General
This group of building descriptors applies to all cooling systems.
| Cooling Source | |
| Applicability | All systems |
|---|---|
| Definition | The source of cooling for the system. The choices are:
|
| Units | List (see above) |
| Input Restrictions | As designed |
| Baseline Rules | The baseline building cooling source is shown in [bookref id="cooling-source-for-baseline-building-system"]. See [bookref id="hvac-mapping"] for HVAC system mapping. |
[table title="Cooling Source for Baseline Building System" id="cooling-source-for-baseline-building-system"]
| Baseline building System | Cooling Source |
| System 1 – PTAC | Direct expansion (DX) |
| System 2 – PTHP | Direct expansion (DX) |
| System 3 – PSZ-AC | Direct expansion (DX) |
| System 4 – PSZ-HP | Direct expansion (DX) |
| System 5 – Packaged VAV with Reheat | Direct expansion (DX) |
| System 6 – Packaged VAV with PFP boxes | Direct expansion (DX) |
| System 7 – VAV with Reheat | Chilled water |
| System 8 – VAV with PFP boxes | Chilled water |
| Total Cooling Capacity | |||||||
| Applicability | All cooling systems | ||||||
|---|---|---|---|---|---|---|---|
| Definition | The total cooling capacity (both sensible and latent) of a cooling coil or packaged DX system at ARI conditions. The building descriptors defined in this chapter assume that the fan is modeled separately, including any heat it adds to the air stream. The cooling capacity specified by this building descriptor should not consider the heat of the fan. | ||||||
| Units | kBtu/h | ||||||
| Input Restrictions |
As designed. For packaged equipment that has the fan motor in the air stream such that it adds heat to the cooled air, the software shall adjust the total cooling capacity as follows: (6.7.5-1) $ Q_{t,adj} = Q_{t,rated} + B\!H\!P_{supply} \times 2.545 $
If the number of unmet load hours in the proposed design exceeds 300, the software shall warn the user to resize the equipment. |
||||||
| Baseline Rules | The total cooling capacity of the baseline building is oversized by 15%. However, the cooling equipment may need to be subsequently downsized such that the difference in unmet load hours between the proposed design and the baseline building is less than 50 (see Chapter 2). Sizing calculations shall be based on 1% dry-bulb and 1% wet-bulb design conditions. | ||||||
| Sensible Cooling Capacity | |||||||
| Applicability | All cooling systems | ||||||
|---|---|---|---|---|---|---|---|
| Definition | The sensible heat cooling capacity of the coil or packaged equipment at ARI conditions. The building descriptors defined in this chapter assume that the fan is modeled separately, including any heat it adds to the air stream. The cooling capacity specified by this building descriptor should not consider the heat of the fan. | ||||||
| Units | kBtu/h | ||||||
| Input Restrictions |
As designed. For packaged equipment that has the fan motor located in the air stream such that it adds heat to the cooled air, the software shall adjust the sensible cooling capacity as follows: (6.7.5-2) $ Q_{s,adj} = Q_{s,rated} + B\!H\!P_{supply} \times 2.545 $
If the number of unmet load hours in the proposed design exceeds 300, the software shall warn the user to resize the equipment. |
||||||
| Baseline Rules | The sensible cooling capacity of the baseline building is oversized by 15%. However, the cooling equipment may need to be subsequently downsized such that the difference in unmet load hours between the proposed design and the baseline building is less than 50 (see Chapter 2). Sizing calculations shall be based on 1% dry-bulb and 1% wet-bulb design conditions. | ||||||
| Cooling Capacity Adjustment Curves | |||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
| Applicability | All cooling systems | ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
| Definition |
A curve that represents the available total cooling capacity as a function of cooling coil and/or condenser conditions. The common form of these curves is given as follows: (6.7.5-3) $ Q_{t,available} = C\!A\!P\!\_FT \times Q_{t,adj} $ (6.7.5-4) $$ C\!AP\!\_FT = a + b \times t_{wb} + c \times \left. t_{wb} \right. ^2 + d \times t_{odb} + e \times \left. t_{odb} \right. ^2 + f \times t_{wb} \times t_{odb}$$ For water cooled direct expansion (6.7.5-5) $$ C\!AP\!\_FT = a + b \times t_{wb} + c \times \left. t_{wb} \right. ^2 + d \times t_{wt} + e \times \left. t_{wt} \right. ^2 + f \times t_{wb} \times t_{wt}$$ For chilled water coils (6.7.5-6) $$ C\!AP\!\_FT = a + b \times t_{wb} + c \times \left. t_{wb} \right. ^2 + d \times t_{db} + e \times \left. t_{db} \right. ^2 + f \times t_{wb} \times t_{db}$$ where
Note: if an air-cooled unit employs an evaporative condenser, todb is the effective dry-bulb temperature of the air leaving the evaporative cooling unit.
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| Units | Data structure | ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
| Input Restrictions | As designed. The equations and coefficients given above are the default. | ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
| Baseline Rules | Use the default curves or equivalent data for other models. | ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
| Coil Bypass Factor | |||||||||||
| Applicability | All cooling systems | ||||||||||
|---|---|---|---|---|---|---|---|---|---|---|---|
| Definition | The ratio of air that bypasses the cooling coil at design conditions to the total system airflow. | ||||||||||
| Units | Ratio | ||||||||||
| Input Restrictions |
As designed. Default values are given in [bookref id="default-coil-bypass-factors"].
|
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| Baseline Rules | Defaults | ||||||||||
| Coil Bypass Factor Adjustment Curve | |||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
| Applicability | All cooling systems | ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
| Definition | Adjustments for the amount of coil bypass due to the following factors:
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| Units | Data structure | ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
| Input Restrictions |
Default to the simulation engine defaults based on HVAC system type. The following default values shall be used for the adjustment curves: (6.7.5-7) $$ C\!B\!F_{adj} = C\!B\!F_{rated} \times COI\!L - B\!F - F\!F\!LOW \times COI\!L - B\!F - FT \times COI\!L - B\!F - F\!P\!L\!R$$ (6.7.5-8) $$ CO\!I\!L - B\!F - F\!F\!LOW = a +b \times C\!F\!M\!R + c \times C\!F\!M\!R^2 +d \times C\!F\!M\!R^3 $$ (6.7.5-9) $$ COI\!L - B\!F - FT = a +b \times T_{wb} + c \times \left. T_{wb} \right. ^2 +d \times T_{db} +e \times \left. T_{db} \right. ^2 +f \times T_{wb} \times T_{db} $$ (6.7.5-10) $$ CO\!I\!L - B\!F - F\!P\!LR = a +b \times P\!LR$$ where
And the coefficients are listed in the tables below. [table title="Coil Bypass Factor Airflow Adjustment Factor" id="coil-bypass-factor-airflow-adjustment-factor"]
[table title="Coil Bypass Factor Temperature Adjustment Factor" id="coil-bypass-factor-temperature-adjustment-factor"]
[table title="Coil Bypass Factor Part Load Adjustment Factor" id="coil-bypass-factor-part-load-adjustment-actor"]
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| Baseline Rules | Use defaults as described above. | ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
Direct Expansion
| Direct Expansion Cooling Efficiency | |||||||||
| Applicability | Packaged equipment | ||||||||
|---|---|---|---|---|---|---|---|---|---|
| Definition |
The cooling efficiency of a direct expansion (DX) cooling system at ARI rated conditions as a ratio of output over input in Btu/h per W, excluding fan energy. The software must accommodate user input in terms of either the Energy Efficiency Ratio (EER) or the Seasonal Energy Efficiency Ratio (SEER). For equipment with SEER ratings, EER shall be taken from manufacturers’ data when it is available. When it is not available it shall be calculated as follows: (6.7.5-11) $ EER = 10 - \left ( 11.5 - SEER \right ) \times 0.83\ when\ SEER \textless\!=11.5 \\ = 10 \ when\ SEER\ \textgreater\!=11.5$ For all unitary and applied equipment where the fan energy is part of the equipment efficiency rating, the EER shall be adjusted as follows: (6.7.5-12) $$ E\!E\!R_{adj} = \frac{Q_{t,rated} + B\!H\!P_{supply} \times 2.545}{\frac{Q_{t,rated}}{E\!E\!R} - B\!H\!P_{supply} \times 0.7457}$$ where
|
||||||||
| Units | Btu/h-W | ||||||||
| Input Restrictions | As designed. When possible, specify the SEER and EER for packaged equipment with cooling capacity less than 65,000 Btu/h. For equipment with capacity above 65,000 Btu/h, specify EER. | ||||||||
| Baseline Rules | For the purpose of green building ratings, look up the requirement from Table 6.8.1A and Table 6.8.1B in ASHRAE Standard 90.1-2007. For the purpose of tax deduction calculations, look up the requirement from Table 6.2.1A and 6.2.1B in ASHRAE Standard 90.1-2001. Use the total cooling capacity of the proposed design to determine the size category. | ||||||||
| Direct Expansion Cooling Efficiency Adjustment Curve | |||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
| Applicability | Packaged DX equipment | ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
| Definition |
A curve or group of curves that varies the cooling efficiency of a direct expansion (DX) coil as a function of evaporator conditions, condenser conditions and part-load ratio. The default curves are given as follows as adjustments to the energy input ratio (EIR)1 : (6.7.5-13) $$ P\!LR = \frac{Q_{operating}}{Q_{available}\left ( t_{wb},t_{odb/wt}\right )}$$ (6.7.5-14) $$ E\!I\!R\_F\!P\!LR = a + b \times P\!LR + c \times P\!LR^2 + d \times P\!LR^3$$ (6.7.5-15) For air-cooled DX systems: (6.7.5-16) For water-cooled DX systems: (6.7.5-17) $$ P_{operating} = P_{rated} \times E\!I\!R\_F\!P\!LR \times E\!I\!R\_FT \times C\!A\!P\_FT$$ where
Note: if an air-cooled unit employs an evaporative condenser, todb is the effective dry-bulb temperature of the air leaving the evaporative cooling unit. [table title="Cooling System Coefficients for EIR-FPLR" id="cooling-system-coefficients-for-EIR-FPLR"]
[table title="Cooling System Coefficients for EIR-FT" id="Cooling System Coefficients for EIR-FT"]
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| Units | Data structure | ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
| Input Restrictions | User may input curves or use default curves. If defaults are overridden, the software must indicate that supporting documentation is required on the output forms. | ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
| Baseline Rules | Use default curves. | ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
| Minimum Unloading Ratio | |
| Applicability | Packaged systems which use hot-gas bypass during low load conditions |
|---|---|
| Definition | The upper end of the hot-gas bypass operating range. This is the percentage of peak cooling capacity below which hot-gas bypass will operate. |
| Units | Ratio |
| Input Restrictions | As designed. The user must enter this descriptor for each DX cooling system. If hot-gas bypass is not employed, a value of 0 may be entered. A maximum of 0.5 is allowed for units with a peak cooling capacity of 240 kBtu/h (20 tons) or less, and a maximum value of 0.25 is allowed for units with a peak cooling capacity greater than 240 kBtu/h. |
| Baseline Rules | Not applicable |
| Minimum HGB Ratio | |
| Applicability | Packaged systems which use hot-gas bypass during low load conditions |
|---|---|
| Definition | The lower end of the hot-gas bypass operating range. The percentage of peak cooling capacity below which hot-gas bypass will no longer operate (i.e. the compressor will cycle). |
| Units | Ratio |
| Input Restrictions | As designed. The user must enter this descriptor for each DX cooling system. If hot-gas bypass is not employed, a value of 0 may be entered. |
| Baseline Rules | Not applicable |
| Condenser Type | |
| Applicability | All direct expansion systems including heat pumps |
|---|---|
| Definition | The type of condenser for a direct expansion (DX) cooling system. The choices are:
|
| Units | List (see above) |
| Input Restrictions | As designed |
| Baseline Rules | Based on the prescribed system type. Refer to the HVAC System Map in [bookref id="hvac-mapping"]. |
[table title="Baseline Building Condenser Type" id="baseline-building-condenser-type"]
| Baseline building System | Condenser Type |
| System 1 – PTAC | Air-cooled |
| System 2 – PTHP | Air-cooled |
| System 3 – PSZ-AC | Air-cooled |
| System 4 – PSZ-HP | Air-Cooled |
| System 5 – Packaged VAV with Reheat | Air-cooled |
| System 6 – Packaged VAV with PFP boxes | Air-cooled |
| System 7 – VAV with Reheat | N/A |
| System 8 – VAV with PFP boxes | N/A |
| Condenser Flow Type | |
| Applicability | All direct expansion systems including heat pumps |
|---|---|
| Definition | Describes water flow control for a water-cooled condenser. The choices are:
|
| Units | List (see above) |
| Input Restrictions | Default to fixed flow. If the variable-flow is selected, the software must indicate that supporting documentation is required on the output forms. |
| Baseline Rules | Always fixed flow |
Evaporative Cooler
This is equipment that pre-cools the outside air that is brought into the building. It may be used with any type of cooling system that brings in outside air. This equipment is not applicable for the baseline building.
