Trane Understanding BACnet Thermostats and Tracer SC Integration
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Additional Information and Considerations

Rooftop and Heat Pump Units

Programs writing to the devices should have a structure similar to the following:

If Once Schedule = On then

 

Do Every 5min

MV11 = Occupied

 

If Schedule = On Then

End If

 

MV11= Occupied

If Once Schedule = Off

OR

Else

Then

 

MV11 = Unoccupied

MV11 = Unoccupied

 

End If

End If

 

End Do

Retries and Timeouts (Supervisory Controllers Other Than Tracer SC)

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

The 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.

Number of APDU Retries;

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 (Tracer SC) request, and the Retry Timeout is set to 2000 msec and the Number of APDU Retries is set to 1 (still at the Tracer SC level), then the Tracer SC will send one other request, 2 seconds 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.

Objects and Parameters

The following items apply to all equipment types.

Each thermostat is delivered from the factory with the default MAC address set at 254. At this value, the BACnet communication is NOT active and the device will not participate in the token pass either. The local LED status (located on the backside of the board) is one short flash only. To enable the BACnet communication, set the local MAC address configuration property of the thermostat to any valid value from 0 to 127 using the Installer Configuration Parameter menuon the Thermostat. (Refer to the Trane Communicating Thermostats for Heat Pump Control User Guide (BAS-SVU10A-EN), Trane Communicating Thermostats for Rooftop Control User Guide (BAS-SVU11A-EN), or the Trane Communicating Thermostats for Fan Coil Control User Guide (BAS-SVU12A-EN) for details.)

All configuration objects are available and can be edited locally from the device itself using the local configuration routine. (See the Communicating Thermostat User Guides mentioned previously in this section or in “Related Documents,” p. 6.)

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 automatic baud rate detection. Re-powering the devices will force immediate auto-detection.

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BAS-SVP10A-EN

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Contents Integration Manual Copyright Table of Contents Objects and Parameters Tracer SC Network Configuration Overview Product DescriptionPlanning Your Integration How To InformationRelated Documents OverviewSummary of BACnet Objects Supported BACnet ServicesDefault Device Name and Default Device ID BACnet Interoperability Building BlocksX13511541010 and -2010 Rooftop and Heat Pump Models Fan Coil ObjectsSummary of BACnet Objects Objects table for fan coilsOutput Configuration Options GRP PresentValue R General Options GRP PresentValue RType Rooftop Rooftop and Heat Pump ObjectsRooftop and heat pump ungrouped objects Object Name Instance Object Property 1010 2010Stages Configuration GRP PresentValue R Options Economizer Model GRP PresentValue R Configuration OptionsHeatpump Model GRP PresentValue R Configuration Options Standard Object Types Supported Standard object types supportedList of Proprietary Properties Configuration Objects for Fan CoilsConfiguration Objects for Rooftop and Heat Pump Units Proprietary PropertiesBACnet Object Properties Fan Coil Object PropertiesList of property value range restrictions List of property enumeration sets for MV objects Object Name Object ID BACnet Index Text Default valueBACnet Object Properties Table NoteMV15 Sequence of Operation values for Note Object Name Object ID BACnet Index Text Default valueFunction MV58 MV17 Index State Text Index Default Value Additional MV valuesFunction MV26 BV75 Value MV52 Index MV27 Object Name State Text IndexHour Hours Value Rooftop and Heat Pump Object PropertiesObject Type Under Range Object Name Over Range ValueUnder Range List of property enumeration sets for BI and BV objectsObject Type Object Name Instance InactiveText ActiveText Instance Value Over Range ValueObject Name Instance BACnet Index Text Object TypeNone RemNSB DI1 Configuration MV65 RemOVR Filter Service Objects You Can Use in Site Graphics Fan CoilsRooftop and Heat Pump Units Objects You Can Use in Site GraphicsWiring Requirements for Communicating Thermostats BACnet MS/TP Link WiringWiring Requirements for Communicating Thermostats Daisy chain configuration for BACnet wiringNetwork Adapter Product SpecificationsCommunicating Thermostat Specifications DetailsPossible Cause Solution TroubleshootingCauses and solutions for error condition Communicating Thermostat Status LEDsAdditional Information and Considerations MS/TP Network IntegrationFan Coils Objects and Parameters Additional Information and Considerations Night Purge disabled Tracer SC Network ConfigurationNo automatic installation No priority arrayHeat only/cool only Parameters not supportedNo active setpoint or heat/cool mode data Discharge air temp requirementsInappropriate text on graphic displays BAS-SVP10A-EN Data Normalization Example Occupancy RequestTemplate TStatFanCoilTrane Tracer SC writing to the fan coil Heat Cool Mode Request Reading from fan coil to Tracer SC Heat Cool Mode RequestData Normalization Tracer SC writing to the fan coil Fan Mode BAS Reading from fan coil to tracer SC Fan Mode BASTracer SC Point name Supply Fan Staged Speed Status Reading from heat pump to Tracer SC Occupancy Status Template TStatHeatPumpTraneTracer SC writing to the heat pump Occupancy Status Tracer SC writing to the heat pump Occupancy RequestTemplate TStatRTUTrane Tracer SC writing to the heat pump Heat Cool Mode RequestReading from Heat Pump to Tracer SC Heat Cool Mode Request Tracer SC writing to the rooftop unit Occupancy StatusTracer SC writing to the rooftop unit Occupancy Request Reading from rooftop unit to Tracer SC Occupancy RequestPoints Available in the TStatFanCoilTrane Template Trane Communicating Thermostat Points ListTStatFanCoilTrane TStat Device PointPoints Available in the TStatHeatPumpTrane Template TStatHeatPumpTrane TemplateTrane Communicating Thermostat Points List Point Type Instance TionPoint Type TStatRTUTrane TemplatePoints Available in the TStatRTUTrane Template YesAUX Page

