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| Description of Equipment
Active Chilled Beams (ACB) is a terminal-level equipment that uses the chilled water supply from the chiller and the air from an AHU to condition the space. Active Chilled Beam+ Dedicated Outside Air System (DOAS) is a terminal profile under the VAV system profile using SmartNode.
The SmartNode in CCU-connected mode/ the fail-safe mode provides the necessary controls to support the operation of the Active Chilled Beam equipment.
SmartNode
With SmartNode
| Control System Object List
Object Name | Type | Input/Output Type |
Heating Desired Temp | User Intent | NA |
Cooling Desired Temp | User Intent | NA |
Current Temp | Input | OWI Sensor |
Humidity | Input | OWI Sensor |
Occupancy Mode |
Input |
OWI Sensor |
Damper Actuator | Output | SmartNode/ Helionode Analog Out |
Water Valve Actuator | Output | SmartNode/ Helionode Analog Out |
Shutoff Valve | Output | SmartNode/ Helionode Relay |
Zone Priority | Input | User Intent/ Configuration Setup |
Damper Type | Input | User Intent/ Configuration Setup |
Discharge Airflow Temperature | Input | SmartNode/ HelioNode Thermistor |
Condensate Detection | Input | SmartNode/ HelioNode Thermistor |
Minimum Damper Position Cooling | Input | User Intent/ Configuration Setup |
Maximum Damper Position Cooling | Input | User Intent/ Configuration Setup |
Minimum Damper Position Heating | Input | User Intent/ Configuration Setup |
Maximum Damper Position Heating | Input | User Intent/ Configuration Setup |
Minimum CFM Cooling | Input | User Intent/ Configuration Setup |
Maximum CFM Cooling | Input | User Intent/ Configuration Setup |
Minimum CFM Reheating | Input | User Intent/ Configuration Setup |
Maximum CFM Reheating | Input | User Intent/ Configuration Setup |
Maximum Damper Heating | Input | User Intent/ Configuration Setup |
coolingPreconditioningRate | Tuner | 15 Mins |
heatingPreconditioningRate | Tuner | 15 Mins |
Note: For a comprehensive list of tuners and their details refer to Tuners Complete List
| Sequence of Operation
The sequence of operation is completely driven based on Occupancy mode, Space Current Temperature, the set Cooling and Heating Desired Temperatures, Supply Water temperature, and Space CO2 levels.
Let us understand the Sequence of operations based on the occupancy modes, and how the other factors contribute to the sequence of operations during different types of occupancy modes.
| Occupancy Modes
The occupancy mode (Occupied or Unoccupied) shall be determined through a user-adjustable, graphical, seven-day schedule with a holiday schedule, alongside the configurable autoaway and forced occupied options (external schedule influencers) for optimized controls and enhanced energy savings.
Based on the above aspects factoring into the occupancy the following can be the possible applicable occupancy modes:
- Pre- Conditioning
- Occupied
- Unoccupied
- Auto-Away
- Forced Occupied
| Sequence of Operation During Pre-Conditioning
Pre-conditioning is a state just before the building enters the scheduled occupancy. It starts at more like the unoccupied state, the desired temperatures drift to unoccupied setbacks.
The preconditioning uses an algorithm to start the conditioning before the building is scheduled for occupancy, from the heating side or cooling side, to bring the building to an optimum level ( within the occupied heating & cooling desired temperatures) exactly at the time of occupancy start.
A coolingPreconditioningRate and heatingPreconditiningRate tuners defaulted to 15 minutes, are used alongside the occupied heating/cooling desired temperature breach to determine when the pre-conditioning should start.
Example Calculation:`
When,
- The heating & cooling desired temperatures are 70F and 74F for the building,
- The current temperature is 76F (Average of zone temperatures),
- 8:00 AM is the time the building is scheduled to be occupied.
Then the preconditioning start time is calculated as follows:
Cooling Desired Temperature Breach= 76-74=2F
Preconditioning duration= coolingPreconditioningRate (mins) * Cooling Desired Temperature Breach
= 15*2
= 30 mins
The preconditioning starts 30 minutes before the building is scheduled to be occupied, which is = 7:30 AM.
