Canon PC800S Camcorder User Manual
Contents
1. IN IN LN IN Fan Mode Sequence MV 58 Present Value R W V V SIN DS LS SISS Heating Setpoint Limit AV 58 Present Value RW Cooling Setpoint Limit AV 59 Present Value RW Setpoint Type BV 60 Present Value RW SINN Setpoint Function BV 61 Present Value R W RV IN A A A LN Occupancy gg Present Value RW Deadband AV 63 Present Value R W vVivivivivilvJl viv ON IN vod Reheat Time Base BV 64 Present Value RW IVLIVS SISS iv IN BACNET INTEGRATION MANUAL FOR 7200 amp TB7300 SERIES THERMOSTATS Table 5 Objects Continued mm s Deer sr c eere 5 Object Object Property A Instance o0 ood N IN N N N N N N IN N INI N mm elele E Proportional Band MV 65 Present Value RW N N ISSN IN NN Auto Fan BV 66 Present Value R W A IN IN A A iv dv Stand by Time AV 67 Present Value RW N ISSN INNI NN IN IN Unoccupied Time AV 68 Present Value RW N N NN IN NN IN EON GRP 69 Present Value Configuration Options RH Display BV 70 Present Value R W Viv2. INTEGRATION MANUAL FOR 7200 6 7300 SERIES THERMOSTATS Cable Type Honeywell recommends the use of balanced 22 24 AWG twisted pair with a characteristic impedance of 100 130 ohms capacitance of 30 pF ft or lower A braided shield is also recommended Impedance A value based on the inherent conductance resistance capacitance and inductance that represent the impedance of an infinitely long cable The nominal impedance of the cable should be between 100Qand 1200 However using1200 will result in a lighter load on the network Capacitance pF ft The amount of equivalent capacitive load of the cable typically listed in a per foot basis One of the factors limiting total cable length is the capacitive load Systems with long lengths benefit from using low capacitance cable i e 17pF ft or lower 63 4524 01 4 BACNET INTEGRATION MANUAL FOR 7200 amp TB7300 SERIES THERMOSTATS NETWORK CONFIGURATION EIA 485 networks use a daisy chain configuration A daisy chain means that there is only one main cable and every network device is connected directly along its path Figure 1 illustrates two improper network configurations and the proper daisy chain configuration Other methods of wiring an EIA 485 network may give unreliable and unpredictable results There are no troubleshooting methods for these types of networks Therefore a great deal of site experimentation may have to be done making this a difficult task wit
3. Filter Alarm BI 36 Present Value R NN NN NN NN NN iy Service Alarm BI 37 Present Value R NV N NI N IN NN IN NI N N IN Temperature Setpoints GRP 38 Present Value R Fes MESE ed Occupied Heat Setpoint 39 Present Value N NN NN N NN NEN N N Occupied Cool Setpoint AV 40 Present Value RW N NN NN N Iy NEIN jv iv Stand by Heat Setpoint AV 41 Present Value RW N JN JN N 1 N N Stand by Cool Setpoint AV 42 Present Value RW N N N N N N 1 N NN IN NN as Heat AV 43 Present Value RW iv Aee AV44 Present Value RW General Options 1 GRP 45 Present_Value R AAAA AAAS BI 1 Configuration MV 46 Present Value BI 2 Configuration MV 47 Present Vlue RW N 1 N 4 UI 3 configuration MV 48 Present IV VIN IV NN SINN Menu Scroll BV 49 Present Value RW VV v vN N NN Auto Mode Enable BV 50 Present Value R W Temperature Scale BV 51 Present Value RW VI VIVII yI yI vyv Pipe Number MV 52 Present_Value R W VIINIIN Out 1 Config MV 53 Present_Value R W AUX Configuration MV 54 Present Value 4 ns ie ea E General Options 2 GRP 55 Present Value R EAC cet Password Value AV 56 Present Value RW
4. PI Heating Demand AV21 PI Cooling Demand AV22 Window Alarm BI 35 Filter Alarm BI 36 Service Alarm BI 37 Occupancy System mode Fan Mode Outdoor Temperature 42 Supply Temperature Fan Status Heating Valve Cooling Valve Status Status Filter Alarm Roorn Temperature Occupied Heating Setpoint ERU Occupied Cooling Setpoint Unoccupied Heating Setpoint 62 0 F Unoccupied Cooling Setpoint 82 0 F Room Hurridity 49 7 Room Hurridity Setpoint 50 0 96 Fig 8 Example of graphical user interface objects 11 63 4524 01 BACNET INTEGRATION MANUAL FOR 7200 amp TB7300 SERIES THERMOSTATS Configuration Objects The following objects and group objects should be typically used for configuration purposes General Options 1 Group GRP 45 and its complete list of objects General Options 2 Group GRP 55 and its complete list of objects Humidity Models Configuration Options Group GRP 69 and its complete list of objects Output Configuration Options Group GRP 74 and its complete list of objects If your BAS allows you to remove objects Honeywell recommends removing all configuration objects once your setup is complete This will prevent unnecessary network polling and traffic Default Device Name and default Device ID Default Device Name is set to Model number MAC Where MAC is the current MAC address of the device Where Model number is Honeywell part number The device name will be u