| Evaporative Cooling Type | |
| Applicability | Systems with evaporative pre-cooling |
|---|---|
| Definition |
The type of evaporative pre-cooler, including:
In all cases, the evaporative pre-cooler must be modeled with 100% of the outside air routed through the pre-cooler. |
| Units | None |
| Input Restrictions | As designed |
| Baseline Rules | Not applicable |
| Direct Stage Effectiveness | |||||||||
| Applicability | Systems with evaporative pre-cooling | ||||||||
|---|---|---|---|---|---|---|---|---|---|
| Definition |
The effectiveness of the direct stage of an evaporative cooling system. Effectiveness is defined as follows: (6.7.5-18) $$ DirectE\!F\!F = \frac{T_{db} - T_{direct}}{T_{db} - T_{wb}}$$ where
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| Units | Numeric | ||||||||
| Input Restrictions | As designed | ||||||||
| Baseline Rules | Not applicable | ||||||||
| Indirect Stage Effectiveness | |||||||||
| Applicability | Systems with evaporative pre-cooling | ||||||||
|---|---|---|---|---|---|---|---|---|---|
| Definition |
The effectiveness of the indirect stage of an evaporative cooling system. Effectiveness is defined as follows: (6.7.5-19) $$ IndE\!F\!F = \frac {T_{db} - T_{ind}}{T_{db} - T_{wb}}$$ where
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| Units | Numeric | ||||||||
| Input Restrictions | As designed | ||||||||
| Baseline Rules | Not applicable | ||||||||
| Evaporative Cooling Performance Curves | |||||||||||||||||||||
| Applicability | Systems with evaporative cooling | ||||||||||||||||||||
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
| Definition |
A curve that varies the evaporative cooling effectiveness as a function of primary air stream airflow. The default curves are given as follows: (6.7.5-20) $$ P\!LR = \frac {C\!F\!M_{operating}}{C\!F\!M_{design}}$$ $$ E\!F\!F\_F\!F\!LOW = a+ b \times P\!LR + c \times P\!LR^2 $$ where
[table title="Part Load Curve Coefficients – Evaporative Cooler Effectiveness" id="part-load-curve-coefficients-–-evaporative-cooler-effectiveness"]
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| Units | Data structure | ||||||||||||||||||||
| Input Restrictions | User may input curves or use default curves. If defaults are overridden, the software must indicate that supporting documentation is required on the output forms. | ||||||||||||||||||||
| Baseline Rules | Not used. | ||||||||||||||||||||
| Auxiliary Evaporative Cooling Power | |
| Applicability | Systems with evaporative cooling |
|---|---|
| Definition | The auxiliary energy of the indirect evaporative cooler fan, and the pumps for both direct and indirect stages |
| Units | kW/cfm |
| Input Restrictions | As designed |
| Baseline Rules | Not applicable |
| Evaporative Cooling Scavenger Air Source | |
| Applicability | Systems with evaporative cooling |
|---|---|
| Definition | The source of scavenger air for an indirect section of an evaporative cooler. Options include:
|
| Units | List (see above) |
| Input Restrictions | As designed |
| Baseline Rules | Not applicable |
Evaporative Condenser
| Evaporative Condenser Power | |
| Applicability | Direct expansion systems with an evaporatively cooled condenser |
|---|---|
| Definition | The power of the evaporative precooling unit. This includes any pump(s) and/or fans that are part of the precooling unit. |
| Units | Kilowatts (kW) |
| Input Restrictions | As designed |
| Baseline Rules | Not applicable |
| Evaporative Condenser Effectiveness | |||||||||
| Applicability | Direct expansion systems with an evaporatively cooled condenser | ||||||||
|---|---|---|---|---|---|---|---|---|---|
| Definition | The effectiveness of the evaporative precooling unit for a condenser. Effectiveness is defined as follows:
(6.7.5-21) $$ DirectE\!F\!F = \frac {T_{db} - T_{direct}}{T_{db} - T_{wb}}$$ where
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| Units | Ratio | ||||||||
| Input Restrictions | As designed | ||||||||
| Baseline Rules | Not applicable | ||||||||
| Evaporative Condenser Operation Range | |
| Applicability | Direct expansion systems with an evaporatively cooled condenser. |
|---|---|
| Definition |
The temperature range within which the evaporative condenser operates. Two values are provided: Tmaximum The threshold outside air dry-bulb temperature below which evaporative condenser operates. Tminimum The threshold outside air dry-bulb temperature above which evaporative condenser operates. |
| Units | Degrees Fahrenheit (°F) |
| Input Restrictions | As designed |
| Baseline Rules | Not applicable |
- 1The EIR is the ratio of energy used by the system to cooling capacity in the same units. It is the reciprocal of the coefficient of performance (COP).
General
This group of building descriptors applies to all cooling systems.
| Cooling Source | |
| Applicability | All systems |
|---|---|
| Definition | The source of cooling for the system. The choices are:
|
| Units | List (see above) |
| Input Restrictions | As designed |
| Baseline Rules | The baseline building cooling source is shown in [bookref id="cooling-source-for-baseline-building-system"]. See [bookref id="hvac-mapping"] for HVAC system mapping. |
[table title="Cooling Source for Baseline Building System" id="cooling-source-for-baseline-building-system"]
| Baseline building System | Cooling Source |
| System 1 – PTAC | Direct expansion (DX) |
| System 2 – PTHP | Direct expansion (DX) |
| System 3 – PSZ-AC | Direct expansion (DX) |
| System 4 – PSZ-HP | Direct expansion (DX) |
| System 5 – Packaged VAV with Reheat | Direct expansion (DX) |
| System 6 – Packaged VAV with PFP boxes | Direct expansion (DX) |
| System 7 – VAV with Reheat | Chilled water |
| System 8 – VAV with PFP boxes | Chilled water |
| Total Cooling Capacity | |||||||
| Applicability | All cooling systems | ||||||
|---|---|---|---|---|---|---|---|
| Definition | The total cooling capacity (both sensible and latent) of a cooling coil or packaged DX system at ARI conditions. The building descriptors defined in this chapter assume that the fan is modeled separately, including any heat it adds to the air stream. The cooling capacity specified by this building descriptor should not consider the heat of the fan. | ||||||
| Units | kBtu/h | ||||||
| Input Restrictions |
As designed. For packaged equipment that has the fan motor in the air stream such that it adds heat to the cooled air, the software shall adjust the total cooling capacity as follows: (6.7.5-1) $ Q_{t,adj} = Q_{t,rated} + B\!H\!P_{supply} \times 2.545 $
If the number of unmet load hours in the proposed design exceeds 300, the software shall warn the user to resize the equipment. |
||||||
| Baseline Rules | The total cooling capacity of the baseline building is oversized by 15%. However, the cooling equipment may need to be subsequently downsized such that the difference in unmet load hours between the proposed design and the baseline building is less than 50 (see Chapter 2). Sizing calculations shall be based on 1% dry-bulb and 1% wet-bulb design conditions. | ||||||
| Sensible Cooling Capacity | |||||||
| Applicability | All cooling systems | ||||||
|---|---|---|---|---|---|---|---|
| Definition | The sensible heat cooling capacity of the coil or packaged equipment at ARI conditions. The building descriptors defined in this chapter assume that the fan is modeled separately, including any heat it adds to the air stream. The cooling capacity specified by this building descriptor should not consider the heat of the fan. | ||||||
| Units | kBtu/h | ||||||
| Input Restrictions |
As designed. For packaged equipment that has the fan motor located in the air stream such that it adds heat to the cooled air, the software shall adjust the sensible cooling capacity as follows: (6.7.5-2) $ Q_{s,adj} = Q_{s,rated} + B\!H\!P_{supply} \times 2.545 $
If the number of unmet load hours in the proposed design exceeds 300, the software shall warn the user to resize the equipment. |
||||||
| Baseline Rules | The sensible cooling capacity of the baseline building is oversized by 15%. However, the cooling equipment may need to be subsequently downsized such that the difference in unmet load hours between the proposed design and the baseline building is less than 50 (see Chapter 2). Sizing calculations shall be based on 1% dry-bulb and 1% wet-bulb design conditions. | ||||||
| Cooling Capacity Adjustment Curves | |||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
| Applicability | All cooling systems | ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
| Definition |
A curve that represents the available total cooling capacity as a function of cooling coil and/or condenser conditions. The common form of these curves is given as follows: (6.7.5-3) $ Q_{t,available} = C\!A\!P\!\_FT \times Q_{t,adj} $ (6.7.5-4) $$ C\!AP\!\_FT = a + b \times t_{wb} + c \times \left. t_{wb} \right. ^2 + d \times t_{odb} + e \times \left. t_{odb} \right. ^2 + f \times t_{wb} \times t_{odb}$$ For water cooled direct expansion (6.7.5-5) $$ C\!AP\!\_FT = a + b \times t_{wb} + c \times \left. t_{wb} \right. ^2 + d \times t_{wt} + e \times \left. t_{wt} \right. ^2 + f \times t_{wb} \times t_{wt}$$ For chilled water coils (6.7.5-6) $$ C\!AP\!\_FT = a + b \times t_{wb} + c \times \left. t_{wb} \right. ^2 + d \times t_{db} + e \times \left. t_{db} \right. ^2 + f \times t_{wb} \times t_{db}$$ where
Note: if an air-cooled unit employs an evaporative condenser, todb is the effective dry-bulb temperature of the air leaving the evaporative cooling unit.
