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Cooling Load Calculation Guide: ASHRAE Standards & Methods

Comprehensive guide to calculating cooling loads for buildings using ASHRAE Fundamentals Handbook methods, including heat gain analysis and equipment sizing

Enginist Technical Team
Professional engineers with expertise in air conditioning, refrigeration, and psychrometric analysis.
Reviewed by ASHRAE-Certified Engineers
Published: October 21, 2025
Updated: November 9, 2025
Related Calculators:Psychrometric CalculatorDuct Sizing CalculatorHeat Loss Calculator

Table of Contents

Cooling Load Calculation: Complete Engineering Guide

Quick AnswerHow do you calculate cooling load?
Sum heat gains from people (70W sensible + 45W latent per person), lighting (W/m²), equipment, solar gains, and ventilation per ASHRAE standards.
Qtotal=Qsensible+QlatentQ_{total} = Q_{sensible} + Q_{latent}
Example

100m² office with 10 people and 15 W/m² lighting needs approximately 8-10 kW cooling capacity.

Introduction

Cooling load calculation is the process of determining the total amount of heat that must be removed from a building space to maintain desired indoor temperature and humidity conditions, forming the foundation of HVAC system design. Cooling load consists of two main components: sensible heat (temperature change) and latent heat (moisture), with total cooling load equaling the sum of all heat gains from people, lighting, equipment, solar radiation, transmission through building envelope, ventilation, and infiltration.

Why This Calculation Matters

Accurate cooling load calculation is crucial for:

  • Equipment Sizing: Selecting air conditioning equipment with correct capacity to meet peak cooling demands.
  • Energy Efficiency: Avoiding oversized equipment that wastes energy through short cycling and poor humidity control.
  • Occupant Comfort: Ensuring adequate cooling capacity to maintain design temperatures and humidity levels.
  • Cost Optimization: Balancing initial equipment costs with long-term operating expenses and maintenance.

The Fundamental Challenge

The primary challenge in cooling load calculation lies in accurately accounting for all heat gain sources—both external (solar radiation, transmission, ventilation) and internal (people, lighting, equipment)—while considering their time-varying nature. Peak cooling loads often occur at specific times depending on building orientation and occupancy patterns, requiring analysis of multiple conditions to determine the design load. Additionally, distinguishing between sensible and latent loads is essential for proper equipment selection and humidity control. Oversizing equipment (using excessive safety factors) causes energy waste and poor dehumidification, while undersizing leads to comfort failures during peak conditions.

What You'll Learn

In this comprehensive guide, you will learn:

  • The core formula Qtotal=Qsensible+QlatentQ_{\text{total}} = Q_{\text{sensible}} + Q_{\text{latent}} and all contributing heat gain components.
  • How to calculate sensible heat gains from people, lighting, equipment, solar, and transmission.
  • Methods for determining latent heat gains from occupants and ventilation air.
  • Equipment sizing from cooling load including tons of refrigeration conversion.
  • Step-by-step examples to confidently apply ASHRAE Fundamentals methods in your projects per Chapter 18 and Standard 90.1 requirements.

This guide is designed for HVAC engineers, building designers, and facility managers who need to calculate cooling loads for residential, commercial, and industrial buildings. You will learn the fundamental calculation methods, how to determine sensible and latent heat gains, methods for sizing equipment and airflow requirements, performance metrics, and standards compliance per ASHRAE Fundamentals Handbook and Standard 90.1.

Quick Answer: How to Calculate Cooling Load for Buildings

Cooling load is the sum of sensible heat (temperature-related) and latent heat (humidity-related) that must be removed from a space.

Core Formula

Qtotal=Qsensible+QlatentQ_{\text{total}} = Q_{\text{sensible}} + Q_{\text{latent}}

Where:

  • QtotalQ_{\text{total}} = Total cooling load (kW or BTU/h)
  • QsensibleQ_{\text{sensible}} = Sensible heat gain (temperature-related)
  • QlatentQ_{\text{latent}} = Latent heat gain (humidity-related)