5. wv ps psg PI Heating Demand AV 21 Present Value R NN IN NIN NIN N NN IN IN PI Cooling Demand AV 22 Present Value R NIN IN NIN NiN N A IN IN Dehumidification Status 23 Present Value R Viv Viv Controller Status GRP 24 Present_Value R ae AUX Status 25 Present_Value R ViviJvjivivjiv pv iv NN IN IN Heating Valve Status MV 26 Present_Value R NO NN IN IN Cooling Valve Status MV 27 Present Value R Vivi vjv iv IN iv dv Fan Status MV 28 Present_Value R NUN NON IN NN a IN iv dv BI 1 Status BI 29 Present Value R NI N IN NIN NIN N NIN IN IN BI 2 Status BI 30 Present Value R NI IN IN ON IN NIN N NN IN IN UI 3 Status BI 31 Present Value R NIN IN NN IN NIiN N NN IN IN Local Motion BI 32 Present Value R VivivivJvivilvjiv NIN IN IN Effective Occupancy MV 33 Present Value R NN IN A NIN N NN IN IN Controller Alarms GRP 34 Present Value R SESS Es s E SERE E REUS eR ERE si Window Alarm BI 35 Present Value R NI NN IN IN IN iv iv IN 63 4524 01 BACNET INTEGRATION MANUAL FOR 7200 amp TB7300 SERIES THERMOSTATS Table 5 Objects Continued 63 4524 01 18 29323922989 Em cm E Object Name Object Property SS ean erre Instance 5 d e e 3 e e esa ES
6. BACNET INTEGRATION MANUAL FOR 7200 amp TB7300 SERIES THERMOSTATS Table 10 Property enumeration sets for MV objects Continued Object Name Object ID BACnet Index Text Default value 1 0 5 minute 2 1 minute 3 1 5 minutes 4 2 minutes 5 2 5 minutes 6 3 minutes 7 3 5 minutes 8 4 minutes Floating Motor Timing MV 76 Sams 1 5 minutes 10 5 minutes 11 5 5 minutes 12 6 minutes 13 6 5 minutes 14 7 minutes 15 7 5 minutes 16 8 minutes 17 8 5 minutes 18 9 minutes 1 3 CPH 2 4 CPH On Off Control CPH MV 77 mee 4 4 6 5 7 6 8 CPH 27 63 4524 01 BACNET INTEGRATION MANUAL FOR TB7200 amp TB7300 SERIES THERMOSTATS Automation and Control Solutions Honeywell International Inc 1985 Douglas Drive North Golden Valley MN 55422 Honeywell Limited Honeywell Limit e 35 Dynamic Drive Toronto Ontario M1V 429 customer honeywell com U S Registered Trademark 2011 Honeywell International Inc 63 4524 01 M S 05 11 Printed in U S A Honeywell
7. The Ref terminal should NEVER be used to wire shields The 2 shields from each feed of the network connection to a thermostat should be wired together in the back of the thermostat and properly protected to prevent any accidental connection to the ground The joined shield connection should then be grounded at a SINGLE point on the whole segment More than one ground connection to a shielded wire may induce ground loop noises and affect communication Network Adapter Status LED Table 3 shows the different possibilities with the Status LED behavior for a BACnet module Table 3 Status LED condition and possible solutions Condition of the Status LED Possible Cause Solution 1 short blink BACnet communication NOT active at default MAC address 254 Change MAC address to another value from 0 to 127 2 short blink no wires connected to the module The right module has been installed on the right thermostat model N A 2 short blink wires connected to the module Module is not at the same baud rate as the network Power off and on the thermostat e 2 short blinks and a longer blink wires connected to the module The module has detected the presence of a network N A Right after power is applied 2 long blinks and then no blinking Polarity has been reversed at the module Reverse polarity at the module 63 4524 01 BACNET INTEGRATION MANUAL FOR 7200 amp TB7300
8. write request will occur at the Supervisory Controller s program scan rate which might as well be in hundredths of milliseconds This can easily bog down a network as single commands can be sent to all ASC devices down the MS TP trunks every hundredth of milliseconds Programs writing to the devices should have a structure similar to the following If Once Schedule On then Do Every 5min MV13 Occupied If Schedule On Then End If MV13 Occupied If Once Schedule Off Then OR Else MV13 Unoccupied MV13 Unoccupied End If End If End Do Retries and Timeouts Another thing to look for in a BACnet integration is the Device object of the Supervisory Controller and the Operator s Workstation This object contains the 2 following required properties Retry Timeout and Number of APDU Retries 1 Retry Timeout property specifies the time between re transmissions if the acknowledgement has not been received When you are experiencing problems with controllers dropping off line increasing this value may help 2 The Number of APDU Retries property specifies the number of times unsuccessful transmissions will be repeated If the receiving controller has not received the transmission successfully after this many attempts no further attempts will be made For example if one of the thermostats does not reply to a Supervisory Controller SC request and the SC s Retry Timeout is set to 2000 msec and the Number of APDU Retries is set to 1