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| Units | Data structure | ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
| Input Restrictions | As designed. The equations and coefficients given above are the default. | ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
| Baseline Rules | Use the default curves or equivalent data for other models. | ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
| Coil Bypass Factor | |||||||||||
| Applicability | All cooling systems | ||||||||||
|---|---|---|---|---|---|---|---|---|---|---|---|
| Definition | The ratio of air that bypasses the cooling coil at design conditions to the total system airflow. | ||||||||||
| Units | Ratio | ||||||||||
| Input Restrictions |
As designed. Default values are given in [bookref id="default-coil-bypass-factors"].
|
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| Baseline Rules | Defaults | ||||||||||
| Coil Bypass Factor Adjustment Curve | |||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
| Applicability | All cooling systems | ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
| Definition | Adjustments for the amount of coil bypass due to the following factors:
|
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| Units | Data structure | ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
| Input Restrictions |
Default to the simulation engine defaults based on HVAC system type. The following default values shall be used for the adjustment curves: (6.7.5-7) $$ C\!B\!F_{adj} = C\!B\!F_{rated} \times COI\!L - B\!F - F\!F\!LOW \times COI\!L - B\!F - FT \times COI\!L - B\!F - F\!P\!L\!R$$ (6.7.5-8) $$ CO\!I\!L - B\!F - F\!F\!LOW = a +b \times C\!F\!M\!R + c \times C\!F\!M\!R^2 +d \times C\!F\!M\!R^3 $$ (6.7.5-9) $$ COI\!L - B\!F - FT = a +b \times T_{wb} + c \times \left. T_{wb} \right. ^2 +d \times T_{db} +e \times \left. T_{db} \right. ^2 +f \times T_{wb} \times T_{db} $$ (6.7.5-10) $$ CO\!I\!L - B\!F - F\!P\!LR = a +b \times P\!LR$$ where
And the coefficients are listed in the tables below. [table title="Coil Bypass Factor Airflow Adjustment Factor" id="coil-bypass-factor-airflow-adjustment-factor"]
[table title="Coil Bypass Factor Temperature Adjustment Factor" id="coil-bypass-factor-temperature-adjustment-factor"]
[table title="Coil Bypass Factor Part Load Adjustment Factor" id="coil-bypass-factor-part-load-adjustment-actor"]
|
||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
| Baseline Rules | Use defaults as described above. | ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
Direct Expansion
| Direct Expansion Cooling Efficiency | |||||||||
| Applicability | Packaged equipment | ||||||||
|---|---|---|---|---|---|---|---|---|---|
| Definition |
The cooling efficiency of a direct expansion (DX) cooling system at ARI rated conditions as a ratio of output over input in Btu/h per W, excluding fan energy. The software must accommodate user input in terms of either the Energy Efficiency Ratio (EER) or the Seasonal Energy Efficiency Ratio (SEER). For equipment with SEER ratings, EER shall be taken from manufacturers’ data when it is available. When it is not available it shall be calculated as follows: (6.7.5-11) $ EER = 10 - \left ( 11.5 - SEER \right ) \times 0.83\ when\ SEER \textless\!=11.5 \\ = 10 \ when\ SEER\ \textgreater\!=11.5$ For all unitary and applied equipment where the fan energy is part of the equipment efficiency rating, the EER shall be adjusted as follows: (6.7.5-12) $$ E\!E\!R_{adj} = \frac{Q_{t,rated} + B\!H\!P_{supply} \times 2.545}{\frac{Q_{t,rated}}{E\!E\!R} - B\!H\!P_{supply} \times 0.7457}$$ where
|
||||||||
| Units | Btu/h-W | ||||||||
| Input Restrictions | As designed. When possible, specify the SEER and EER for packaged equipment with cooling capacity less than 65,000 Btu/h. For equipment with capacity above 65,000 Btu/h, specify EER. | ||||||||
| Baseline Rules | For the purpose of green building ratings, look up the requirement from Table 6.8.1A and Table 6.8.1B in ASHRAE Standard 90.1-2007. Use the total cooling capacity of the proposed design to determine the size category. | ||||||||
| Direct Expansion Cooling Efficiency Adjustment Curve | |||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
| Applicability | Packaged DX equipment | ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
| Definition |
A curve or group of curves that varies the cooling efficiency of a direct expansion (DX) coil as a function of evaporator conditions, condenser conditions and part-load ratio. The default curves are given as follows as adjustments to the energy input ratio (EIR)1 : (6.7.5-13) $$ P\!LR = \frac{Q_{operating}}{Q_{available}\left ( t_{wb},t_{odb/wt}\right )}$$ (6.7.5-14) $$ E\!I\!R\_F\!P\!LR = a + b \times P\!LR + c \times P\!LR^2 + d \times P\!LR^3$$ (6.7.5-15) For air-cooled DX systems: (6.7.5-16) For water-cooled DX systems: (6.7.5-17) $$ P_{operating} = P_{rated} \times E\!I\!R\_F\!P\!LR \times E\!I\!R\_FT \times C\!A\!P\_FT$$ where
Note: if an air-cooled unit employs an evaporative condenser, todb is the effective dry-bulb temperature of the air leaving the evaporative cooling unit. [table title="Cooling System Coefficients for EIR-FPLR" id="cooling-system-coefficients-for-EIR-FPLR"]
[table title="Cooling System Coefficients for EIR-FT" id="Cooling System Coefficients for EIR-FT"]
|
||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
| Units | Data structure | ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
| Input Restrictions | User may input curves or use default curves. If defaults are overridden, the software must indicate that supporting documentation is required on the output forms. | ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
| Baseline Rules | Use default curves. | ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
| Minimum Unloading Ratio | |
| Applicability | Packaged systems which use hot-gas bypass during low load conditions |
|---|---|
| Definition | The upper end of the hot-gas bypass operating range. This is the percentage of peak cooling capacity below which hot-gas bypass will operate. |
| Units | Ratio |
| Input Restrictions | As designed. The user must enter this descriptor for each DX cooling system. If hot-gas bypass is not employed, a value of 0 may be entered. A maximum of 0.5 is allowed for units with a peak cooling capacity of 240 kBtu/h (20 tons) or less, and a maximum value of 0.25 is allowed for units with a peak cooling capacity greater than 240 kBtu/h. |
| Baseline Rules | Not applicable |
| Minimum HGB Ratio | |
| Applicability | Packaged systems which use hot-gas bypass during low load conditions |
|---|---|
| Definition | The lower end of the hot-gas bypass operating range. The percentage of peak cooling capacity below which hot-gas bypass will no longer operate (i.e. the compressor will cycle). |
| Units | Ratio |
| Input Restrictions | As designed. The user must enter this descriptor for each DX cooling system. If hot-gas bypass is not employed, a value of 0 may be entered. |
| Baseline Rules | Not applicable |
| Condenser Type | |
| Applicability | All direct expansion systems including heat pumps |
|---|---|
| Definition | The type of condenser for a direct expansion (DX) cooling system. The choices are:
|
| Units | List (see above) |
| Input Restrictions | As designed |
| Baseline Rules | Based on the prescribed system type. Refer to the HVAC System Map in [bookref id="hvac-mapping"]. |
[table title="Baseline Building Condenser Type" id="baseline-building-condenser-type"]
| Baseline building System | Condenser Type |
| System 1 – PTAC | Air-cooled |
| System 2 – PTHP | Air-cooled |
| System 3 – PSZ-AC | Air-cooled |
| System 4 – PSZ-HP | Air-Cooled |
| System 5 – Packaged VAV with Reheat | Air-cooled |
| System 6 – Packaged VAV with PFP boxes | Air-cooled |
| System 7 – VAV with Reheat | N/A |
| System 8 – VAV with PFP boxes | N/A |
| Condenser Flow Type | |
| Applicability | All direct expansion systems including heat pumps |
|---|---|
| Definition | Describes water flow control for a water-cooled condenser. The choices are:
|
| Units | List (see above) |
| Input Restrictions | Default to fixed flow. If the variable-flow is selected, the software must indicate that supporting documentation is required on the output forms. |
| Baseline Rules | Always fixed flow |
Evaporative Cooler
This is equipment that pre-cools the outside air that is brought into the building. It may be used with any type of cooling system that brings in outside air. This equipment is not applicable for the baseline building.