Component Formulas

ComponentFormulaDescription
Sensible HeatQsensible=People+Lighting+Equipment+Solar+Transmission+VentilationQ_{\text{sensible}} = \text{People} + \text{Lighting} + \text{Equipment} + \text{Solar} + \text{Transmission} + \text{Ventilation}Heat-related heat
Latent HeatQlatent=People moisture+Ventilation moisture+Infiltration moistureQ_{\text{latent}} = \text{People moisture} + \text{Ventilation moisture} + \text{Infiltration moisture}Humidity-related heat
Design LoadQdesign=Qtotal×SFQ_{\text{design}} = Q_{\text{total}} \times SFSafety factor (1.1-1.2)
Equipment SizingTons=Qdesign3.517 kW\text{Tons} = \frac{Q_{\text{design}}}{3.517 \text{ kW}}Convert to tons of refrigeration

Worked Example

80 m<sup>2</sup> Office: 20 People, 15 W/m<sup>2</sup> Lighting

Given:

  • Floor area: 80 m2
  • Occupants: 20 people
  • Lighting: 15 W/m2
  • Equipment: 20 W/m2

Sensible Heat Gains:

  • People: 1,400 W
  • Lighting: 1,200 W
  • Equipment: 1,600 W
  • Solar: 8,512 W
  • Transmission: 1,278 W
  • Air circulation: 1,814 W
  • Total sensible: 15,804 W

Latent Heat Gains:

  • People: 900 W
  • Air exchange: 3,913 W
  • Total latent: 4,813 W

Total Air conditioning Load:

Qtotal=15,804+4,813=20.6 kWQ_{\text{total}} = 15,804 + 4,813 = \textbf{20.6 kW}

Design Load:

Qdesign=20.6×1.2=24.7 kW (7.0 tons)Q_{\text{design}} = 20.6 \times 1.2 = \textbf{24.7 kW (7.0 tons)}

Reference Table

ParameterTypical RangeStandard
Sensible Heat (People)70 W/personASHRAE
Latent Heat (People)45 W/personASHRAE
Lighting (Office)8-25 W/m²Typical
Equipment (Office)15-100 W/m²Typical
Ventilation (Office)10 L/s per personASHRAE 62.1
Cooling Load (Office)50-150 W/m²Typical
Cooling Load (Retail)80-120 W/m²Typical
Cooling Load (Restaurant)100-150 W/m²Typical
Safety Factor1.1-1.2Typical
Tons of Refrigeration1 ton = 3.517 kWStandard

Key Standards

Refrigeration load is the total amount of heat that must be removed from a space to maintain the desired indoor thermal value and humidity. It represents the rate at which heat must be extracted, measured in Watts (W) or British Thermal Units per hour (BTU/h).

Why Cooling Load Matters

  1. Equipment Sizing: Proper load solution ensures correctly sized air supply conditioning equipment
  2. Energy Performance: Oversized equipment wastes energy; undersized equipment fails to maintain comfort
  3. Cost Optimization: Accurate sizing minimizes initial equipment costs and operating expenses
  4. Comfort: Proper load computation ensures consistent degree and humidity control
  5. Code Compliance: Building codes require load calculations for HVAC permits

ASHRAE Standards and Methods

ASHRAE Fundamentals Handbook

The primary reference for chilling load calculations provides:

  • Chapter 18: Temperature control and Heating Load Analysis Principles
  • Chapter 19: Nonresidential Air conditioning and Heating Load Calculations
  • Chapter 30: Energy Estimating and Modeling Methods

ASHRAE Standard 62.1: Ventilation for Acceptable Indoor Air Quality

Specifies minimum airflow rates for different space types:

  • Office Spaces: 10 L/s per person
  • Classrooms: 7.5 L/s per person
  • Retail: 7.5 L/s per person
  • Restaurants: 10 L/s per person

ASHRAE Standard 90.1: Energy Standard for Buildings

Establishes minimum energy effectiveness requirements:

  • Building Envelope: Maximum U-values for walls, roofs, windows
  • Equipment Productivity: Minimum EER and COP ratings
  • Load Determination: Requires detailed load calculations for compliance

Heat Gain Components

AC load consists of two main components: sensible heat and latent heat.