9. 00 ft 1200 m This will only work reliably for data rates up to 100 000 bps The maximum data rate is 76 800 bps for TB7200 and TB7300 Series thermostats If you require a maximum network length of more than 4000 feet then repeaters are required to extend the network EIA 485 Repeaters If you have more than 64 devices or require a maximum network length of more than 4000 feet then repeaters are required to extend the network The BASRT B repeater by Contemporary Controls can be used if a repeater is needed The best configuration is to daisy chain the repeaters to the controller From each of these repeaters a separate daisy chain will branch off Figure 3 demonstrates a valid use of repeaters in an EIA 485 network LEGEND EOL END OF LINE RESISTOR R RS485 REPEATER SC SUPERVISORY CONTROLLER M32573 Fig 3 Correct usage repeaters are daisy chained to the supervisory controller and separate daisy chains branch from each repeater Do not install repeaters in series as this may result in network reliability problems Figure 4 demonstrates an incorrect use of a repeater in an EIA 485 network DO NOT ADD SECOND REPEATER R IN SERIES LEGEND EOL END OF LINE RESISTOR R RS485 REPEATER SC SUPERVISORY CONTROLLER M32574 Fig 4 Incorrect usage the second repeater in series may result in an unreliable system 63 4524 01 6 BACNET INTEGRATION MANUAL FOR 7200 amp TB7300 SERIES THER
10. 9 9 F 40 C 121 9 F 50 C N A Outdoor Temperature AV 9 39 F 40 C 121 9 F 50 C N A Room Humidity AV 10 5 90 N A Supply Temperature Al 12 39 9 F 40 C 121 9 F 50 C N A Heating demand AV 21 0 100 0 PI Cooling demand AV 22 0 100 0 Occupied Heat Setpoint AV 39 40 F 4 5 C 90 F 32 C 72 F 22 C Occupied Cool Setpoint AV 40 54 F 12 C 100 F 37 5 C 74 F 24 C Stand by Heat Setpoint AV 41 40 F 4 5 C 90 F 32 C 72 F 22 C Stand by Cool Setpoint AV 42 54 F 12 C 100 F 37 5 C 74 F 24 C Unoccupied Heat Setpoint AV 43 40 F 4 5 C 90 F 32 C 62 F 16 5 C Unoccupied Cool Setpoint AV 44 54 F 12 C 100 F 37 5 C 80 F 26 5 C Password Value AV 56 0 1000 0 Heating Setpoint Limit AV 58 40 F 4 5 C 90 F 32 C 90 F 32 C Cooling Setpoint Limit AV 59 54 F 12 C 100 F 37 5 C 54 F 12 C Deadband AV 63 2 F 1 C 5 F 2 5 C 2 F 1 C Stand by Time AV 67 0 5 Hours 24 0 Hours 0 5 Hours Unoccupied Time AV 68 0 0 Hours 24 0 Hours 0 0 Hours RH Setpoint AV 45 30 100 50 Dehumidification Hysterisys AV 46 2 20 5 Dehumidification MAX cooling AV 47 20 100 100 63 4524 01 BACNET INTEGRATION MANUAL FOR 7200 amp 7300 SERIES THERMOSTATS Property Enumeration Sets for BV amp BI Objects Table 9 Property enumeration sets for BV and BI objects Object Name EM Inacti
11. Bps 3 38 4 KBps 4 76 8 KBps and 5 Auto Baud Rate Index 5 is Write only Reading attribute will state current Baud rate used Writing index 1 to 4 will fix the Baud rate to the desired value 63 4524 01 Objects Table BACNET INTEGRATION MANUAL FOR 7200 amp TB7300 SERIES THERMOSTATS Table 5 Objects Object and Object Property 5 5 S 2 9 2 AN S F SS eee el ele Ss Room Temperature AV 7 Present Value RW NV NN IN IN Room Temp Override BV 8 Present Value RW N N NN IN NN NN IN IN Outdoor Temperature AV 9 Present Value RW N N NN IN yI NN N IN Room Humidity AV 10 Present Value R W NN Viv Room Humid Override BV 11 Present_Value R W Viv Viv Supply Temperature Al 12 Present_Value R VivivivJvivilvjv NN IN IN ist M BV 13 Present Value VN VN AUX Command BV 14 Present Value RW NN IN IN Sequence of Operation MV 15 Present Value RW N v xv xv wv NN NN System Mode MV 16 Present Value RW N N NN IN NN NN IN IN Fan Mode MV 17 Present Value R W NUN NON IN EN dv Occupancy Command MV 18 Present Value RW N N NN IN yI NN N IN Keypad Lockout MV 19 Present Value RW VN N NN N NN NN IN IN Control Output GRP 20 Present Value R Wi
12. Honeywell BACnet Integration Manual for 7200 8 TB7300 Series Thermostats RoomTemp 72 5 F TB7300 Series Thermostat with Occupancy Sensor TB7200 Series Thermostat PRODUCT OVERVIEW The TB7200 Series PI thermostats are designed for zoning applications and the TB7300 Series thermostats are designed for fan coil control Both Series are communicating thermostats with models available in BACnet MS TP and ZigBee wireless mesh protocols and can be easily integrated into a WEBs AX building automation system based on the NiagaraAx platform TB7200 and TB7300 Series thermostats are compatible with the Honeywell Occupancy Sensor Cover Thermostats equipped with an occupancy sensor cover provide advanced active occupancy logic which will automatically switch occupancy levels from Occupied to Stand By and Unoccupied as required by local activity being present or not This advanced occupancy functionality provides advantageous energy savings during occupied hours without sacrificing occupant comfort All thermostats can be ordered with or without a factory installed PIR cover INTEGRATION MANUAL More information The additional following documentation is available on http customer honeywell com TB7200 Series Installation Instructions form number 62 2019 TB7300 Series Installation Instructions form number 62 2018 PIR Application Guide for TB7200 and TB7300 Series Thermostats form numbe