The zones would operate as shown below to accommodate the preconditioning from the system equipment.
During Warm-up:
-
- If the space temperature is below the occupied heating temperature setpoint, the pre-conditioning shall initiate the morning warm-up via HeatingLoopOutput, as below:
If System Equipment in Cooling Mode | If System Equipment in Heating Mode |
And if no Condensate is detected:
And if Condensate is detected:
|
The HeatingLoopOutput is mapped to the Damper position actuator and further to modulating reheat or reheat stages. |
-
- The CO2 and IAQ loops are disabled. (If configured for)
- The CFM loop is disabled. (If configured for)
During Pre-cooling:
-
- If the space temperature is below the occupied Cooling temperature setpoint, the pre-conditioning shall initiate the morning pre-cooling via CoolingLoopOutput, as below:
If System Equipment in Cooling Mode | If System Equipment in Heating Mode |
And if no Condensate is detected:
And if Condensate is detected:
|
Note: This is a negative case, where the dampers will be maintained at their minimum position by the zone algorithm. On the system side when the system is doing heating and all zones are kept at minimum damper position owing to the contradicting zone and system conditioning, normalization will open the dampers from minimum towards 100%. |
-
- The CO2 and IAQ loops are disabled. (If configured for)
| Sequence of Operation During Occupied
At all occupied times: (based on a set schedule)
-
- The device maintains a space temperature within the Heating Desired Temperature and Cooling Desired Temperature Range.
During Deadband:
During deadband, the damper operation is influenced, based on the configuration of the profile, as follows.
Configuration | Damper Operation |
If only the zone temperature-based configuration is enabled. |
The damper shall be at its minimum position and the reheat valve will remain closed. The Damper minimum is decided based on the last known conditioning,
|
If zone Temperature & CO2-based configuration is enabled. |
The Damper position is driven based on the Zone CO2 levels. For more information on the actual calculation refer to VAV Terminal Profile- Damper Position Calculation & Operation Note: It is possible and likely that temperature control will not be as good when IAQ controls override the damper position. This is indicated by the iaqOverridingDamper being set to true. |
If zone Temperature & VOC-based configuration is enabled. |
The Damper position is driven based on the Zone VOC levels. For more information on the actual calculation refer to VAV Terminal Profile- Damper Position Calculation & Operation Note: It is possible and likely that temperature control will not be as good when IAQ controls override the damper position. This is indicated by the iaqOverridingDamper being set to true. |
If zone Temperature & CFM-based configuration is enabled. | The Damper position is driven based on the min-max CFM set. For more information on the actual calculation refer to VAV Terminal Profile- Damper Position Calculation & Operation |
If zone Temperature, IAQ (CO2 & VOC) & CFM-based configuration is enabled. | The Damper position is driven based on Temperature, IAQ, and CFM. For more information on the actual calculation refer to VAV Terminal Profile- Damper Position Calculation & Operation |
During Heating:
-
- When the space current temperature falls below the HeatingDesiredTemperature the HeatingLoopOutput is enabled as below as below
If System Equipment in Cooling Mode | If System Equipment in Heating Mode |
And if no Condensate is detected:
And if Condensate is detected:
|
The HeatingLoopOutput is mapped to the Damper position actuator and further to modulating reheat or reheat stages. |
-
- When the space CO2 & IAQ levels are above the thresholds the CO2/ IAQ loop Outputs drive the damper actuator for damper position. for more information refer to VAV Terminal Profile- Damper Position Calculation & Operation
-
- The CFM loop is disabled. (If configured for)
During Cooling:
-
- When the space current temperature is above the Cooling Desired Temperature the CoolingLoopOutput is enabled, as below.
If System Equipment in Cooling Mode | If System Equipment in Heating Mode |
And if no Condensate is detected:
And if Condensate is detected:
|
Note: This is a negative case, where the dampers will be maintained at their minimum position by the zone algorithm. On the system side when the system is doing heating and all zones are kept at minimum damper position owing to the contradicting zone and system conditioning, normalization will open the dampers from minimum towards 100%. |
-
- When the space CO2 & IAQ levels are above the thresholds the CO2/ IAQ loop Outputs drive the damper actuator for damper position. for more information refer to VAV Terminal Profile- Damper Position Calculation & Operation
| Sequence of Operation During Autoaway
-
- The range of Heating Desired Temperature and Cooling Desired Temperature drifts further away.