| Evaporative Cooling Type | |
| Applicability | Systems with evaporative pre-cooling |
|---|---|
| Definition |
The type of evaporative pre-cooler, including:
In all cases, the evaporative pre-cooler must be modeled with 100% of the outside air routed through the pre-cooler. |
| Units | None |
| Input Restrictions | As designed |
| Baseline Rules | Not applicable |
| Direct Stage Effectiveness | |||||||||
| Applicability | Systems with evaporative pre-cooling | ||||||||
|---|---|---|---|---|---|---|---|---|---|
| Definition |
The effectiveness of the direct stage of an evaporative cooling system. Effectiveness is defined as follows: (6.7.5-18) $$ DirectE\!F\!F = \frac{T_{db} - T_{direct}}{T_{db} - T_{wb}}$$ where
|
||||||||
| Units | Numeric | ||||||||
| Input Restrictions | As designed | ||||||||
| Baseline Rules | Not applicable | ||||||||
| Indirect Stage Effectiveness | |||||||||
| Applicability | Systems with evaporative pre-cooling | ||||||||
|---|---|---|---|---|---|---|---|---|---|
| Definition |
The effectiveness of the indirect stage of an evaporative cooling system. Effectiveness is defined as follows: (6.7.5-19) $$ IndE\!F\!F = \frac {T_{db} - T_{ind}}{T_{db} - T_{wb}}$$ where
|
||||||||
| Units | Numeric | ||||||||
| Input Restrictions | As designed | ||||||||
| Baseline Rules | Not applicable | ||||||||
| Evaporative Cooling Performance Curves | |||||||||||||||||||||
| Applicability | Systems with evaporative cooling | ||||||||||||||||||||
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
| Definition |
A curve that varies the evaporative cooling effectiveness as a function of primary air stream airflow. The default curves are given as follows: (6.7.5-20) $$ P\!LR = \frac {C\!F\!M_{operating}}{C\!F\!M_{design}}$$ $$ E\!F\!F\_F\!F\!LOW = a+ b \times P\!LR + c \times P\!LR^2 $$ where
[table title="Part Load Curve Coefficients – Evaporative Cooler Effectiveness" id="part-load-curve-coefficients-–-evaporative-cooler-effectiveness"]
|
||||||||||||||||||||
| Units | Data structure | ||||||||||||||||||||
| Input Restrictions | User may input curves or use default curves. If defaults are overridden, the software must indicate that supporting documentation is required on the output forms. | ||||||||||||||||||||
| Baseline Rules | Not used. | ||||||||||||||||||||
| Auxiliary Evaporative Cooling Power | |
| Applicability | Systems with evaporative cooling |
|---|---|
| Definition | The auxiliary energy of the indirect evaporative cooler fan, and the pumps for both direct and indirect stages |
| Units | kW/cfm |
| Input Restrictions | As designed |
| Baseline Rules | Not applicable |
| Evaporative Cooling Scavenger Air Source | |
| Applicability | Systems with evaporative cooling |
|---|---|
| Definition | The source of scavenger air for an indirect section of an evaporative cooler. Options include:
|
| Units | List (see above) |
| Input Restrictions | As designed |
| Baseline Rules | Not applicable |
Evaporative Condenser
| Evaporative Condenser Power | |
| Applicability | Direct expansion systems with an evaporatively cooled condenser |
|---|---|
| Definition | The power of the evaporative precooling unit. This includes any pump(s) and/or fans that are part of the precooling unit. |
| Units | Kilowatts (kW) |
| Input Restrictions | As designed |
| Baseline Rules | Not applicable |
| Evaporative Condenser Effectiveness | |||||||||
| Applicability | Direct expansion systems with an evaporatively cooled condenser | ||||||||
|---|---|---|---|---|---|---|---|---|---|
| Definition | The effectiveness of the evaporative precooling unit for a condenser. Effectiveness is defined as follows:
(6.7.5-21) $$ DirectE\!F\!F = \frac {T_{db} - T_{direct}}{T_{db} - T_{wb}}$$ where
|
||||||||
| Units | Ratio | ||||||||
| Input Restrictions | As designed | ||||||||
| Baseline Rules | Not applicable | ||||||||
| Evaporative Condenser Operation Range | |
| Applicability | Direct expansion systems with an evaporatively cooled condenser. |
|---|---|
| Definition |
The temperature range within which the evaporative condenser operates. Two values are provided: Tmaximum The threshold outside air dry-bulb temperature below which evaporative condenser operates. Tminimum The threshold outside air dry-bulb temperature above which evaporative condenser operates. |
| Units | Degrees Fahrenheit (°F) |
| Input Restrictions | As designed |
| Baseline Rules | Not applicable |
- 1The EIR is the ratio of energy used by the system to cooling capacity in the same units. It is the reciprocal of the coefficient of performance (COP).
General
This group of building descriptors applies to all cooling systems.
| Cooling Source | |
| Applicability | All systems |
|---|---|
| Definition | The source of cooling for the system. The choices are:
|
| Units | List (see above) |
| Input Restrictions | As designed |
| Baseline Rules | The baseline building cooling source is shown in Table 6.7.5-1. See Figure 6.1.2-1 for HVAC system mapping. |
Table 6.7.5-1: Cooling Source for Baseline Building System
| Baseline building System | Cooling Source |
| System 1 – PTAC | Direct expansion (DX) |
| System 2 – PTHP | Direct expansion (DX) |
| System 3 – PSZ-AC | Direct expansion (DX) |
| System 4 – PSZ-HP | Direct expansion (DX) |
| System 5 – Packaged VAV with Reheat | Direct expansion (DX) |
| System 6 – Packaged VAV with PFP boxes | Direct expansion (DX) |
| System 7 – VAV with Reheat | Chilled water |
| System 8 – VAV with PFP boxes | Chilled water |
| System 9 – Heating and Ventilation | No cooling |
| System 10 – Heating and Ventilation | No cooling |
| Total Cooling Capacity | |||||||
| Applicability | All cooling systems | ||||||
|---|---|---|---|---|---|---|---|
| Definition | The total cooling capacity (both sensible and latent) of a cooling coil or packaged DX system at ARI conditions. The building descriptors defined in this chapter assume that the fan is modeled separately, including any heat it adds to the air stream. The cooling capacity specified by this building descriptor should not consider the heat of the fan. | ||||||
| Units | kBtu/h | ||||||
| Input Restrictions |
As designed. For packaged equipment that has the fan motor in the air stream such that it adds heat to the cooled air, the software shall adjust the total cooling capacity as follows: (6.7.5-1) $ Q_{t,adj} = Q_{t,rated} + B\!H\!P_{supply} \times 2.545 $
If the number of unmet load hours in the proposed design exceeds 300, the software shall warn the user to resize the equipment. |
||||||
| Baseline Rules | The total cooling capacity of the baseline building is oversized by 15%. However, the cooling equipment may need to be subsequently downsized such that the difference in unmet load hours between the proposed design and the baseline building is less than 50 (see Chapter 2). Sizing calculations shall be based on 1% dry-bulb and 1% wet-bulb design conditions. | ||||||
| Sensible Cooling Capacity | |||||||
| Applicability | All cooling systems | ||||||
|---|---|---|---|---|---|---|---|
| Definition | The sensible heat cooling capacity of the coil or packaged equipment at ARI conditions. The building descriptors defined in this chapter assume that the fan is modeled separately, including any heat it adds to the air stream. The cooling capacity specified by this building descriptor should not consider the heat of the fan. | ||||||
| Units | kBtu/h | ||||||
| Input Restrictions |
As designed. For packaged equipment that has the fan motor located in the air stream such that it adds heat to the cooled air, the software shall adjust the sensible cooling capacity as follows: (6.7.5-2) $ Q_{s,adj} = Q_{s,rated} + B\!H\!P_{supply} \times 2.545 $
If the number of unmet load hours in the proposed design exceeds 300, the software shall warn the user to resize the equipment. |
||||||
| Baseline Rules | The sensible cooling capacity of the baseline building is oversized by 15%. However, the cooling equipment may need to be subsequently downsized such that the difference in unmet load hours between the proposed design and the baseline building is less than 50 (see Chapter 2). Sizing calculations shall be based on 1% dry-bulb and 1% wet-bulb design conditions. | ||||||
| Cooling Capacity Adjustment Curves | |||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
| Applicability | All cooling systems | ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
| Definition |
A curve that represents the available total cooling capacity as a function of cooling coil and/or condenser conditions. The common form of these curves is given as follows: (6.7.5-3) $ Q_{t,available} = C\!A\!P\!\_FT \times Q_{t,adj} $ (6.7.5-4) $$ C\!AP\!\_FT = a + b \times t_{wb} + c \times \left. t_{wb} \right. ^2 + d \times t_{odb} + e \times \left. t_{odb} \right. ^2 + f \times t_{wb} \times t_{odb}$$ For water cooled direct expansion (6.7.5-5) $$ C\!AP\!\_FT = a + b \times t_{wb} + c \times \left. t_{wb} \right. ^2 + d \times t_{wt} + e \times \left. t_{wt} \right. ^2 + f \times t_{wb} \times t_{wt}$$ For chilled water coils (6.7.5-6) $$ C\!AP\!\_FT = a + b \times t_{wb} + c \times \left. t_{wb} \right. ^2 + d \times t_{db} + e \times \left. t_{db} \right. ^2 + f \times t_{wb} \times t_{db}$$ where
Note: if an air-cooled unit employs an evaporative condenser, todb is the effective dry-bulb temperature of the air leaving the evaporative cooling unit.
|
||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
| Units | Data structure | ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
| Input Restrictions | As designed. The equations and coefficients given above are the default. | ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
| Baseline Rules | Use the default curves or equivalent data for other models. | ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
| Coil Bypass Factor | |||||||||||
| Applicability | All cooling systems | ||||||||||
|---|---|---|---|---|---|---|---|---|---|---|---|
| Definition | The ratio of air that bypasses the cooling coil at design conditions to the total system airflow. | ||||||||||
| Units | Ratio | ||||||||||
| Input Restrictions |
As designed. Default values are given in Table 6.7.4-3.
|
||||||||||
| Baseline Rules | Defaults | ||||||||||
| Coil Bypass Factor Adjustment Curve | |||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
| Applicability | All cooling systems | ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
| Definition | Adjustments for the amount of coil bypass due to the following factors:
|
||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
| Units | Data structure | ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
| Input Restrictions |
Default to the simulation engine defaults based on HVAC system type. The following default values shall be used for the adjustment curves: (6.7.5-7) $$ C\!B\!F_{adj} = C\!B\!F_{rated} \times COI\!L - B\!F - F\!F\!LOW \times COI\!L - B\!F - FT \times COI\!L - B\!F - F\!P\!L\!R$$ (6.7.5-8) $$ CO\!I\!L - B\!F - F\!F\!LOW = a +b \times C\!F\!M\!R + c \times C\!F\!M\!R^2 +d \times C\!F\!M\!R^3 $$ (6.7.5-9) $$ COI\!L - B\!F - FT = a +b \times T_{wb} + c \times \left. T_{wb} \right. ^2 +d \times T_{db} +e \times \left. T_{db} \right. ^2 +f \times T_{wb} \times T_{db} $$ (6.7.5-10) $$ CO\!I\!L - B\!F - F\!P\!LR = a +b \times P\!LR$$ where
And the coefficients are listed in the tables below.