13. ING GUIDELINES Overview Honeywell uses EIA 485 as the physical layer between their devices and supervisory controllers For clarity we will use the term Device to represent any product with an active EIA 485 network connection including Honeywell and non Honeywell thermostats Table 2 Summary of Specifications for a Honeywell EIA 485 Network Parameter Details Media Twisted pair 22AWG 24 AWG shielded recommended Characteristic Impedance 100 130 ohms Distributed capacitance Less than 100 pF per meter 30 pF per foot Maximum length per segment 1200 meters 4000 feet Polarity Polarity sensitive Multi drop Daisy chain no T connections Terminations 1 TB7200 TB7300 and or TB7600 Series thermostat devices are installed at both ends of the MS TP network 120 Ohms resistor should be installed at each end 2 ATB7200 TB7300 or TB7600 Series thermostat is installed at one end of the MS TP network and another device is installed at the other end Install an End Of Line resistor value that matches the other device s instructions regarding the End Of Line resistors 3 Other devices are installed at both ends of the MS TP network Follow the other device s instructions regarding the End Of Line resistors Maximum number of nodes per segment 64 Honeywell devices only Maximum number of nodes per network 128 Baud rate 9600 19200 38400 76800 Auto detect 3 63 4524 01
14. MOSTATS End Of Line EOL Resistors MS TP network must be properly terminated For daisy chain configurations you must install an EOL resistor at each end of the daisy chain Depending on your MS TP network configuration the resistance value of the EOL resistor may change TB7200 TB7300 or TB7600 Series devices are installed at both ends of the MS TP network 120 Ohms resistor should be installed at each end ATB7200 TB7300 or TB7600 device is installed at one end of the MS TP network and another device is installed at the other end Install an End Of Line resistor value that matches the other device s instructions regarding its EOL resistor value Other devices are installed at both ends of the MS TP network Follow the other device s instructions regarding its EOL resistor value 7 63 4524 01 BACNET INTEGRATION MANUAL FOR 7200 amp TB7300 SERIES THERMOSTATS NETWORK ADAPTER The polarity of the connection to the cable is important From one module to the other it is important that the same colored wire be connected to plus or and the other colored wire be connected to the minus or Figure 5 shows the proper MS TP connections and the location of the Status LED This Status LED may help to troubleshoot network problems au EEG Status 27 Board revision under the board number Fig 5 Correct MS TP connections and location of a Status LED on a BACnet module IMPORTANT NOTE
15. NC Window None Door Dry Override Filter Service Default value None None UI3 Configuration MV 48 None COC NH COC NC COS 55 Pipe Number MV 52 2 Pipe 4 Pipe 4 Pipes Out 1 Cfg MV 53 2 4 AUX Configuration MV 54 Not used NO with Occ NC with Occ NO with Occ amp Fan NC with Occ amp Fan Network controlled Not Used 25 63 4524 01 BACNET INTEGRATION MANUAL FOR 7200 amp TB7300 SERIES THERMOSTATS Table 10 Property enumeration sets for MV objects Continued Object Name Object ID BACnet Index Text Default value 1 Low Med High 2 Low High Fan Mode Sequence MV 58 3 Low Med High Auto On Auto 4 Low High Auto 5 On Auto 1 0 hour 2 1 hour 3 2 hours 4 3 hours 5 4 hours 6 5 hours 7 6 hours 8 7 hours 9 8 hours 10 9 hours 11 10 hours 12 11 hours POTO Occupancy My 62 13 12 hours 2 hours 14 13 hours 15 14 hours 16 15 hours 17 16 hours 18 17 hours 19 18 hours 20 19 hours 21 20 hours 22 21 hours 23 22 hours 24 23 hours 25 24 hours 1 3 3F 12 2 4 AF 17 C 3 5 5F 22C Proportional Band MV 65 we 80 3 5 7 3 3C 6 8 8F 3 9C 7 9 9F 5 0C 8 10 10F 5 6C 63 4524 01 26
16. NTEGRATION MANUAL FOR 7200 amp 7300 SERIES THERMOSTATS BACNET OBJECTS SUPPORTED Device Objects Table 4 Device Objects Type and Object Name Object Property Thermostat Parameter TB7200X5x14B Device Object Identifier Unique ID number of a device on a network TB73xxX5X14B Property 75 R W Object Name Property 77 Unique name of a Device on network Model Name Property 70 R Thermostat Model number Firmware Revision Property 44 R Current BACnet firmware revision used by the thermostat Protocol Version Property 98 R Current BACnet firmware protocol version Default is Version 1 Protocol Revision Property 139 R Current BACnet firmware protocol revision Default is Version 2 Max ADPU Length Property 62 R Maximum ADPU Length accepted Default is 244 ADPU Timeout Property 10 R ADPU timeout value Default is 60 000 ms Application Software Version Property 12 R Thermostat base application software version Default is based on current released version Max Master R W Maximum master devices allowed to be part of the network 0 to 127 default is 127 MS TP_Address Property 1001 R W BACnet MS TP MAC Address Proprietary attribute Default is as assigned by configuration MS TP_Baud_Rate Property 1002 R W BACnet MS TP Baud Rate Proprietary attribute Range is 1 9 6 KBps 2 19 2 K
17. SERIES THERMOSTATS INTEGRATION Global Commands The following figure shows which objects from the thermostat can be monitored and commanded from the BAS front end GLOBAL COMMANDS ALL DEVICES ALL THERMOSTATS OUTDOOR TEMPERATURE OUTDOOR TEMPERATURE AV9 OUTDOOR TEMPERATURE AND OUTDOOR HUMIDITY ENTHALPY DEHUMIDIFICATION LOCKOUT BV13 OUTDOOR TEMPERATURE AND HVAC PLANT CURRENT MODE a lt SEQUENCE OF OPERATION MV15 SYSTEM MODE AV16 GLOBAL COMMANDS SPECIFIC DEVICES SPECIFIC AREA THERMOSTATS SCHEDULE OCCUPANCY MV18 SCHEDULE AND OUTDOOR TEMPERATURE FAN MODE MV17 OCCUPIED HEATING SETPOINT AV39 UNOCCUPIED HEATING SETPOINT AV43 OCCUPIED COOLING SETPOINT AV40 UNOCCUPIED COOLING SETPOINT AV44 RESTRICT USER ACCESS TO THERMOSTAT gt KEYPAD LOCKOUT 19 ROOM TEMPERATURE FOR TESTING AND OVERRIDE ROOM TEMPERATURE AV7 REMOTE CONTROL OF THE AUXILIARY OUTPUT AUX OUTPUT BV 14 MSTP NETWORK BAS FRONT END TB7300 SERIES TSTAT GLOBAL COMMAND CONTROL LEVEL DEVICE LEVEL MCR32655 Fig 6 Global commands from a BAS front end to a typical TB7300 Series thermostat 9 63 4524 01 BACNET INTEGRATION MANUAL FOR TB7200 amp TB7300 SERIES THERMOSTATS TB7200 Integration Graphical User Interface GUI objects The following objects should be typically used in a GUI Room Temperature AV7 Occupied and U