Sensible Heat Gain

Sensible heat causes a heat level change without phase change (no moisture involved). Components include:

  1. People Heat Gain
  2. Lighting Heat Gain
  3. Equipment Heat Gain
  4. Solar Heat Gain
  5. Transmission Heat Gain (through building envelope)
  6. Airflow movement Heat Gain
  7. Infiltration Heat Gain

Latent Heat Gain

Latent heat is associated with moisture (humidity) and phase changes. Components include:

  1. People Latent Heat (respiration, perspiration)
  2. Atmosphere supply Latent Heat
  3. Infiltration Latent Heat

Heat Gain Calculation Methods

1. People Heat Gain

Heat gain from occupants depends on activity level:

Sensible Heat:

Qsensible=N×qsensibleQ_{\text{sensible}} = N \times q_{\text{sensible}}

Latent Heat:

Qlatent=N×qlatentQ_{\text{latent}} = N \times q_{\text{latent}}

Where:

  • NN = Number of people
  • qsensibleq_{\text{sensible}} = Sensible heat gain per person (W/person)
  • qlatentq_{\text{latent}} = Latent heat gain per person (W/person)

ASHRAE Values (Office work, sedentary):

  • Sensible: 70 W/person
  • Latent: 45 W/person
  • Total: 115 W/person

2. Lighting Heat Gain

Heat gain from lighting fixtures:

Q=P×AQ = P \times A

Where:

  • PlightingP_{\text{lighting}} = Lighting power density (W/m2)
  • AfloorA_{\text{floor}} = Floor area (m2)

Typical Values:

  • Fluorescent: 15 W/m2
  • LED: 8 W/m2
  • Incandescent: 25 W/m2
  • High-bay: 30 W/m2

3. Equipment Heat Gain

Heat gain from electrical equipment:

Q=P×AQ = P \times A

Where:

  • PequipmentP_{\text{equipment}} = Equipment power density (W/m2)
  • AfloorA_{\text{floor}} = Floor area (m2)

Typical Values:

  • Office: 20 W/m2
  • Server room: 100 W/m2
  • Kitchen: 50 W/m2
  • Retail: 15 W/m2

4. Solar Heat Gain

Heat gain through windows from solar radiation:

Q=A×I×SHGC×SCQ = A \times I \times SHGC \times SC

Where:

  • AA = Window area (m2)
  • II = Solar radiation intensity (W/m2)
  • SHGCSHGC = Solar Heat Gain Coefficient (0-1)
  • SCSC = Shading coefficient (0-1)

SHGC Values (ASHRAE):

  • Single glass: 0.86
  • Double glass: 0.76
  • Low-E glass: 0.40
  • Tinted glass: 0.50
  • Reflective: 0.20

Shading Coefficients:

  • No shading: 1.0
  • Light blinds: 0.7
  • Medium blinds: 0.5
  • Heavy drapes: 0.3
  • Exterior shading: 0.2

5. Transmission Heat Gain

Heat gain through building envelope (walls, roof, windows):

Q=U×A×ΔTQ = U \times A \times \Delta T

Where:

  • UU = U-value (W/(m2·K))
  • AA = Surface area (m2)
  • ΔT\Delta T = Temp difference (°C)

Typical U-Values (ASHRAE):

  • Walls:
    • Uninsulated: 2.5 W/(m2·K)
    • Insulated: 0.5 W/(m2·K)
    • Well insulated: 0.3 W/(m2·K)
  • Roof:
    • Uninsulated: 3.0 W/(m2·K)
    • Insulated: 0.4 W/(m2·K)
    • Well insulated: 0.25 W/(m2·K)
  • Windows:
    • Single: 5.7 W/(m2·K)
    • Double: 2.8 W/(m2·K)
    • Triple: 1.8 W/(m2·K)
    • Low-E: 1.5 W/(m2·K)

6. Ventilation Heat Gain

Heat gain from outdoor ventilation air fresh air circulation:

Sensible Heat:

Q=V˙×ρ×cp×ΔTQ = \dot{V} \times \rho \times c_p \times \Delta T

Latent Heat:

Q=V˙×ρ×hfg×ΔωQ = \dot{V} \times \rho \times h_{\text{fg}} \times \Delta \omega

Where:

  • V˙\dot{V} = Volumetric airflow rate (m3/s)
  • ρ\rho = Air supply density (1.204 kg/m3 at 20°C)
  • cpc_p = Specific heat of airflow (1005 J/(kg·K))
  • hfgh_{\text{fg}} = Latent heat of vaporization (2,450,000 J/kg)
  • ΔT\Delta T = Thermal reading difference (°C)
  • Δω\Delta \omega = Humidity ratio difference (kg/kg)

Atmosphere exchange Rates (ASHRAE 62.1):

  • Office: 10 L/s per person
  • Classroom: 7.5 L/s per person
  • Retail: 7.5 L/s per person
  • Restaurant: 10 L/s per person

7. Infiltration Heat Gain

Heat gain from uncontrolled ventilation air leakage:

Q=ACH×V3600×ρ×cp×ΔTQ = \frac{ACH \times V}{3600} \times \rho \times c_p \times \Delta T

Where:

  • ACHACH = Fresh air changes per hour
  • VV = Room volume (m3)

Typical Infiltration Rates:

  • Tight construction: 0.1 ACH
  • Average construction: 0.5 ACH
  • Loose construction: 1.0 ACH

Total Cooling Load Calculation

Sensible Cooling Load

Qsensible=Qpeople,sensible+Qlighting+Qequipment+Qsolar+Qtransmission+Qairflow,sensible+Qinfiltration,sensibleQ_{\text{sensible}} = Q_{\text{people,sensible}} + Q_{\text{lighting}} + Q_{\text{equipment}} + Q_{\text{solar}} + Q_{\text{transmission}} + Q_{\text{airflow,sensible}} + Q_{\text{infiltration,sensible}}

Where:

  • Qpeople,sensibleQ_{\text{people,sensible}} = People sensible heat gain
  • QlightingQ_{\text{lighting}} = Lighting heat gain
  • QequipmentQ_{\text{equipment}} = Equipment heat gain
  • QsolarQ_{\text{solar}} = Solar heat gain
  • QtransmissionQ_{\text{transmission}} = Transmission heat gain (walls, roof, windows)
  • Qsupply,sensibleQ_{\text{supply,sensible}} = Airflow supply sensible heat gain
  • Qinfiltration,sensibleQ_{\text{infiltration,sensible}} = Infiltration sensible heat gain

Latent Cooling Load

Qlatent=Qpeople,latent+Qatmosphere circulation,latent+Qinfiltration,latentQ_{\text{latent}} = Q_{\text{people,latent}} + Q_{\text{atmosphere circulation,latent}} + Q_{\text{infiltration,latent}}

Where:

  • Qpeople,latentQ_{\text{people,latent}} = People latent heat gain
  • Qventilation,latentQ_{\text{ventilation,latent}} = Airflow latent heat gain
  • Qinfiltration,latentQ_{\text{infiltration,latent}} = Infiltration latent heat gain

Total Cooling Load

Qtotal=Qsensible+QlatentQ_{\text{total}} = Q_{\text{sensible}} + Q_{\text{latent}}

Design Cooling Load (with Safety Factor)

Qdesign=Qtotal×SFQ_{\text{design}} = Q_{\text{total}} \times SF

Where SFSF = Safety factor (typically 1.1 to 1.3)

Equipment Sizing

Cooling Capacity

Refrigeration equipment is sized based on the design chilling load:

Tons of Refrigeration:

Tons=Q3.517Tons = \frac{Q}{3.517}

Where 1 ton = 3.517 kW (12,000 BTU/h)

Kilowatts:

kW=Q1000kW = \frac{Q}{1000}

Airflow Requirements

Required airflow for sensible temperature control:

V˙=Qρ×cp×ΔT\dot{V} = \frac{Q}{\rho \times c_p \times \Delta T}

Where ΔT\Delta T = Supply fresh air heat difference (typically 8-12°C)

Conversion to CFM:

CFM=V˙×2118.88CFM = \dot{V} \times 2118.88

Where 1 m3/s = 2118.88 CFM

Worked Example: Real-World Office Cooling Load Calculation

Modern Office Space: Complete Cooling Load Analysis

Scenario: You're designing the HVAC system for a new 80 m2 office space in a warm climate. The space will house 20 employees with standard office equipment. Your client needs accurate cooling load calculations to select the right air conditioning equipment and ensure comfortable working conditions year-round.

Project Specifications

Space Layout:

  • Dimensions: 10 m × 8 m × 3 m (length × width × height)
  • Floor Area: 80 m2
  • Volume: 240 m3
  • Window Area: 20 m2 (25% of floor area—typical for modern offices)

Occupancy & Internal Loads:

  • Occupants: 20 people (0.25 people/m2—standard office density)
  • Lighting: 15 W/m2 (LED lighting system)
  • Equipment: 20 W/m2 (computers, monitors, printers)

Building Envelope (Thermal Properties):

  • Walls: U-value = 0.5 W/(m2·K) (well-insulated)
  • Roof: U-value = 0.4 W/(m2·K) (insulated)
  • Windows: U-value = 2.8 W/(m2·K) (double-glazed)

Climate Conditions:

  • Outdoor Design Temperature: 33°C (peak summer condition)
  • Indoor Design Temperature: 24°C
  • Temperature Difference: ΔT=9\Delta T = 9°C

