HVAC Load Calculator
-- BTU/hr
Enter building details to calculate

Building Parameters

Envelope Insulation

System Conditions

Load Summary

Heating Load
--
BTU/hr
Cooling Load
--
BTU/hr
--
Heat BTU/sqft
--
Cool BTU/sqft
--
Window Area (sqft)
--
Wall Area (sqft)
Winter Design ΔT -- °F
Summer Design ΔT -- °F
Load density within typical range
Ceil Floor Wall Wall -- BTU/hr Heating Load

Heating Load Components

Cooling Load Components

🔥

Gas Furnace

-- BTU/hr
-- input BTU/hr at 80% AFUE
Oversizing by >15% reduces comfort and efficiency. Size to output, not input.
❄️

Central Air Conditioner

-- Tons
-- BTU/hr cooling capacity
Rule of thumb: 400–500 sqft per ton for well-insulated homes. Oversizing causes short-cycling.
♻️

Heat Pump

-- Tons
-- BTU/hr (heating + cooling)
Size to the larger load (heating or cooling). May need auxiliary heat in Zone 5+.

Sizing Comparison

IECC Climate Zone Design Temperatures

ZoneRegionWinter Design (°F)Summer Design (°F)ΔT Heat (70° indoor)ΔT Cool (75° indoor)
1Very Hot (Miami)45°F91°F25°F16°F
2Hot (Houston)30°F96°F40°F21°F
3Warm (Atlanta)22°F92°F48°F17°F
4Mixed (Baltimore)12°F91°F58°F16°F
5Cool (Chicago)-4°F91°F74°F16°F
6Cold (Minneapolis)-16°F88°F86°F13°F
7Very Cold (Fairbanks)-47°F78°F117°F3°F

IECC 2021 Minimum Insulation Requirements

ZoneWall (cavity)CeilingFloorWindow U-max
1R-13R-30R-13U-0.50
2R-13R-38R-13U-0.40
3R-20 or R-13+5R-38R-19U-0.30
4R-20 or R-13+5R-49R-19U-0.30
5R-20+5 or R-13+10R-49R-30U-0.27
6R-20+5 or R-13+10R-49R-30U-0.27
7R-21+R-12ciR-49R-38U-0.22

Typical Load Density (BTU/hr per sq ft)

Building TypeHeatingCoolingNotes
High-performance (Zone 4–6)15–2510–15R-21 walls, R-49 ceil, triple glazing
Code-minimum (Zone 4–6)25–4015–25R-13–20 walls, R-38–49, double LowE
Older/poorly insulated (Zone 5–6)40–6020–30R-11 walls, R-19 ceil, single/double pane
Hot-dry climate (Zone 2–3)10–2020–30Cooling-dominant; low heating loads
Commercial office25–3525–40Higher internal gains

U-Values by Assembly Type

AssemblyR-ValueU-ValueNotes
Wall — R-13 batt + framing~R-120.082Includes framing factor & air films
Wall — R-20 + framing~R-170.059Wood frame, typical sheathing
Ceiling — R-38 atticR-380.026Blown/batt, no framing factor
Ceiling — R-49 atticR-490.020IECC zone 5–8 minimum
Window — Double LowER-3.30.30Standard ENERGY STAR zone 4–6
Window — Triple LowER-5.00.20Premium; required zone 7–8
Floor — R-13 over crawl~R-13.50.074Includes air films

How to Use This HVAC Load Calculator

  1. 1
    Select your climate zone — IECC zones 1–7 determine design temperatures. If you don't know your zone, look up your city on the IECC map or enter your zip code on energy.gov.
  2. 2
    Enter conditioned floor area — Include only heated/cooled spaces. Exclude garages, unfinished basements, and attics.
  3. 3
    Set ceiling height and stories — These determine building volume for infiltration calculations and wall area estimation.
  4. 4
    Choose insulation levels — Match your actual or planned construction. IECC minimum is pre-selected for zone 4 as a baseline.
  5. 5
    Set window-to-floor ratio — 15% is typical for residential. Energy codes often limit windows to 15–20% of floor area.
  6. 6
    Review Equipment Sizing tab — See recommended furnace BTU/hr, AC tonnage, and heat pump sizing based on your loads.

Key Formulas

Envelope Heat LossQ = U × A × ΔT
Infiltration LossQ = 0.018 × ACH × V × ΔT
Solar GainQ = SHGC × I × A × CLF
Design ΔT (heat)ΔT = 70°F − T_winter_design
Design ΔT (cool)ΔT = T_summer_design − 75°F
AC TonnageTons = BTU/hr ÷ 12,000

Glossary

Manual J
ACCA Manual J is the industry-standard method for calculating residential HVAC loads. This calculator uses a simplified Manual J approach.
Design Temperature
The outdoor temperature used for load calculations — typically the 99% heating or 1% cooling design condition from ASHRAE weather data.
U-Value
Thermal transmittance in BTU/hr·ft²·°F. The inverse of R-value (U = 1/R). Lower U = better insulation.
ACH (Air Changes/Hour)
The number of times per hour the entire building volume of air is replaced by infiltration. Tight modern homes: 0.25–0.35 ACH.
SHGC
Solar Heat Gain Coefficient — fraction of solar radiation admitted through a window. Lower SHGC reduces cooling loads in sunny climates.
Tonnage
AC capacity unit equal to 12,000 BTU/hr (heat removed to freeze one ton of ice in 24 hours). Residential systems: 1.5–5 tons.
AFUE
Annual Fuel Utilization Efficiency — percent of fuel converted to heat. 80% AFUE = 80% efficient. Federal minimum is 80% for most climates.
CLF
Cooling Load Factor — accounts for the time lag between heat gain and peak cooling load due to building thermal mass.

Frequently Asked Questions

How accurate is this calculator vs. a professional Manual J?

This simplified calculator gives results within 15–25% of a full Manual J for typical rectangular homes. Professional Manual J software (e.g., Wrightsoft, Elite RHVAC) accounts for exact room-by-room layouts, orientation, shading, duct losses, and local weather data. For equipment purchasing decisions, hire an HVAC contractor to perform a full Manual J.

My load density seems high — what's normal?

For a code-minimum home in Zone 4–5, 25–40 BTU/hr per sq ft for heating and 15–25 BTU/hr per sq ft for cooling are typical. Older homes can reach 50–60 BTU/hr·sqft. High-performance homes can be as low as 15–20 BTU/hr·sqft. Very high densities usually indicate high infiltration, poor insulation, or large windows.

Should I size up for safety margin?

No — ACCA Manual J explicitly discourages oversizing. An oversized furnace short-cycles (turns on/off rapidly), reducing efficiency and comfort. An oversized AC cools too fast without dehumidifying adequately. Size to the calculated load ± 15%. Modulating variable-speed equipment can tolerate slightly more oversizing.

What about duct losses?

This calculator calculates building envelope loads only. Duct losses in unconditioned spaces (attics, crawlspaces) can add 15–30% to equipment sizing requirements. The ACCA Manual D standard recommends adding a duct loss factor if ducts run outside the conditioned envelope.

Does this account for humidity/latent load?

This calculator estimates sensible (temperature) loads only. Latent (humidity) loads can add 20–40% to cooling equipment sizing in humid climates (Zones 1–3A). Full Manual J includes latent calculations using wet-bulb design temperatures and psychrometric analysis.

How do I find my IECC climate zone?

IECC climate zones are determined by county. You can look up your county on the DOE Building Energy Codes Program map at energycodes.gov/about/climate-zones, or search your state's energy code office. Most US population centers are in Zones 3–6.

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