18. V75 Value MV52 Index MV26 Object Function MV26 State Text Index Default Value Name On Off 1 2 pipe Unused Output N A N A 2 4 pipe Heating Valve 1 Closed 2 Open Closed Status Floating 1 2 pipe Unused Output N A N A 2 4 pipe Heating Valve 1 Stopped 2 Opening 3 Closing Stopped Status 8 Enumeration sets for MV27 depends on Control Type BV75 value and Pipe Number MV52 value upon device dis covery If required enumeration is not present set BV75 and MV52 to desired value and rediscover MV27 object Available enumeration will now reflect required configuration 9 Available object name state text and default value depends on Control Type BV75 value and Pipe Number MV52 upon device discovery 63 4524 01 24 BACNET INTEGRATION MANUAL FOR 7200 amp TB7300 SERIES THERMOSTATS BV75 Value MV52 Index MV27 Object Function MV26 State Text Index Default Value Name On Off 1 2 pipe Heat Cool Valve 1 Closed 2 Open Closed Status 2 4 pipe Cooling Valve 1 Closed 2 Open Closed Status Floating 1 2 pipe Heat Cool Valve 1 Stopped 2 Opening 3 Closing Stopped Status 2 4 pipe Cooling Valve 1 Stopped 2 Opening 3 Closing Stopped Status Table 10 Property enumeration sets for MV objects Continued Object Name Configuration BI2 Configuration Object ID MV 46 MV 47 BACnet Index Text None Rem NSB Motion NO Motion
19. Viv RH Setpoint AV 71 Present_Value R W Viv Viv AV 72 Present Value V v Hysterisys AM Present Value R W Cooling output Configuraton rp74 Present Vaue R 4 4 siy Options Control type BV 75 Present Value RW Vi Viv Floating Motor timing MV 76 Present Value RW NN IN iv On Off Control CPH MV 77 Present Value RW IN NIN IN Direct Reverse Acting BV 78 Present Value R W Y VivJv jv 63 4524 01 BACNET INTEGRATION MANUAL FOR 7200 amp TB7300 SERIES THERMOSTATS Standard Object Types Supported Table 6 Standard object types supported Optional Supported Dynamically Dynamically Object Type Objects Deletable Properties Writable Properties Supported Analog Input Oo Reliability Out of Service Present Value Analog Value o Reliability Out of Service Object Name Reliability Binary Input o Lr Active Text Out of Service Inactive Text Reliability Present Value Binary Value m LI Active Text Out of Service Inactive Text Object Identifier Device L1 Mex Object name Max Info frames Group EE d Multi state Value E Reliability Present Value States Text Out of Service a PI Heating Demand AV21 PI Cooling Demand AV22 Room Temperature AV7 Heati
20. h no guarantee of success Honeywell will only support daisy chain configurations STAR CONFIGURATION BUS CONFIGURATION DAISY CHAIN CONFIGURATION M32571 Fig 1 Three different network configurations star bus and daisy chain Only the daisy chain configuration is correct for EIA 485 network Maximum Number of Devices A maximum of 64 nodes is allowed on a single daisy chain segment A node is defined as any device controller thermostat repeater etc connected to the RS485 network Terminators do not count as a node NOTE Biasing is not required with this series of devices To determine the number of nodes on a network add the following One node for each device including the controller One node for each repeater on the chain For the example in Figure 2 we have one node for the controller plus 4 for the thermostats for a total of 5 nodes END OF LINE RESISTOR DOES NOT COUNT ASANODE NODE2 NODE3 NODE4 NODES NODE 1 LEGEND EOL END OF LINE RESISTOR SC SUPERVISORY CONTROLLER M32572 Fig 2 Five nodes network example If you have more than 64 devices then repeaters are required to extend the network 5 63 4524 01 BACNET INTEGRATION MANUAL FOR 7200 amp TB7300 SERIES THERMOSTATS Maximum Cable Length The maximum length of a chain is related to its transmission speed The longer the chain the slower the speed Using proper cable the maximum length of an EIA 485 daisy chain is 40
21. ion is not present set MV58 to desired value and rediscover MV17 object Available enumeration will now reflect required configuration 4 Available state text and default value depends on Fan Mode Sequence MV58 value upon device discovery 5 Same as Note 4 23 63 4524 01 BACNET INTEGRATION MANUAL FOR 7200 6 TB7300 SERIES THERMOSTATS MV17 Index Function MV58 State Text Index Default Value 1 1 Low 2 Med 3 High High 2 1 Low 2 High High 3 1 Low 2 Med 3 High 4 Auto High 4 1 Low 2 High 3 Auto High 5 1 Auto 2 On Auto Table 10 Property enumeration sets for MV objects Continued Object Name Object ID BACnet Index Text Default value Heding Sias og Note 7 Note 7 Note 7 Note 6 Note 9 Note 9 Note 9 Note 8 1 Off 2 Low Fan Status MV 28 Off 3 Med 4 High 1 Occupied 2 Unoccupied Effective Occupancy MV 33 Depends onilocal 3 Temporary Occupied occupancy 4 Stand by 6 Enumeration sets for MV26 depends on Control Type BV75 value and Pipe Number MV52 value upon device dis covery If required enumeration is not present set BV75 and MV52 to desired value and rediscover MV26 object Available enumeration will now reflect required configuration 7 Available object name state text and default value depends on Control Type BV75 value and Pipe Number MV52 upon device discovery B