Ventilation & Air Quality:

  • Ventilation Rate: 2 ACH (meets ASHRAE 62.1 requirements)
  • Infiltration Rate: 0.5 ACH (average construction)

Solar Heat Gain:

  • Solar Heat Gain Coefficient (SHGC): 0.76 (double-glazed windows)
  • Solar Radiation: 800 W/m2 (peak afternoon, south-facing)
  • Shading Coefficient: 0.7 (light blinds installed)

Design Safety Factor: 1.2 (20% margin for uncertainties)

Step-by-Step Calculation

Step 1: Calculate Room Geometry

First, we determine the key areas and volumes needed for all subsequent calculations:

Afloor=10×8=80 m2Vroom=10×8×3=240 m3Awall=2×(10+8)×3=108 m2Aroof=10×8=80 m2ΔT=3324=9°C\begin{align} A_{\text{floor}} &= 10 \times 8 = 80 \text{ m}^2 \\ V_{\text{room}} &= 10 \times 8 \times 3 = 240 \text{ m}^3 \\ A_{\text{wall}} &= 2 \times (10 + 8) \times 3 = 108 \text{ m}^2 \\ A_{\text{roof}} &= 10 \times 8 = 80 \text{ m}^2 \\ \Delta T &= 33 - 24 = 9 \text{°C} \end{align}

Step 2: Calculate Internal Heat Gains

People Heat Gain (ASHRAE Standard Values):

Sensible heat from occupants:

Qpeople,sensible=20×70=1,400 WQ_{\text{people,sensible}} = 20 \times 70 = 1,400 \text{ W}

Latent heat from occupants:

Qpeople,latent=20×45=900 WQ_{\text{people,latent}} = 20 \times 45 = 900 \text{ W}

Lighting Heat Gain:

Qlighting=15×80=1,200 WQ_{\text{lighting}} = 15 \times 80 = 1,200 \text{ W}

Equipment Heat Gain:

Qequipment=20×80=1,600 WQ_{\text{equipment}} = 20 \times 80 = 1,600 \text{ W}

Step 3: Calculate External Heat Gains

Solar Heat Gain Through Windows:

This is often the largest single component in office cooling loads:

Qsolar=Awindow×Isolar×SHGC×SCQ_{\text{solar}} = A_{\text{window}} \times I_{\text{solar}} \times \text{SHGC} \times \text{SC}Qsolar=20×800×0.76×0.7=8,512 WQ_{\text{solar}} = 20 \times 800 \times 0.76 \times 0.7 = 8,512 \text{ W}

Transmission Heat Gain Through Building Envelope:

Heat entering through walls, roof, and windows:

Qwall=0.5×108×9=486 WQroof=0.4×80×9=288 WQwindow=2.8×20×9=504 WQtransmission=486+288+504=1,278 W\begin{align} Q_{\text{wall}} &= 0.5 \times 108 \times 9 = 486 \text{ W} \\ Q_{\text{roof}} &= 0.4 \times 80 \times 9 = 288 \text{ W} \\ Q_{\text{window}} &= 2.8 \times 20 \times 9 = 504 \text{ W} \\ Q_{\text{transmission}} &= 486 + 288 + 504 = 1,278 \text{ W} \end{align}

Step 4: Calculate Ventilation Heat Gains

Ventilation Airflow Rate:

V˙vent=ACH×V3600=2×2403600=0.133 m3/s\dot{V}_{\text{vent}} = \frac{\text{ACH} \times V}{3600} = \frac{2 \times 240}{3600} = 0.133 \text{ m}^3/\text{s}

Ventilation Sensible Heat:

Qvent,sensible=V˙×ρ×cp×ΔTQ_{\text{vent,sensible}} = \dot{V} \times \rho \times c_p \times \Delta T

Using ρ=1.204\rho = 1.204 kg/m3 and cp=1,005c_p = 1,005 J/(kg·K):

Qvent,sensible=0.133×1.204×1,005×9=1,451 WQ_{\text{vent,sensible}} = 0.133 \times 1.204 \times 1,005 \times 9 = 1,451 \text{ W}

Ventilation Latent Heat:

For humidity control, assuming Δω=0.008\Delta \omega = 0.008 kg/kg (typical for 33°C/60% RH outdoor, 24°C/50% RH indoor):