Table 6.7.4-4: Coil Bypass Factor Airflow Adjustment Factor
Table 6.7.4-5: Coil Bypass Factor Temperature Adjustment Factor
Table 6.7.4-6: Coil Bypass Factor Part Load Adjustment Factor
|
||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
| Baseline Rules | Use defaults as described above. | ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
Direct Expansion
| Direct Expansion Cooling Efficiency | |||||||||
| Applicability | Packaged equipment | ||||||||
|---|---|---|---|---|---|---|---|---|---|
| Definition |
The cooling efficiency of a direct expansion (DX) cooling system at ARI rated conditions as a ratio of output over input in Btu/h per W, excluding fan energy. The software must accommodate user input in terms of either the Energy Efficiency Ratio (EER) or the Seasonal Energy Efficiency Ratio (SEER). For equipment with SEER ratings, EER shall be taken from manufacturers’ data when it is available. When it is not available it shall be calculated as follows: (6.7.5-11) $ EER = 10 - \left ( 11.5 - SEER \right ) \times 0.83\ when\ SEER \textless\!=11.5 \\ = 10 \ when\ SEER\ \textgreater\!=11.5$ For all unitary and applied equipment where the fan energy is part of the equipment efficiency rating, the EER shall be adjusted as follows: (6.7.5-12) $$ E\!E\!R_{adj} = \frac{Q_{t,rated} + B\!H\!P_{supply} \times 2.545}{\frac{Q_{t,rated}}{E\!E\!R} - B\!H\!P_{supply} \times 0.7457}$$ where
|
||||||||
| Units | Btu/h-W | ||||||||
| Input Restrictions | As designed. When possible, specify the SEER and EER for packaged equipment with cooling capacity less than 65,000 Btu/h. For equipment with capacity above 65,000 Btu/h, specify EER. | ||||||||
| Baseline Rules | For the purpose of green building ratings, look up the requirement from Tables 6.8.1A - 6.8.1K in ASHRAE Standard 90.1-2010. Use the total cooling capacity of the proposed design to determine the size category. | ||||||||
| Direct Expansion Cooling Efficiency Adjustment Curve | |||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
| Applicability | Packaged DX equipment | ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
| Definition |
A curve or group of curves that varies the cooling efficiency of a direct expansion (DX) coil as a function of evaporator conditions, condenser conditions and part-load ratio. The default curves are given as follows as adjustments to the energy input ratio (EIR)1 : (6.7.5-13) $$ P\!LR = \frac{Q_{operating}}{Q_{available}\left ( t_{wb},t_{odb/wt}\right )}$$ (6.7.5-14) $$ E\!I\!R\_F\!P\!LR = a + b \times P\!LR + c \times P\!LR^2 + d \times P\!LR^3$$ (6.7.5-15) For air-cooled DX systems: (6.7.5-16) For water-cooled DX systems: (6.7.5-17) $$ P_{operating} = P_{rated} \times E\!I\!R\_F\!P\!LR \times E\!I\!R\_FT \times C\!A\!P\_FT$$ where
Note: if an air-cooled unit employs an evaporative condenser, todb is the effective dry-bulb temperature of the air leaving the evaporative cooling unit.
Table 6.7.4-7: Cooling System Coefficients for EIR-FPLR
Table 6.7.4-8: Cooling System Coefficients for EIR-FT
|
||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
| Units | Data structure | ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
| Input Restrictions | User may input curves or use default curves. If defaults are overridden, the software must indicate that supporting documentation is required on the output forms. | ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
| Baseline Rules | Use default curves. | ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
| Minimum Unloading Ratio | |
| Applicability | Packaged systems which use hot-gas bypass during low load conditions |
|---|---|
| Definition | The upper end of the hot-gas bypass operating range. This is the percentage of peak cooling capacity below which hot-gas bypass will operate. |
| Units | Ratio |
| Input Restrictions | As designed. The user must enter this descriptor for each DX cooling system. If hot-gas bypass is not employed, a value of 0 may be entered. A maximum of 0.5 is allowed for units with a peak cooling capacity of 240 kBtu/h (20 tons) or less, and a maximum value of 0.25 is allowed for units with a peak cooling capacity greater than 240 kBtu/h. |
| Baseline Rules | Not applicable |
| Minimum HGB Ratio | |
| Applicability | Packaged systems which use hot-gas bypass during low load conditions |
|---|---|
| Definition | The lower end of the hot-gas bypass operating range. The percentage of peak cooling capacity below which hot-gas bypass will no longer operate (i.e. the compressor will cycle). |
| Units | Ratio |
| Input Restrictions | As designed. The user must enter this descriptor for each DX cooling system. If hot-gas bypass is not employed, a value of 0 may be entered. |
| Baseline Rules | Not applicable |
| Condenser Type | |
| Applicability | All direct expansion systems including heat pumps |
|---|---|
| Definition | The type of condenser for a direct expansion (DX) cooling system. The choices are:
|
| Units | List (see above) |
| Input Restrictions | As designed |
| Baseline Rules | Based on the prescribed system type. Refer to the HVAC System Map in Figure 6.1.2-1. |
Table 6.7.4-9: Baseline Building Condenser Type
| Baseline building System | Condenser Type |
| System 1 – PTAC | Air-cooled |
| System 2 – PTHP | Air-cooled |
| System 3 – PSZ-AC | Air-cooled |
| System 4 – PSZ-HP | Air-Cooled |
| System 5 – Packaged VAV with Reheat | Air-cooled |
| System 6 – Packaged VAV with PFP boxes | Air-cooled |
| System 7 – VAV with Reheat | N/A |
| System 8 – VAV with PFP boxes | N/A |
| System 9 – Heating and Ventilation | No cooling |
| System 10 – Heating and Ventilation | No cooling |
| Condenser Flow Type | |
| Applicability | All direct expansion systems including heat pumps |
|---|---|
| Definition | Describes water flow control for a water-cooled condenser. The choices are:
|
| Units | List (see above) |
| Input Restrictions | Default to fixed flow. If the variable-flow is selected, the software must indicate that supporting documentation is required on the output forms. |
| Baseline Rules | Always fixed flow |
Evaporative Cooler
This is equipment that pre-cools the outside air that is brought into the building. It may be used with any type of cooling system that brings in outside air. This equipment is not applicable for the baseline building.
| Evaporative Cooling Type | |
| Applicability | Systems with evaporative pre-cooling |
|---|---|
| Definition |
The type of evaporative pre-cooler, including:
In all cases, the evaporative pre-cooler must be modeled with 100% of the outside air routed through the pre-cooler. |
| Units | None |
| Input Restrictions | As designed |
| Baseline Rules | Not applicable |
| Direct Stage Effectiveness | |||||||||
| Applicability | Systems with evaporative pre-cooling | ||||||||
|---|---|---|---|---|---|---|---|---|---|
| Definition |
The effectiveness of the direct stage of an evaporative cooling system. Effectiveness is defined as follows: (6.7.5-18) $$ DirectE\!F\!F = \frac{T_{db} - T_{direct}}{T_{db} - T_{wb}}$$ where
|
||||||||
| Units | Numeric | ||||||||
| Input Restrictions | As designed | ||||||||
| Baseline Rules | Not applicable | ||||||||
| Indirect Stage Effectiveness | |||||||||
| Applicability | Systems with evaporative pre-cooling | ||||||||
|---|---|---|---|---|---|---|---|---|---|
| Definition |
The effectiveness of the indirect stage of an evaporative cooling system. Effectiveness is defined as follows: (6.7.5-19) $$ IndE\!F\!F = \frac {T_{db} - T_{ind}}{T_{db} - T_{wb}}$$ where
|
||||||||
| Units | Numeric | ||||||||
| Input Restrictions | As designed | ||||||||
| Baseline Rules | Not applicable | ||||||||
| Evaporative Cooling Performance Curves | |||||||||||||||||||||
| Applicability | Systems with evaporative cooling | ||||||||||||||||||||
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
| Definition |
A curve that varies the evaporative cooling effectiveness as a function of primary air stream airflow. The default curves are given as follows: (6.7.5-20) $$ P\!LR = \frac {C\!F\!M_{operating}}{C\!F\!M_{design}}$$ $$ E\!F\!F\_F\!F\!LOW = a+ b \times P\!LR + c \times P\!LR^2 $$ where
Table 6.7.4-10: Part Load Curve Coefficients – Evaporative Cooler Effectiveness
|
||||||||||||||||||||
| Units | Data structure | ||||||||||||||||||||
| Input Restrictions | User may input curves or use default curves. If defaults are overridden, the software must indicate that supporting documentation is required on the output forms. | ||||||||||||||||||||
| Baseline Rules | Not used. | ||||||||||||||||||||
| Auxiliary Evaporative Cooling Power | |
| Applicability | Systems with evaporative cooling |
|---|---|
| Definition | The auxiliary energy of the indirect evaporative cooler fan, and the pumps for both direct and indirect stages |
| Units | kW/cfm |
| Input Restrictions | As designed |
| Baseline Rules | Not applicable |
| Evaporative Cooling Scavenger Air Source | |
| Applicability | Systems with evaporative cooling |
|---|---|
| Definition | The source of scavenger air for an indirect section of an evaporative cooler. Options include:
|
| Units | List (see above) |
| Input Restrictions | As designed |
| Baseline Rules | Not applicable |
Evaporative Condenser
| Evaporative Condenser Power | |
| Applicability | Direct expansion systems with an evaporatively cooled condenser |
|---|---|
| Definition | The power of the evaporative precooling unit. This includes any pump(s) and/or fans that are part of the precooling unit. |
| Units | Kilowatts (kW) |
| Input Restrictions | As designed |
| Baseline Rules | Not applicable |
| Evaporative Condenser Effectiveness | |||||||||
| Applicability | Direct expansion systems with an evaporatively cooled condenser | ||||||||
|---|---|---|---|---|---|---|---|---|---|
| Definition | The effectiveness of the evaporative precooling unit for a condenser. Effectiveness is defined as follows:
(6.7.5-21) $$ DirectE\!F\!F = \frac {T_{db} - T_{direct}}{T_{db} - T_{wb}}$$ where
|
||||||||
| Units | Ratio | ||||||||
| Input Restrictions | As designed | ||||||||
| Baseline Rules | Not applicable | ||||||||
| Evaporative Condenser Operation Range | |
| Applicability | Direct expansion systems with an evaporatively cooled condenser. |
|---|---|
| Definition |
The temperature range within which the evaporative condenser operates. Two values are provided: Tmaximum The threshold outside air dry-bulb temperature below which evaporative condenser operates. Tminimum The threshold outside air dry-bulb temperature above which evaporative condenser operates. |
| Units | Degrees Fahrenheit (°F) |
| Input Restrictions | As designed |
| Baseline Rules | Not applicable |
- 1The EIR is the ratio of energy used by the system to cooling capacity in the same units. It is the reciprocal of the coefficient of performance (COP).
