s IO LED and the diagnosis LEDs of the Inline terminals labelled D State Description off no logic voltage on logic voltage ok local bus active blinking 0 5 Hz logic voltage ok local bus not running blinking 2 Hz logic voltage ok peripheral error see manual of specific terminal ae logic voltage ok error at interface between blinking and previous terminal blinking 4 Hz i f e g loose contact defective terminal hot plugging of terminal Table 5 3 6 1 Behavior of diagnosis LED D SCA 340 SCA 340 L sysmik de 41 Technical Data
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