- The device maintains a space temperature within the newly set Heating Desired Temperature and Cooling Desired Temperature Range.
During Deadband:
-
- CoolingLoopOutput, HeatingLoopOutput, CFM LoopOutput, CO2, and IAQ Loop Output, are disabled.
During Heating:
-
- When the space current temperature falls below the heating autoaway setback temperature, the HeatingLoopOutput is enabled as below.
If System Equipment in Cooling Mode | If System Equipment in Heating Mode |
And if no Condensate is detected:
And if Condensate is detected:
|
The HeatingLoopOutput is mapped to the Damper position actuator and further to modulating reheat or reheat stages. |
-
- The CO2 and IAQ loops are disabled. (If configured for)
- The CFM loop is disabled. (If configured for)
During Cooling:
-
- When the space current is above the cooling the CoolingLoopOutput is enabled, as below.
If System Equipment in Cooling Mode | If System Equipment in Heating Mode |
And if no Condensate is detected:
And if Condensate is detected:
|
Note: This is a negative case, where the dampers will be maintained at their minimum position by the zone algorithm. On the system side when the system is doing heating and all zones are kept at minimum damper position owing to the contradicting zone and system conditioning, normalization will open the dampers from minimum towards 100%. |
-
- The CO2 and IAQ loops are disabled. (If configured for)
| Sequence of Operation During Unoccupied
-
- The range of Heating Desired Temperature and Cooling Desired Temperature drifts further away.
- The device maintains a space temperature within the newly set Heating Desired Temperature and Cooling Desired Temperature Range.
During Deadband:
-
- CoolingLoopOutput, HeatingLoopOutput, CFM LoopOutput, CO2, and IAQ Loop Output, are disabled.
During Heating:
-
- When the space's current temperature falls below the heating the HeatingLoopOutput is enabled as below.
If System Equipment in Cooling Mode | If System Equipment in Heating Mode |
And if no Condensate is detected:
And if Condensate is detected:
|
The HeatingLoopOutput is mapped to the Damper position actuator and further to modulating reheat or reheat stages. |
-
- The CO2 and IAQ loops are disabled. (If configured for)
- The CFM loop is disabled. (If configured for)
During Cooling:
-
- When the space current temperature is above the cooling the CoolingLoopOutput is enabled, as below.
If System Equipment in Cooling Mode | If System Equipment in Heating Mode |
And if no Condensate is detected:
And if Condensate is detected:
|
Note: This is a negative case, where the dampers will be maintained at their minimum position by the zone algorithm. On the system side when the system is doing heating and all zones are kept at minimum damper position owing to the contradicting zone and system conditioning, normalization will open the dampers from minimum towards 100%. |
-
- The CO2 and IAQ loops are disabled. (If configured for)
Note: The fan runs wherever the zone is occupied and when the reheat is enabled.
| Sequence of Operation During Forced Occupied
-
- The device maintains a space temperature within the Heating Desired Temperature and Cooling Desired Temperature Range.
During Deadband:
During deadband, the damper operation is influenced, based on the configuration of the profile, as follows.