General
This group of building descriptors applies to all cooling systems.
| Cooling Source | |
| Applicability | All systems |
|---|---|
| Definition | The source of cooling for the system. The choices are:
|
| Units | List (see above) |
| Input Restrictions | As designed |
| Total Cooling Capacity | |||||||
| Applicability | All cooling systems | ||||||
|---|---|---|---|---|---|---|---|
| Definition | The total cooling capacity (both sensible and latent) of a cooling coil or packaged DX system at ARI conditions. The building descriptors defined in this chapter assume that the fan is modeled separately, including any heat it adds to the air stream. The cooling capacity specified by this building descriptor should not consider the heat of the fan. | ||||||
| Units | kBtu/h | ||||||
| Input Restrictions |
As designed. For packaged equipment that has the fan motor in the air stream such that it adds heat to the cooled air, the software shall adjust the total cooling capacity as follows: (6.7.5-1) $ Q_{t,adj} = Q_{t,rated} + B\!H\!P_{supply} \times 2.545 $
If the number of unmet load hours in the proposed design exceeds 300, the software shall warn the user to resize the equipment. |
||||||
| Sensible Cooling Capacity | |||||||
| Applicability | All cooling systems | ||||||
|---|---|---|---|---|---|---|---|
| Definition | The sensible heat cooling capacity of the coil or packaged equipment at ARI conditions. The building descriptors defined in this chapter assume that the fan is modeled separately, including any heat it adds to the air stream. The cooling capacity specified by this building descriptor should not consider the heat of the fan. | ||||||
| Units | kBtu/h | ||||||
| Input Restrictions |
As designed. For packaged equipment that has the fan motor located in the air stream such that it adds heat to the cooled air, the software shall adjust the sensible cooling capacity as follows: (6.7.5-2) $ Q_{s,adj} = Q_{s,rated} + B\!H\!P_{supply} \times 2.545 $
If the number of unmet load hours in the proposed design exceeds 300, the software shall warn the user to resize the equipment. |
||||||
| Cooling Capacity Adjustment Curves | |||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
| Applicability | All cooling systems | ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
| Definition |
A curve that represents the available total cooling capacity as a function of cooling coil and/or condenser conditions. The common form of these curves is given as follows: (6.7.5-3) $ Q_{t,available} = C\!A\!P\!\_FT \times Q_{t,adj} $ (6.7.5-4) $$ C\!AP\!\_FT = a + b \times t_{wb} + c \times \left. t_{wb} \right. ^2 + d \times t_{odb} + e \times \left. t_{odb} \right. ^2 + f \times t_{wb} \times t_{odb}$$ For water cooled direct expansion (6.7.5-5) $$ C\!AP\!\_FT = a + b \times t_{wb} + c \times \left. t_{wb} \right. ^2 + d \times t_{wt} + e \times \left. t_{wt} \right. ^2 + f \times t_{wb} \times t_{wt}$$ For chilled water coils (6.7.5-6) $$ C\!AP\!\_FT = a + b \times t_{wb} + c \times \left. t_{wb} \right. ^2 + d \times t_{db} + e \times \left. t_{db} \right. ^2 + f \times t_{wb} \times t_{db}$$ where
Note: if an air-cooled unit employs an evaporative condenser, todb is the effective dry-bulb temperature of the air leaving the evaporative cooling unit.
|
||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
| Units | Data structure | ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
| Input Restrictions | As designed. The equations and coefficients given above are the default. | ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
| Coil Bypass Factor | |||||||||||
| Applicability | All cooling systems | ||||||||||
|---|---|---|---|---|---|---|---|---|---|---|---|
| Definition | The ratio of air that bypasses the cooling coil at design conditions to the total system airflow. | ||||||||||
| Units | Ratio | ||||||||||
| Input Restrictions |
As designed. Default values are given in [bookref id="default-coil-bypass-factors"].
|
||||||||||
| Coil Bypass Factor Adjustment Curve | |||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
| Applicability | All cooling systems | ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
| Definition | Adjustments for the amount of coil bypass due to the following factors:
|
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| Units | Data structure | ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
| Input Restrictions |
Default to the simulation engine defaults based on HVAC system type. The following default values shall be used for the adjustment curves: (6.7.5-7) $$ C\!B\!F_{adj} = C\!B\!F_{rated} \times COI\!L - B\!F - F\!F\!LOW \times COI\!L - B\!F - FT \times COI\!L - B\!F - F\!P\!L\!R$$ (6.7.5-8) $$ CO\!I\!L - B\!F - F\!F\!LOW = a +b \times C\!F\!M\!R + c \times C\!F\!M\!R^2 +d \times C\!F\!M\!R^3 $$ (6.7.5-9) $$ COI\!L - B\!F - FT = a +b \times T_{wb} + c \times \left. T_{wb} \right. ^2 +d \times T_{db} +e \times \left. T_{db} \right. ^2 +f \times T_{wb} \times T_{db} $$ (6.7.5-10) $$ CO\!I\!L - B\!F - F\!P\!LR = a +b \times P\!LR$$ where
And the coefficients are listed in the tables below. [table title="Coil Bypass Factor Airflow Adjustment Factor" id="coil-bypass-factor-airflow-adjustment-factor"]
[table title="Coil Bypass Factor Temperature Adjustment Factor" id="coil-bypass-factor-temperature-adjustment-factor"]
[table title="Coil Bypass Factor Part Load Adjustment Factor" id="coil-bypass-factor-part-load-adjustment-actor"]
|
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Direct Expansion
| Direct Expansion Cooling Efficiency | |||||||||
| Applicability | Packaged equipment | ||||||||
|---|---|---|---|---|---|---|---|---|---|
| Definition |
The cooling efficiency of a direct expansion (DX) cooling system at ARI rated conditions as a ratio of output over input in Btu/h per W, excluding fan energy. The software must accommodate user input in terms of either the Energy Efficiency Ratio (EER) or the Seasonal Energy Efficiency Ratio (SEER). For equipment with SEER ratings, EER shall be taken from manufacturers’ data when it is available. When it is not available it shall be calculated as follows: (6.7.5-11) $ EER = 10 - \left ( 11.5 - SEER \right ) \times 0.83\ when\ SEER \textless\!=11.5 \\ = 10 \ when\ SEER\ \textgreater\!=11.5$ For all unitary and applied equipment where the fan energy is part of the equipment efficiency rating, the EER shall be adjusted as follows: (6.7.5-12) $$ E\!E\!R_{adj} = \frac{Q_{t,rated} + B\!H\!P_{supply} \times 2.545}{\frac{Q_{t,rated}}{E\!E\!R} - B\!H\!P_{supply} \times 0.7457}$$ where
|
||||||||
| Units | Btu/h-W | ||||||||
| Input Restrictions | As designed. When possible, specify the SEER and EER for packaged equipment with cooling capacity less than 65,000 Btu/h. For equipment with capacity above 65,000 Btu/h, specify EER. | ||||||||
| Direct Expansion Cooling Efficiency Adjustment Curve | |||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
| Applicability | Packaged DX equipment | ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
| Definition |
A curve or group of curves that varies the cooling efficiency of a direct expansion (DX) coil as a function of evaporator conditions, condenser conditions and part-load ratio. The default curves are given as follows as adjustments to the energy input ratio (EIR)1 : (6.7.5-13) $$ P\!LR = \frac{Q_{operating}}{Q_{available}\left ( t_{wb},t_{odb/wt}\right )}$$ (6.7.5-14) $$ E\!I\!R\_F\!P\!LR = a + b \times P\!LR + c \times P\!LR^2 + d \times P\!LR^3$$ (6.7.5-15) For air-cooled DX systems: (6.7.5-16) For water-cooled DX systems: (6.7.5-17) $$ P_{operating} = P_{rated} \times E\!I\!R\_F\!P\!LR \times E\!I\!R\_FT \times C\!A\!P\_FT$$ where
Note: if an air-cooled unit employs an evaporative condenser, todb is the effective dry-bulb temperature of the air leaving the evaporative cooling unit. [table title="Cooling System Coefficients for EIR-FPLR" id="cooling-system-coefficients-for-EIR-FPLR"]
[table title="Cooling System Coefficients for EIR-FT" id="Cooling System Coefficients for EIR-FT"]
|
||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
| Units | Data structure | ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
| Input Restrictions | User may input curves or use default curves. If defaults are overridden, the software must indicate that supporting documentation is required on the output forms. | ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
| Minimum Unloading Ratio | |
| Applicability | Packaged systems which use hot-gas bypass during low load conditions |
|---|---|
| Definition | The upper end of the hot-gas bypass operating range. This is the percentage of peak cooling capacity below which hot-gas bypass will operate. |
| Units | Ratio |
| Input Restrictions | As designed. The user must enter this descriptor for each DX cooling system. If hot-gas bypass is not employed, a value of 0 may be entered. A maximum of 0.5 is allowed for units with a peak cooling capacity of 240 kBtu/h (20 tons) or less, and a maximum value of 0.25 is allowed for units with a peak cooling capacity greater than 240 kBtu/h. |
| Minimum HGB Ratio | |
| Applicability | Packaged systems which use hot-gas bypass during low load conditions |
|---|---|
| Definition | The lower end of the hot-gas bypass operating range. The percentage of peak cooling capacity below which hot-gas bypass will no longer operate (i.e. the compressor will cycle). |
| Units | Ratio |
| Input Restrictions | As designed. The user must enter this descriptor for each DX cooling system. If hot-gas bypass is not employed, a value of 0 may be entered. |
| Condenser Type | |
| Applicability | All direct expansion systems including heat pumps |
|---|---|
| Definition | The type of condenser for a direct expansion (DX) cooling system. The choices are:
|
| Units | List (see above) |
| Input Restrictions | As designed |
| Condenser Flow Type | |
| Applicability | All direct expansion systems including heat pumps |
|---|---|
| Definition | Describes water flow control for a water-cooled condenser. The choices are:
|
| Units | List (see above) |
| Input Restrictions | Default to fixed flow. If the variable-flow is selected, the software must indicate that supporting documentation is required on the output forms. |
Evaporative Cooler
This is equipment that pre-cools the outside air that is brought into the building. It may be used with any type of cooling system that brings in outside air. This equipment is not applicable for the baseline building.