Qvent,latent=V˙×ρ×hfg×ΔωQ_{\text{vent,latent}} = \dot{V} \times \rho \times h_{\text{fg}} \times \Delta \omega

Using hfg=2,450,000h_{\text{fg}} = 2,450,000 J/kg:

Qvent,latent=0.133×1.204×2,450,000×0.008=3,130 WQ_{\text{vent,latent}} = 0.133 \times 1.204 \times 2,450,000 \times 0.008 = 3,130 \text{ W}

Step 5: Calculate Infiltration Heat Gains

Infiltration Airflow Rate:

V˙inf=0.5×2403600=0.033 m3/s\dot{V}_{\text{inf}} = \frac{0.5 \times 240}{3600} = 0.033 \text{ m}^3/\text{s}

Infiltration Sensible Heat:

Qinf,sensible=0.033×1.204×1,005×9=363 WQ_{\text{inf,sensible}} = 0.033 \times 1.204 \times 1,005 \times 9 = 363 \text{ W}

Infiltration Latent Heat:

Qinf,latent=0.033×1.204×2,450,000×0.008=783 WQ_{\text{inf,latent}} = 0.033 \times 1.204 \times 2,450,000 \times 0.008 = 783 \text{ W}

Step 6: Sum All Heat Gains

Total Sensible Heat Gain:

Qsensible=Qpeople,sensible+Qlighting+Qequipment+Qsolar+Qtransmission+Qvent,sensible+Qinf,sensible=1,400+1,200+1,600+8,512+1,278+1,451+363=15,804 W=15.8 kW\begin{align} Q_{\text{sensible}} &= Q_{\text{people,sensible}} + Q_{\text{lighting}} + Q_{\text{equipment}} \\ &\quad + Q_{\text{solar}} + Q_{\text{transmission}} + Q_{\text{vent,sensible}} + Q_{\text{inf,sensible}} \\ &= 1,400 + 1,200 + 1,600 + 8,512 + 1,278 + 1,451 + 363 \\ &= \textbf{15,804 W} = \textbf{15.8 kW} \end{align}

Total Latent Heat Gain:

Qlatent=Qpeople,latent+Qvent,latent+Qinf,latent=900+3,130+783=4,813 W=4.8 kW\begin{align} Q_{\text{latent}} &= Q_{\text{people,latent}} + Q_{\text{vent,latent}} + Q_{\text{inf,latent}} \\ &= 900 + 3,130 + 783 \\ &= \textbf{4,813 W} = \textbf{4.8 kW} \end{align}

Total Cooling Load:

Qtotal=Qsensible+Qlatent=15,804+4,813=20,617 W=20.6 kWQ_{\text{total}} = Q_{\text{sensible}} + Q_{\text{latent}} = 15,804 + 4,813 = \textbf{20,617 W} = \textbf{20.6 kW}

Step 7: Apply Safety Factor and Determine Design Load

Qdesign=Qtotal×SF=20,617×1.2=24,740 W=24.7 kWQ_{\text{design}} = Q_{\text{total}} \times \text{SF} = 20,617 \times 1.2 = \textbf{24,740 W} = \textbf{24.7 kW}

Step 8: Size Equipment and Determine Airflow Requirements

Equipment Capacity (Tons of Refrigeration):

Tons=Qdesign3.517=24,7403,517=7.0 tons\text{Tons} = \frac{Q_{\text{design}}}{3.517} = \frac{24,740}{3,517} = \textbf{7.0 tons}

Required Airflow for Sensible Cooling:

Assuming a 10°C supply air temperature difference (ΔTsupply=10\Delta T_{\text{supply}} = 10°C):

V˙=Qsensibleρ×cp×ΔTsupply=15,8041.204×1,005×10=1.31 m3/s\dot{V} = \frac{Q_{\text{sensible}}}{\rho \times c_p \times \Delta T_{\text{supply}}} = \frac{15,804}{1.204 \times 1,005 \times 10} = 1.31 \text{ m}^3/\text{s}

Converting to CFM:

CFM=1.31×2,118.88=2,775 CFM\text{CFM} = 1.31 \times 2,118.88 = \textbf{2,775 CFM}

Results Summary & Interpretation

ParameterValueEngineering Assessment
Total Cooling Load20.6 kWBase load without safety margin
Design Cooling Load24.7 kWEquipment selection basis
Required Capacity7.0 tonsSelect 7.5 ton unit (next standard size)
Required Airflow2,775 CFMVerify: 396 CFM/ton (within 350-450 range ✔ )
Load Density309 W/m2High—above typical office range (50-150 W/m2)
Load per Person1,237 W/personHigh—typical range is 100-300 W/person