BAS-SVP10A-EN, Trane Communicating Thermostats (BACnet) specifications

The Trane BAS-SVP10A-EN is a part of the Trane Communicating Thermostats series designed to facilitate efficient and effective building temperature control in HVAC systems. These thermostats work with BACnet (Building Automation and Control Network), a widely adopted communication protocol in building automation for networked control of HVAC systems, lighting, access control, and fire systems.

One of the standout features of the Trane BAS-SVP10A-EN is its compatibility with various Trane equipment and other BACnet-compliant devices. This versatility allows for seamless integration into existing building systems, enhancing operational efficiency. The thermostat is designed to support zoning applications, offering precise temperature control to individual areas or rooms, thus significantly improving occupant comfort while also minimizing energy consumption.

The Trane communicating thermostat is built with advanced technologies that ensure optimal performance. It utilizes digital communication, enabling real-time data exchange between the thermostat and the HVAC system. This capability enhances the responsiveness of the HVAC system, allowing it to adjust more accurately to changing environmental conditions. The thermostat features an intuitive interface with a clear display, making it user-friendly for building occupants and facility managers alike.

Another important characteristic is its advanced scheduling capabilities. Users can program customized heating and cooling schedules, promoting energy savings while maintaining comfort levels. Additionally, its remote access feature allows for monitoring and control from smartphones, tablets, or computers, making it convenient for users to manage their HVAC systems from virtually anywhere.

The Trane BAS-SVP10A-EN also boasts robust diagnostic and reporting functions. It can provide feedback on system performance, enabling proactive maintenance and troubleshooting, which increases the reliability of HVAC operations. Overall, the Trane Communicating Thermostat represents a sophisticated solution for modern building management, focusing on comfort, energy efficiency, and ease of integration into existing systems. With its commitment to leveraging cutting-edge technology, Trane continues to lead in providing innovative solutions for heating, ventilation, and air conditioning needs in diverse building environments.
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