| Evaporative Cooling Type | |
| Applicability | Systems with evaporative pre-cooling |
|---|---|
| Definition |
The type of evaporative pre-cooler, including:
In all cases, the evaporative pre-cooler must be modeled with 100% of the outside air routed through the pre-cooler. |
| Units | None |
| Input Restrictions | As designed |
| Direct Stage Effectiveness | |||||||||
| Applicability | Systems with evaporative pre-cooling | ||||||||
|---|---|---|---|---|---|---|---|---|---|
| Definition |
The effectiveness of the direct stage of an evaporative cooling system. Effectiveness is defined as follows: (6.7.5-18) $$ DirectE\!F\!F = \frac{T_{db} - T_{direct}}{T_{db} - T_{wb}}$$ where
|
||||||||
| Units | Numeric | ||||||||
| Input Restrictions | As designed | ||||||||
| Indirect Stage Effectiveness | |||||||||
| Applicability | Systems with evaporative pre-cooling | ||||||||
|---|---|---|---|---|---|---|---|---|---|
| Definition |
The effectiveness of the indirect stage of an evaporative cooling system. Effectiveness is defined as follows: (6.7.5-19) $$ IndE\!F\!F = \frac {T_{db} - T_{ind}}{T_{db} - T_{wb}}$$ where
|
||||||||
| Units | Numeric | ||||||||
| Input Restrictions | As designed | ||||||||
| Evaporative Cooling Performance Curves | |||||||||||||||||||||
| Applicability | Systems with evaporative cooling | ||||||||||||||||||||
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
| Definition |
A curve that varies the evaporative cooling effectiveness as a function of primary air stream airflow. The default curves are given as follows: (6.7.5-20) $$ P\!LR = \frac {C\!F\!M_{operating}}{C\!F\!M_{design}}$$ $$ E\!F\!F\_F\!F\!LOW = a+ b \times P\!LR + c \times P\!LR^2 $$ where
[table title="Part Load Curve Coefficients – Evaporative Cooler Effectiveness" id="part-load-curve-coefficients-–-evaporative-cooler-effectiveness"]
|
||||||||||||||||||||
| Units | Data structure | ||||||||||||||||||||
| Input Restrictions | User may input curves or use default curves. If defaults are overridden, the software must indicate that supporting documentation is required on the output forms. | ||||||||||||||||||||
| Auxiliary Evaporative Cooling Power | |
| Applicability | Systems with evaporative cooling |
|---|---|
| Definition | The auxiliary energy of the indirect evaporative cooler fan, and the pumps for both direct and indirect stages |
| Units | kW/cfm |
| Input Restrictions | As designed |
| Evaporative Cooling Scavenger Air Source | |
| Applicability | Systems with evaporative cooling |
|---|---|
| Definition | The source of scavenger air for an indirect section of an evaporative cooler. Options include:
|
| Units | List (see above) |
| Input Restrictions | As designed |
Evaporative Condenser
| Evaporative Condenser Power | |
| Applicability | Direct expansion systems with an evaporatively cooled condenser |
|---|---|
| Definition | The power of the evaporative precooling unit. This includes any pump(s) and/or fans that are part of the precooling unit. |
| Units | Kilowatts (kW) |
| Input Restrictions | As designed |
| Evaporative Condenser Effectiveness | |||||||||
| Applicability | Direct expansion systems with an evaporatively cooled condenser | ||||||||
|---|---|---|---|---|---|---|---|---|---|
| Definition | The effectiveness of the evaporative precooling unit for a condenser. Effectiveness is defined as follows:
(6.7.5-21) $$ DirectE\!F\!F = \frac {T_{db} - T_{direct}}{T_{db} - T_{wb}}$$ where
|
||||||||
| Units | Ratio | ||||||||
| Input Restrictions | As designed | ||||||||
| Evaporative Condenser Operation Range | |
| Applicability | Direct expansion systems with an evaporatively cooled condenser. |
|---|---|
| Definition |
The temperature range within which the evaporative condenser operates. Two values are provided: Tmaximum The threshold outside air dry-bulb temperature below which evaporative condenser operates. Tminimum The threshold outside air dry-bulb temperature above which evaporative condenser operates. |
| Units | Degrees Fahrenheit (°F) |
| Input Restrictions | As designed |
- 1The EIR is the ratio of energy used by the system to cooling capacity in the same units. It is the reciprocal of the coefficient of performance (COP).
General
This group of building descriptors applies to all cooling systems.
| Cooling Source | |
| Applicability | All systems |
|---|---|
| Definition | The source of cooling for the system. The choices are:
|
| Units | List (see above) |
| Input Restrictions | As designed |
| Total Cooling Capacity | |||||||
| Applicability | All cooling systems | ||||||
|---|---|---|---|---|---|---|---|
| Definition | The total cooling capacity (both sensible and latent) of a cooling coil or packaged DX system at ARI conditions. The building descriptors defined in this chapter assume that the fan is modeled separately, including any heat it adds to the air stream. The cooling capacity specified by this building descriptor should not consider the heat of the fan. | ||||||
| Units | kBtu/h | ||||||
| Input Restrictions |
As designed. For packaged equipment that has the fan motor in the air stream such that it adds heat to the cooled air, the software shall adjust the total cooling capacity as follows: (6.7.5-1) $ Q_{t,adj} = Q_{t,rated} + B\!H\!P_{supply} \times 2.545 $
If the number of unmet load hours in the proposed design exceeds 300, the software shall warn the user to resize the equipment. |
||||||
| Sensible Cooling Capacity | |||||||
| Applicability | All cooling systems | ||||||
|---|---|---|---|---|---|---|---|
| Definition | The sensible heat cooling capacity of the coil or packaged equipment at ARI conditions. The building descriptors defined in this chapter assume that the fan is modeled separately, including any heat it adds to the air stream. The cooling capacity specified by this building descriptor should not consider the heat of the fan. | ||||||
| Units | kBtu/h | ||||||
| Input Restrictions |
As designed. For packaged equipment that has the fan motor located in the air stream such that it adds heat to the cooled air, the software shall adjust the sensible cooling capacity as follows: (6.7.5-2) $ Q_{s,adj} = Q_{s,rated} + B\!H\!P_{supply} \times 2.545 $
If the number of unmet load hours in the proposed design exceeds 300, the software shall warn the user to resize the equipment. |
||||||
| Cooling Capacity Adjustment Curves | |||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
| Applicability | All cooling systems | ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
| Definition |
A curve that represents the available total cooling capacity as a function of cooling coil and/or condenser conditions. The common form of these curves is given as follows: (6.7.5-3) $ Q_{t,available} = C\!A\!P\!\_FT \times Q_{t,adj} $ (6.7.5-4) $$ C\!AP\!\_FT = a + b \times t_{wb} + c \times \left. t_{wb} \right. ^2 + d \times t_{odb} + e \times \left. t_{odb} \right. ^2 + f \times t_{wb} \times t_{odb}$$ For water cooled direct expansion (6.7.5-5) $$ C\!AP\!\_FT = a + b \times t_{wb} + c \times \left. t_{wb} \right. ^2 + d \times t_{wt} + e \times \left. t_{wt} \right. ^2 + f \times t_{wb} \times t_{wt}$$ For chilled water coils (6.7.5-6) $$ C\!AP\!\_FT = a + b \times t_{wb} + c \times \left. t_{wb} \right. ^2 + d \times t_{db} + e \times \left. t_{db} \right. ^2 + f \times t_{wb} \times t_{db}$$ where
Note: if an air-cooled unit employs an evaporative condenser, todb is the effective dry-bulb temperature of the air leaving the evaporative cooling unit.
|
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| Units | Data structure | ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
| Input Restrictions | As designed. The equations and coefficients given above are the default. | ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
| Coil Bypass Factor | |||||||||||
| Applicability | All cooling systems | ||||||||||
|---|---|---|---|---|---|---|---|---|---|---|---|
| Definition | The ratio of air that bypasses the cooling coil at design conditions to the total system airflow. | ||||||||||
| Units | Ratio | ||||||||||
| Input Restrictions |
As designed. Default values are given in [bookref id="default-coil-bypass-factors"].