Key Insights from This Calculation

Heat Gain Component Breakdown:

ComponentSensible (W)Latent (W)% of Total
Solar8,51241%
Ventilation1,4513,13022%
People1,40090011%
Equipment1,6008%
Transmission1,2786%
Lighting1,2006%
Infiltration3637836%
Total15,8044,813100%

Sensible Heat Ratio (SHR):

SHR=QsensibleQtotal=15,80420,617=0.77\text{SHR} = \frac{Q_{\text{sensible}}}{Q_{\text{total}}} = \frac{15,804}{20,617} = 0.77

This SHR of 0.77 is typical for office spaces and indicates the equipment must handle both temperature and humidity control effectively.

Equipment Selection Summary

Recommended Equipment:

  • Capacity: 7.5 tons (26.4 kW) — next standard size above 7.0 tons
  • Airflow: 2,775 CFM minimum (verify equipment can deliver)
  • SHR Match: Equipment SHR should be 0.75-0.80 for proper dehumidification
  • Efficiency: Verify meets ASHRAE 90.1 minimum EER/COP requirements

Verification Checklist:

  • ✔ Load density checked against typical values
  • ✔ Airflow per ton verified (396 CFM/ton is acceptable)
  • ✔ SHR matches application requirements
  • ✔ Safety factor applied (1.2 = 20%)
  • ✔ All heat gain components accounted for

Performance Metrics

Load per Area

L=QAL = \frac{Q}{A}

Typical Values:

  • Low: < 50 W/m2
  • Moderate: 50-100 W/m2
  • High: 100-150 W/m2
  • Very High: 150-200 W/m2
  • Critical: > 200 W/m2

Load per Volume

L=QVL = \frac{Q}{V}

Typical range: 20-80 W/m3

Load per Person

L=QNL = \frac{Q}{N}

Typical range: 100-300 W/person

Common Mistakes and Best Practices

Common Mistakes

  1. Oversizing Equipment: Using excessive safety factors (>1.3) wastes energy
  2. Ignoring Internal Gains: Underestimating people, lighting, and equipment heat
  3. Incorrect U-Values: Using outdated or incorrect thermal properties
  4. Solar Heat Gain: Underestimating solar heat gain through windows
  5. Airflow Load: Not accounting for air supply movement and infiltration properly
  6. Latent Load: Ignoring latent heat gain from humidity

Best Practices

  1. Use ASHRAE Standards: Follow ASHRAE Fundamentals Handbook methods
  2. Account for All Heat Sources: Include all internal and external heat gains
  3. Consider Peak Loads: Design for worst-case conditions
  4. Apply Reasonable Safety Factors: Use 1.1-1.2 for typical applications
  5. Verify with Multiple Methods: Cross-check calculations with different methods
  6. Consider Part-Load Operation: Design for variable loads with staging
  7. Document Assumptions: Clearly document all input parameters and assumptions

Advanced Considerations

Diversity Factors

For multiple spaces, apply diversity factors to account for non-simultaneous peak loads:

  • Office Buildings: 0.7-0.8
  • Residential: 0.5-0.7
  • Retail: 0.6-0.8

Time-Dependent Loads

AC loads vary throughout the day:

  • Solar Heat Gain: Peaks at midday
  • Occupancy: Varies with building use
  • Equipment: May have scheduled operation
  • Airflow supply: May be reduced during unoccupied hours

Zoning Strategies

Divide buildings into thermal zones:

  • Exterior Zones: High solar and transmission loads
  • Interior Zones: Primarily internal heat gains
  • North vs. South: Different solar exposure
  • East vs. West: Different peak times

Conclusion

Accurate cooling load calculation is essential for proper HVAC system design. By understanding the principles, following ASHRAE standards, and applying the methods outlined in this guide, engineers can ensure energy-efficient, cost-effective, and comfortable building environments.