Configuration | Damper Operation |
If only the zone temperature-based configuration is enabled. |
The damper shall be at its minimum position and the reheat valve will remain closed. The Dmaper minimum is decided based on the last known conditioning,
|
If zone Temperature & CO2-based configuration is enabled. |
The Damper position is driven based on the Zone CO2 levels. For more information on the actual calculation refer to VAV Terminal Profile- Damper Position Calculation & Operation Note: It is possible and likely that temperature control will not be as good when IAQ controls override the damper position. This is indicated by the iaqOverridingDamper being set to true. |
If zone Temperature & VOC-based configuration is enabled. |
The Damper position is driven based on the Zone VOC levels. For more information on the actual calculation refer to VAV Terminal Profile- Damper Position Calculation & Operation Note: It is possible and likely that temperature control will not be as good when IAQ controls override the damper position. This is indicated by the iaqOverridingDamper being set to true. |
If zone Temperature & CFM-based configuration is enabled. | The Damper position is driven based on the min-max CFM set. For more information on the actual calculation refer to VAV Terminal Profile- Damper Position Calculation & Operation |
If zone Temperature, IAQ (CO2 & VOC) & CFM-based configuration is enabled. | The Damper position is driven based on Temperature, IAQ, and CFM. For more information on the actual calculation refer to VAV Terminal Profile- Damper Position Calculation & Operation |
During Heating:
-
- When the space current temperature falls below the Heating Desired Temperature the HeatingLoopOutput is enabled as below.
If System Equipment in Cooling Mode | If System Equipment in Heating Mode |
And if no Condensate is detected:
And if Condensate is detected:
|
The HeatingLoopOutput is mapped to the Damper position actuator and further to modulating reheat or reheat stages. |
-
- The CO2 and IAQ loops are disabled. (If configured for)
- The CFM loop is disabled. (If configured for)
During Cooling:
-
- When the space current temperature is above the Cooling Desired Temperature the CoolingLoopOutput is enabled as below:
If System Equipment in Cooling Mode | If System Equipment in Heating Mode |
And if no Condensate is detected:
And if Condensate is detected:
|
Note: This is a negative case, where the dampers will be maintained at their minimum position by the zone algorithm. On the system side when the system is doing heating and all zones are kept at minimum damper position owing to the contradicting zone and system conditioning, normalization will open the dampers from minimum towards 100%. |
-
- The CO2 and IAQ loops are disabled. (If configured for)
| Sequence of Operation During Emergency Conditioning
When zone limits are violated, and the recorded temperature is within the zone limit plus leeway the conditioning will happen in the direction of zone load.
| Sequence of Operation During ZOne Temp Dead
And, When the zone temperature breaches the zone limits, beyond the leeway limits all the following loops are disabled:
-
- CoolingLoopOutput
- HeatingLoopOutput
- CO2 & IAQ LoopOutput
- CFM LoopOutput
| N/O, N/C Relay Based Water Valve Operation
Based on the water valve type used in the field, the configuration can be set to a Normally Open (N/O) or Normally Open (N/C).
The following table provides the operation details based on the type of water valve selected.
Selection | Operation |
When a Normally Close (N/C) type water valve is selected |
In this type of selection: When the Loop output is above the relay activation hysteresis (Default 10%)
When the Loop output is below the relay activation hysteresis (Default 10%) "or" When condensation is detected in the condensation sensor:
|
When a Normally Open (N/O) type water valve is selected |
The following steps occur in the algorithm to address the scenario: When the Loop output is above the relay activation hysteresis (Default 10%)
When the Loop output is below the relay activation hysteresis (Default 10%) "or" When condensation is detected in the condensation sensor:
|
| Control Mode Summary
Modes & Operation |
Pre-Conditioning | Occupied | AutoAway | Unoccupied | Forced Occupied |
Auto |
HeatingLoopOutput CoolingLoopOutput CFMLoopOutput |
HeatingLoopOutput CoolingLoopOutput CFMLoopOutput CO2LoopOutput IAQLoopOutput |
HeatingLoopOutput CoolingLoopOutput
|
HeatingLoopOutput CoolingLoopOutput
|
HeatingLoopOutput CoolingLoopOutput |
Heat Only |
HeatingLoopOutput |
HeatingLoopOutput CO2LoopOutput IAQLoopOutput |
HeatingLoopOutput |
HeatingLoopOutput |
HeatingLoopOutput CO2LoopOutput IAQLoopOutput |
Cool Only |
CoolingLoopOutput CFMLoopOutout |
CoolingLoopOutput CFMLoopOutput CO2LoopOutput IAQLoopOutput |
CoolingLoopOutput |
CoolingLoopOutput |
CoolingLoopOutput CO2LoopOutput IAQLoopOutput |
Off |
All Loops Deactivated |
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