|
||||||||||
| Coil Bypass Factor Adjustment Curve | |||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
| Applicability | All cooling systems | ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
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| Definition | Adjustments for the amount of coil bypass due to the following factors:
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| Units | Data structure | ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
| Input Restrictions |
Default to the simulation engine defaults based on HVAC system type. The following default values shall be used for the adjustment curves: (6.7.5-7) $$ C\!B\!F_{adj} = C\!B\!F_{rated} \times COI\!L - B\!F - F\!F\!LOW \times COI\!L - B\!F - FT \times COI\!L - B\!F - F\!P\!L\!R$$ (6.7.5-8) $$ CO\!I\!L - B\!F - F\!F\!LOW = a +b \times C\!F\!M\!R + c \times C\!F\!M\!R^2 +d \times C\!F\!M\!R^3 $$ (6.7.5-9) $$ COI\!L - B\!F - FT = a +b \times T_{wb} + c \times \left. T_{wb} \right. ^2 +d \times T_{db} +e \times \left. T_{db} \right. ^2 +f \times T_{wb} \times T_{db} $$ (6.7.5-10) $$ CO\!I\!L - B\!F - F\!P\!LR = a +b \times P\!LR$$ where
And the coefficients are listed in the tables below. [table title="Coil Bypass Factor Airflow Adjustment Factor" id="coil-bypass-factor-airflow-adjustment-factor"]
[table title="Coil Bypass Factor Temperature Adjustment Factor" id="coil-bypass-factor-temperature-adjustment-factor"]
[table title="Coil Bypass Factor Part Load Adjustment Factor" id="coil-bypass-factor-part-load-adjustment-actor"]
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Direct Expansion
| Direct Expansion Cooling Efficiency | |||||||||
| Applicability | Packaged equipment | ||||||||
|---|---|---|---|---|---|---|---|---|---|
| Definition |
The cooling efficiency of a direct expansion (DX) cooling system at ARI rated conditions as a ratio of output over input in Btu/h per W, excluding fan energy. The software must accommodate user input in terms of either the Energy Efficiency Ratio (EER) or the Seasonal Energy Efficiency Ratio (SEER). For equipment with SEER ratings, EER shall be taken from manufacturers’ data when it is available. When it is not available it shall be calculated as follows: (6.7.5-11) $ EER = 10 - \left ( 11.5 - SEER \right ) \times 0.83\ when\ SEER \textless\!=11.5 \\ = 10 \ when\ SEER\ \textgreater\!=11.5$ For all unitary and applied equipment where the fan energy is part of the equipment efficiency rating, the EER shall be adjusted as follows: (6.7.5-12) $$ E\!E\!R_{adj} = \frac{Q_{t,rated} + B\!H\!P_{supply} \times 2.545}{\frac{Q_{t,rated}}{E\!E\!R} - B\!H\!P_{supply} \times 0.7457}$$ where
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| Units | Btu/h-W | ||||||||
| Input Restrictions | As designed. When possible, specify the SEER and EER for packaged equipment with cooling capacity less than 65,000 Btu/h. For equipment with capacity above 65,000 Btu/h, specify EER. | ||||||||
| Direct Expansion Cooling Efficiency Adjustment Curve | |||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
| Applicability | Packaged DX equipment | ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
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| Definition |
A curve or group of curves that varies the cooling efficiency of a direct expansion (DX) coil as a function of evaporator conditions, condenser conditions and part-load ratio. The default curves are given as follows as adjustments to the energy input ratio (EIR)1 : (6.7.5-13) $$ P\!LR = \frac{Q_{operating}}{Q_{available}\left ( t_{wb},t_{odb/wt}\right )}$$ (6.7.5-14) $$ E\!I\!R\_F\!P\!LR = a + b \times P\!LR + c \times P\!LR^2 + d \times P\!LR^3$$ (6.7.5-15) For air-cooled DX systems: (6.7.5-16) For water-cooled DX systems: (6.7.5-17) $$ P_{operating} = P_{rated} \times E\!I\!R\_F\!P\!LR \times E\!I\!R\_FT \times C\!A\!P\_FT$$ where
Note: if an air-cooled unit employs an evaporative condenser, todb is the effective dry-bulb temperature of the air leaving the evaporative cooling unit. [table title="Cooling System Coefficients for EIR-FPLR" id="cooling-system-coefficients-for-EIR-FPLR"]
[table title="Cooling System Coefficients for EIR-FT" id="Cooling System Coefficients for EIR-FT"]
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| Units | Data structure | ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
| Input Restrictions | User may input curves or use default curves. If defaults are overridden, the software must indicate that supporting documentation is required on the output forms. | ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
| Minimum Unloading Ratio | |
| Applicability | Packaged systems which use hot-gas bypass during low load conditions |
|---|---|
| Definition | The upper end of the hot-gas bypass operating range. This is the percentage of peak cooling capacity below which hot-gas bypass will operate. |
| Units | Ratio |
| Input Restrictions | As designed. The user must enter this descriptor for each DX cooling system. If hot-gas bypass is not employed, a value of 0 may be entered. A maximum of 0.5 is allowed for units with a peak cooling capacity of 240 kBtu/h (20 tons) or less, and a maximum value of 0.25 is allowed for units with a peak cooling capacity greater than 240 kBtu/h. |
| Minimum HGB Ratio | |
| Applicability | Packaged systems which use hot-gas bypass during low load conditions |
|---|---|
| Definition | The lower end of the hot-gas bypass operating range. The percentage of peak cooling capacity below which hot-gas bypass will no longer operate (i.e. the compressor will cycle). |
| Units | Ratio |
| Input Restrictions | As designed. The user must enter this descriptor for each DX cooling system. If hot-gas bypass is not employed, a value of 0 may be entered. |
| Condenser Type | |
| Applicability | All direct expansion systems including heat pumps |
|---|---|
| Definition | The type of condenser for a direct expansion (DX) cooling system. The choices are:
|
| Units | List (see above) |
| Input Restrictions | As designed |
| Condenser Flow Type | |
| Applicability | All direct expansion systems including heat pumps |
|---|---|
| Definition | Describes water flow control for a water-cooled condenser. The choices are:
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| Units | List (see above) |
| Input Restrictions | Default to fixed flow. If the variable-flow is selected, the software must indicate that supporting documentation is required on the output forms. |
Evaporative Cooler
This is equipment that pre-cools the outside air that is brought into the building. It may be used with any type of cooling system that brings in outside air. This equipment is not applicable for the baseline building.
| Evaporative Cooling Type | |
| Applicability | Systems with evaporative pre-cooling |
|---|---|
| Definition |
The type of evaporative pre-cooler, including:
In all cases, the evaporative pre-cooler must be modeled with 100% of the outside air routed through the pre-cooler. |
| Units | None |
| Input Restrictions | As designed |
| Direct Stage Effectiveness | |||||||||
| Applicability | Systems with evaporative pre-cooling | ||||||||
|---|---|---|---|---|---|---|---|---|---|
| Definition |
The effectiveness of the direct stage of an evaporative cooling system. Effectiveness is defined as follows: (6.7.5-18) $$ DirectE\!F\!F = \frac{T_{db} - T_{direct}}{T_{db} - T_{wb}}$$ where
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| Units | Numeric | ||||||||
| Input Restrictions | As designed | ||||||||
| Indirect Stage Effectiveness | |||||||||
| Applicability | Systems with evaporative pre-cooling | ||||||||
|---|---|---|---|---|---|---|---|---|---|
| Definition |
The effectiveness of the indirect stage of an evaporative cooling system. Effectiveness is defined as follows: (6.7.5-19) $$ IndE\!F\!F = \frac {T_{db} - T_{ind}}{T_{db} - T_{wb}}$$ where
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| Units | Numeric | ||||||||
| Input Restrictions | As designed | ||||||||
| Evaporative Cooling Performance Curves | |||||||||||||||||||||
| Applicability | Systems with evaporative cooling | ||||||||||||||||||||
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
| Definition |
A curve that varies the evaporative cooling effectiveness as a function of primary air stream airflow. The default curves are given as follows: (6.7.5-20) $$ P\!LR = \frac {C\!F\!M_{operating}}{C\!F\!M_{design}}$$ $$ E\!F\!F\_F\!F\!LOW = a+ b \times P\!LR + c \times P\!LR^2 $$ where
[table title="Part Load Curve Coefficients – Evaporative Cooler Effectiveness" id="part-load-curve-coefficients-–-evaporative-cooler-effectiveness"]
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| Units | Data structure | ||||||||||||||||||||
| Input Restrictions | User may input curves or use default curves. If defaults are overridden, the software must indicate that supporting documentation is required on the output forms. | ||||||||||||||||||||
| Auxiliary Evaporative Cooling Power | |
| Applicability | Systems with evaporative cooling |
|---|---|
| Definition | The auxiliary energy of the indirect evaporative cooler fan, and the pumps for both direct and indirect stages |
| Units | kW/cfm |
| Input Restrictions | As designed |
| Evaporative Cooling Scavenger Air Source | |
| Applicability | Systems with evaporative cooling |
|---|---|
| Definition | The source of scavenger air for an indirect section of an evaporative cooler. Options include:
|
| Units | List (see above) |
| Input Restrictions | As designed |
Evaporative Condenser
| Evaporative Condenser Power | |
| Applicability | Direct expansion systems with an evaporatively cooled condenser |
|---|---|
| Definition | The power of the evaporative precooling unit. This includes any pump(s) and/or fans that are part of the precooling unit. |
| Units | Kilowatts (kW) |
| Input Restrictions | As designed |
| Evaporative Condenser Effectiveness | |||||||||
| Applicability | Direct expansion systems with an evaporatively cooled condenser | ||||||||
|---|---|---|---|---|---|---|---|---|---|
| Definition | The effectiveness of the evaporative precooling unit for a condenser. Effectiveness is defined as follows:
(6.7.5-21) $$ DirectE\!F\!F = \frac {T_{db} - T_{direct}}{T_{db} - T_{wb}}$$ where
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| Units | Ratio | ||||||||
| Input Restrictions | As designed | ||||||||
| Evaporative Condenser Operation Range | |
| Applicability | Direct expansion systems with an evaporatively cooled condenser. |
|---|---|
| Definition |
The temperature range within which the evaporative condenser operates. Two values are provided: Tmaximum The threshold outside air dry-bulb temperature below which evaporative condenser operates. Tminimum The threshold outside air dry-bulb temperature above which evaporative condenser operates. |
| Units | Degrees Fahrenheit (°F) |
| Input Restrictions | As designed |
- 1The EIR is the ratio of energy used by the system to cooling capacity in the same units. It is the reciprocal of the coefficient of performance (COP).