22. ng Valve Status MV26 Cooling Valve Status MV27 FanStatus MV28 Effective Occupancy MV33 List of Proprietary Properties Present Value and Out of Service properties are writable for every AV objects except Present Value and Out of Service properties are writable for every MV objects except Table 7 Proprietary Properties Present Value property for Room Temperature AV7 and Room Humidity AV10 is writable only if Room Temp Override BV8 is enabled and Room Humidity Override BV11 is enabled respectively Object Name property is writable for the following object only Property name ID BACnet Data type Description The version number of the BACnet communications Major Version 1000 CharacterString module This is the hardware version number MS TP Address 1001 Unsigned Display the MAC layer address of the module MS TP Baud Rate 1002 Unsigned Display the communication baud rate of the module Display the temperature or humidity calibration value Sensor Offset 1005 REAL The range is 5 0 deg F to 5 0 deg F for a temperature and 15 to 15 for humidity 63 4524 01 20 Property Value Range Restrictions BACNET INTEGRATION MANUAL FOR 7200 amp TB7300 SERIES THERMOSTATS Table 8 Property value range restrictions 21 Object name bir M as gosse 2 Default value Room Temperature AV 7 3
23. noccupied Heat Setpoints AV 39 and AV43 Occupied Unoccupied Cool Setpoints AV 40 and 34 Outdoor Temperature AV 9 Supply Temperature 12 If available Occupancy Command MV 18 System Mode MV16 Heating Valve Status 26 Cooling Valve Status MV28 PI Heating Demand AV21 PI Cooling Demand AV22 Window Alarm BI 35 Filter Alarm BI 36 Service Alarm BI 37 Occupancy Supply System mode Temperature Outdoor Temperature PI Cooling Demand 78 Heating Demand Room Temperature Occupied Heating Setpoint Occupied Cooling Setpoint m 211 Unoccupied Heating Setpoint Aux Output Unoccupied Cooling Setpoint Fig 7 Example of graphical user interface objects 63 4524 01 10 ho 4 f ar ico iol olla Fn e N m BACNET INTEGRATION MANUAL FOR TB7200 amp TB7300 SERIES THERMOSTATS TB7300 Integration Graphical User Interface GUI Objects The following objects should be typically used in a GUI Room Temperature AV7 Occupied and Unoccupied Heat Setpoints AV 39 and AV43 Occupied and Unoccupied Cool Setpoints AV 40 and AV34 Room Humidity AV10 If available Room Humidity Setpoint AV 71 If available Outdoor Temperature AV 9 Supply Temperature 112 If available Occupancy Command MV18 System Mode MV16 Fan Mode MV17 Fan Status MV28 Heating Valve Status MV26 Cooling Valve Status MV28
24. now reflect required configuration Enumeration sets for MV26 and MV27 depend on Control Type BV75 value and Pipe Number MV52 value upon device discovery If required enumeration is not present set BV75 and MV52 to desired value and rediscover MV26 and BV27 object Available enumeration will now reflect required configuration If the device should go off line the following binded thermostat parameters will be released Room Temperature Outdoor Temperature Occupancy The BACnet Data Link layer has two key parameters the device object name and the device object ID The device object name must be unique from any other BACnet device object name on the BACnet network i e not just the MS TP sub network The device object ID must be unique from any other BACnet device object ID on the entire BACnet network i e not just the MS TP sub network 63 4524 01 2 BACNET INTEGRATION MANUAL FOR 7200 amp TB7300 SERIES THERMOSTATS To assign a Room Temperature AV7 value manually users must first enable the Override mode in the Room Temp Override BV8 object To assign a Room Humidity AV10 value manually users must first enable the Override mode in the Room Humidity Override BV 11 object Device Name and Device ID properties are writable in Honeywell device object Both properties can be renamed from any BACnet network management tool as long as the tool itself give access to write to these properties WIR