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Key Takeaways

Core Formula

Total cooling load is the sum of sensible and latent heat components:

Qtotal=Qsensible+QlatentQ_{\text{total}} = Q_{\text{sensible}} + Q_{\text{latent}}

Where:

  • Sensible heat (QsensibleQ_{\text{sensible}}) causes temperature change—typically 70-80% of total load
  • Latent heat (QlatentQ_{\text{latent}}) affects humidity through moisture—typically 20-30% of total load

Essential Heat Sources

Account for ALL heat gain components in your calculations:

ComponentSensibleLatentASHRAE Standard
People70 W/person45 W/personFundamentals Handbook
Lighting8-25 W/m2Technology dependent
Equipment15-100 W/m2Usage dependent
SolarVariableSHGC × SC × Area
TransmissionU×A×ΔTU \times A \times \Delta TEnvelope dependent
Ventilationρ×cp×V˙×ΔT\rho \times c_p \times \dot{V} \times \Delta Tρ×hfg×V˙×Δω\rho \times h_{\text{fg}} \times \dot{V} \times \Delta \omegaASHRAE 62.1
InfiltrationACH-basedACH-basedConstruction dependent

Critical: Missing any component leads to undersized equipment and comfort failures.

ASHRAE Standard Values

Use ASHRAE Fundamentals Handbook values for reliable calculations:

  • People heat gain: 115 W/person total (70 W sensible + 45 W latent) for office work
  • Ventilation rates: 10 L/s per person for offices (ASHRAE 62.1)
  • U-values: Modern insulated walls 0.3-0.5 W/(m2·K), roofs 0.25-0.4 W/(m2·K)
  • Solar Heat Gain Coefficient (SHGC): 0.20 (reflective) to 0.86 (single glass)

Safety Factor Application

Apply safety factor of 1.1-1.2 to design load:

Qdesign=Qtotal×SFQ_{\text{design}} = Q_{\text{total}} \times \text{SF}

Guidelines:

  • 1.1 (10%): Well-documented projects with low uncertainty
  • 1.2 (20%): Standard practice for most applications
  • >1.3: Avoid—causes oversizing, energy waste, and poor humidity control

Equipment Sizing

Size equipment based on design cooling load:

Tons=Qdesign3.517 kW\text{Tons} = \frac{Q_{\text{design}}}{3.517 \text{ kW}}

Where 1 ton = 3.517 kW (12,000 BTU/h)

Selection criteria:

  • Select next standard size ≥ calculated capacity
  • Verify airflow: 350-450 CFM per ton
  • Match Sensible Heat Ratio (SHR) to application requirements
  • Ensure compliance with ASHRAE 90.1 efficiency standards

Load Density Verification

Verify load density against typical ASHRAE values:

Building TypeTypical RangeNotes
Residential40-80 W/m2Lower internal gains
Office50-150 W/m2Standard glazing, moderate gains
Retail80-120 W/m2High lighting, customer density
Restaurant100-150 W/m2Cooking equipment, high occupancy
Server Room200-400 W/m2High equipment density

Red flag: If your calculated load density significantly exceeds these ranges, review:

  • Solar heat gain assumptions (window area, SHGC, shading)
  • Ventilation rates (may be too high)
  • Internal gains (equipment/lighting power density)
  • Building envelope U-values (may be outdated)

Further Learning

References & Standards

Primary Standards

ASHRAE Fundamentals Handbook Chapter 18: Cooling and Heating Load Calculation Principles. Provides comprehensive guidance on cooling load calculation methods, heat gain components, and calculation procedures. Chapter 19 covers nonresidential cooling and heating load calculations.

ASHRAE Standard 62.1 Ventilation for Acceptable Indoor Air Quality. Specifies minimum ventilation rates (10 L/s per person for offices) that affect cooling load calculations through ventilation heat gain.

ASHRAE Standard 90.1 Energy Standard for Buildings. Establishes minimum energy efficiency requirements including maximum U-values for building envelope and minimum equipment efficiency ratings that impact cooling load calculations.

Supporting Standards & Guidelines

AHRI Standards Air-Conditioning, Heating, and Refrigeration Institute certification programs. Provides performance rating standards for HVAC equipment.

EN 14511 Air conditioners, liquid chilling packages and heat pumps for space heating and cooling and process chillers. European standard for AC equipment testing and rating.

Further Reading

Note: Standards and codes are regularly updated. Always verify you're using the current adopted edition applicable to your project's location. Consult with local authorities having jurisdiction (AHJ) for specific requirements.

Disclaimer: This guide provides general technical information based on international HVAC standards. Always verify calculations with applicable local codes and consult licensed professionals for actual installations. HVAC system design should only be performed by qualified professionals. Component ratings and specifications may vary by manufacturer.

Frequently Asked Questions

Cooling Load Guide | Enginist