25. ol Implementation Conformance Statement PICS Vendor Name Honeywell Product Name 7200 and TB7300 Series Thermostats TB7200 Product Description The TB7200 series BACnet communicating thermostat has been specifically designed for zoning applications to be monitored on a BACnet MS TP network TB7200 Product Model Number TB7200C5x14B and TB7200F5x14B TB7300 Product Description The TB7300 series BACnet communicating thermostat has been specifically designed for zoning and fan coil applications to be monitored on a BACnet MS TP network TB7300 Product Model Number TB7300A5x14B TB7305A5x14B TB7300C5x14B TB7305C5x14B TB7350C5x14B TB7355C5x14B TB7300F5x14B TB7305F5x14B TB7350F5x14B and TB7355F5x14B Supported BACnet Services The BACnet communicating thermostat meets all requirements for designation as an Application Specific Controller B ASC The BACnet thermostat series supports the following BACnet Interoperability Building Blocks BIBBs Application Service Designation Data Sharing Read Property B DS RP B Data Sharing Read Property Multiple B DS RPM B Data Sharing Write Property B DS WP B Device Management Device Communication Control B DM DCC B Device Management Dynamic Device Binding B DM DDB B Device Management Dynamic Object Binding B DM DOB B NOTE The thermostat does not support segmented requests or responses 15 63 4524 01 BACNET I
26. pgraded as soon as there is a change to the device MAC address The Device Name and Device ID properties are writable in Honeywell device object Both properties can be renamed from any BACnet network management tool as long as the tool itself can write to these properties TB7200 Models Default Device ID is set to 72000 MAC Where is the current MAC address of the device The device ID will also be upgraded as soon as there is a change to the device s MAC For example when a TB7200F5014B thermostat with a MAC address of 41 is connected to a network its default Device Name will be TB7200F5x14B 41 and its default Device ID will be 72041 TB7300 Models Default Device ID is set to 73000 MAC Where MAC is the current MAC address of the device The device ID will also be upgraded as soon as there is a change to the device s MAC For example when a TB7300C5014B thermostat with a MAC address of 63 is connected to a network its default Device Name will be TB7300C5x14B 63 and its default Device ID will be 73063 Integrating Honeywell Devices on an MS TP Network Before doing any BACnet integration make sure to have Honeywell PICS Protocol Implementation Conformance Statement This PICS document lists all the BACnet Services and Object types supported by a device and can be found at http customer honeywell com Honeywell devices do not support the COV service COV reporting allows an object to send out notices when its P
27. r 63 4526 Contents Product OVerview oae reti ensk i a 1 Compatibility 2 2 Tips and Things You Need To Know 2 Wiring Guidelines aa ii 3 Network Configuration 5 Network Adapter 2 8 Integration 2 0 ennt ennt nnn 9 Troubleshooting 2 14 15 BACnet Objects Supported 16 63 4524 01 BACNET INTEGRATION MANUAL FOR 7200 amp TB7300 SERIES THERMOSTATS COMPATIBILITY Honeywell TB7200 and TB7300 Series thermostat compatiblity information is provided in Table 1 Table 1 TB7200 Series and TB7300 Series Thermostat Compatibility Information WEBs AX Controller Thermostats Per Controller WEBStation AX WEB 2xx 126 3 0 or later WEB 6xx 126 3 0 or later WEB 7xx 126 3 5 128 total devices supported One node used by controller and one for a repeater A repeater is required if more than 64 devices are on a bus TIPS AND THINGS YOU NEED TO KNOW Each thermostat is delivered from the factory with the default MAC address set at 254 At this value BACnet communication is NOT active and the device will not participate in the token pass either The local LED status for the communication adapter at this point is one short flash only To enable BACnet communication set
28. resent Value property is incremented by a pre defined value Since this is not supported at Honeywell s end special attention should be given to the polling time settings at the Supervisory Controller and Workstation level when using a graphic interface or an application program to read or write to a Honeywell object 63 4524 01 12 BACNET INTEGRATION MANUAL FOR 7200 amp TB7300 SERIES THERMOSTATS Graphical interfaces For example some graphic interface might poll every data linked to the graphic page on a COV basis If the 314 party device does not support COV the graphic interface then relies on pre configured polling interval which is usually in hundredths of milliseconds Any device containing a monitored object could be subject to network traffic congestion if such a polling interval is used Honeywell strongly recommends a polling interval of 5 seconds minimum for any graphic interface This becomes even more critical in area graphics where a single representation might poll many devices If proper poll rate is not respected devices may be reported offline by certain front end by saturating the traffic handling capacity of BACnet MS TP without COV subscription Free programmed object or loops As for the application program you might want to read and write any MS TP data on an If Once basis or a Do Every loop basis instead of reading or writing to a 3rd party device s object directly in the program Otherwise any read or
29. still at the SC level then the SC will send one other request 2 sec later If the MS TP device does not reply it will be considered Off line by the workstation So having a Retry Timeout value of 10000 msec and a Number of APDU Retries property set to 3 at the SC level may prevent device from dropping Off line These properties should also be changed at the Workstation level since the workstation will likely issue requests to any MS TP devices when the graphics are used 13 63 4524 01 BACNET INTEGRATION MANUAL FOR 7200 amp TB7300 SERIES THERMOSTATS TROUBLESHOOTING Error Trouble Condition Possible Cause Solution Thermostat does not come online Two or more controllers have the same MAC address Modify each duplicate address to a unique number The MS TP network has too many devices Do not exceed the maximum number of devices and maximum length allowed by the EIA 485 specifications Too many devices were installed without any repeaters Repeaters need to be installed as specified in this document The MS TP cable runs are broken Locate the break and correct wiring MS TP connections at the module are reversed Respect polarity of the wires on a MS TP network The thermostat does not have power Apply power to the thermostat 63 4524 01 BACNET INTEGRATION MANUAL FOR 7200 amp TB7300 SERIES THERMOSTATS APPENDIX TB7200 amp TB7300 Series Protoc
30. the local MAC address configuration property of the thermostat to any valid value from 0 to 127 Afterthe initial configuration of your device and if your BAS allows you to remove objects we suggest that you remove all the configuration objects to prevent unnecessary polling of non used objects and to help speed up the network All configuration objects are available and accessible locally from the device itself using the local configuration routine Please refer to the PIR Application Guide for TB7200 and TB7300 Series Thermostats form number 63 4526 In its default mode of operation the device will automatically match its baud rate to the baud rate of the network Automatic baud rate detection will occur when the MS TP communication port is initialized on power up If the network speed is changed the device will keep listening at the previously detected speed for 10 minutes before resuming auto bauding Re powering the devices will force immediate auto bauding Enumeration sets for System Mode MV16 depends on Sequence of Operation MV15 value upon device discovery If required enumerations are not present set MV15 to desired value and rediscover MV16 object Available enumeration will now reflect required configuration Enumeration sets for MV16 depends on Fan Mode Sequence MV58 value upon device discovery If required enumerations are not present set MV58 to desired value and rediscover MV16 object Available enumeration will
31. ts Table 10 Property enumeration sets for MV objects Object Name Object ID BACnet Index Text Default value 1 Cooling Only 2 Heating Only Sequence of 3 Cooling amp Reheat 15 Heating Onl Operation 4 Heating 8 Reheat NR 5 Cool Heat4P 6 Cool Heat4P amp Reht 1 Off System Mode 2 Auto Note 1 MES 3 Cool 4 Heat MV 17 1 2 3 4 Note 4 Note 5 Note 3 1 Local D d 97 MV 18 5 Occupied epends on networ Command command 3 Unoccupied 1 Level 0 2 Level 1 3 Level 2 Keypad Lockout 19 4 3 Level 0 5 Level 4 6 Level 5 NOTES 1 Enumeration sets for MV16 depends on Sequence of Operation MV15 value upon device discovery If required enumeration is not present set MV15 to desired value and rediscover MV16 object Available enumeration will now reflect required configuration 2 Default value of MV16 depends on MV15 value upon device discovery MV15 Index Function Default Value is BV50 Default Value is BV50 Enabled Disabled 1 Cooling Only Cool Cool 2 Cooling with Reheat Auto Heat 3 Heating Only Heat Heat 4 Heating with Reheat Heat Heat 5 Cooling Heating 4 Pipes Auto Heat 6 Cooling Heating 4 Pipes with Reheat Auto Heat 3 Enumeration sets for MV17 depends on Fan Mode Sequence MV58 value upon device discovery If required enu merat
32. ve Text Active Text Default value Room Temp Override BV8 Normal Override Normal Room Humidity Override BV 11 Normal Override Normal Dehumidification Lockout BV 13 Disabled Enabled Enabled AUX Command BV 14 Off On Off Dehumidification Status BI 23 Off On Off Aux Status BI 25 Off On Off BI 1 Status BI 29 Deactivated Activated Deactivated BI 2 Status BI 30 Deactivated Activated Deactivated UI 3 Status BI 31 Deactivated Activated Deactivated Local Motion BI 32 No Motion Motion No Motion Window Alarm BI 35 Off On Off Filter Alarm BI 36 Off On Off Service Alarm BI 37 Off On Off Menu Scroll BV 49 No Scroll Scroll Active Scroll Active Auto Mode Enable BV 50 Disabled Enabled Enabled Temperature Scale BV 51 C F F Setpoint Type BV 60 Permanent Temporary Permanent Setpoint Function BV 61 Dual Setpoints Attached Dual Setpoints Setpoints Reheat Time Base BV 64 15 minutes 10 seconds 15 minutes Auto Fan BV 66 Auto Speed Auto Speed Auto Auto Speed Demand RH Display BV 70 Disabled Enabled Disabled Control Type BV 75 On Off Floating On Off Direct Reverse Acting BV 78 Direct Acting Reverse Acting Direst Acting This object will be linked to the value of the UI 3 Configuration object When the UI 3 Configuration object value is 0 3 or 4 the value will be set to Deactivated 63 4524 01 22 BACNET INTEGRATION MANUAL FOR 7200 amp TB7300 SERIES THERMOSTATS Enumeration Sets for MV Objec
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