Heater Sizing Calculator for Gardening

Heater sizing inputs

Use 3 columns on large screens, 2 on medium, and 1 on mobile.

Units

Length (m)

Width (m)

Average height (m)

Inside setpoint (°C)

Outside design temp (°C)

Ground temp (optional) (°C)

Used only if you include floor losses.

Glazing share of walls+roof (%)

Higher values increase heat loss for most builds.

Glazing U-value (W/m²·K)

Solid surface U-value (W/m²·K)

Air changes per hour (ACH)

Typical: 0.5–2.0. Leaky structures: 3+.

Include floor losses?

Helpful for raised floors or cold slabs.

Floor U-value (W/m²·K)

Safety factor

Common range: 1.10–1.25.

Heater efficiency (0–1)

Electric resistance is near 1.0.

Expected duty cycle (%)

Estimate how often heating runs at load.

Hours per day

Days per month

Electric rate (per kWh)

For non-electric heaters, treat as comparison only.

Reset

Example data table

Scenario	Size	Inside / Outside	Glazing	ACH	Efficiency	Suggested capacity
Small hobby greenhouse	4m × 2m × 2.2m	18°C / 2°C	90% double glazing	1.5	0.90	≈ 7,000–10,000 BTU/hr
Insulated grow room	12ft × 10ft × 8ft	70°F / 35°F	10% glazing, insulated walls	0.7	0.95	≈ 4–6 kW
Leaky tunnel house	8m × 3m × 2.5m	16°C / 0°C	95% thin film	3.0	0.85	≈ 25,000–35,000 BTU/hr

Examples are illustrative. Local wind, gaps, and thermal mass change real demand.

Formula used

The calculator models heat loss from transmission through surfaces and infiltration from air exchange. It then applies safety and efficiency.

Transmission loss: Q_trans = (U_glaze·A_glaze + U_solid·A_solid) · ΔT
Infiltration loss (metric): Q_inf = 0.33 · ACH · V · ΔT
Infiltration loss (imperial): Q_inf = 0.018 · ACH · V · ΔT
Floor loss (optional): Q_floor = U_floor · A_floor · (T_in − T_ground)
Recommended output: Q_reco = (Q_trans + Q_inf + Q_floor) · Safety
Nameplate rating: Q_nameplate = Q_reco ÷ Efficiency

The constants 0.33 and 0.018 approximate air heat capacity with unit conversions. ΔT uses your inside and outside temperatures.

How to use this calculator

Select metric or imperial units first.
Enter length, width, and average height of your space.
Set your inside temperature and your cold outside design temperature.
Choose glazing and solid surface insulation presets, or enter custom U-values.
Estimate ACH based on tightness, vents, and expected wind exposure.
Add a safety factor, then set heater efficiency for your fuel type.
Press Calculate heater size to see results above the form.
Use Download CSV or Download PDF for records.

Heat loss drivers in garden structures

Heater demand rises with surface area, poor insulation, and higher temperature difference. Glazing usually dominates because its U-value is higher than solid panels. Wind also matters because it increases infiltration through gaps, vents, and doors, raising ACH and pushing the required capacity upward during winter.

Choosing realistic design temperatures

Use a conservative outside design temperature that matches your coldest typical nights, not the seasonal average. For seedlings, stable minimums reduce stress, so pick an inside setpoint that reflects the crop, humidity control, and condensation risk. A small change in ΔT can shift heater size noticeably. If you heat only at night, keep daytime gains out of the setpoint.

Using U-values and glazing percentage well

If you know the cover material, start with a preset U-value and adjust only if you have measured performance. Enter glazing percentage for walls plus roof so the model splits heat loss between glazing and insulated surfaces. Better covers reduce transmission, so you can often downsize while maintaining the same setpoint. Add interior curtains to reduce effective glazing losses.

Accounting for air exchange and door openings

ACH captures leakage plus planned ventilation. Tight greenhouses may run near 0.5–1.0 ACH, while tunnel houses can exceed 3.0 in wind. If doors open often, increase ACH or apply a larger safety factor. Consider a vestibule, weather seals, and controlled intake to reduce losses. Fans that mix air can reduce cold pockets and improve thermostat accuracy.

Interpreting results and selecting equipment

The recommended output already includes safety margin, while the adjusted nameplate accounts for heater efficiency. If you use electric resistance heat, efficiency is close to 1.0, so nameplate and output match closely. For combustion heaters, verify rated output, ventilation needs, and safe clearance around plants. Distribute heat with circulation fans, and consider zoning so you heat propagation benches instead of the full volume. Thermal mass, like water barrels, can reduce cycling and lower peak demand.

FAQs

1) What inside temperature should I use for seedlings?

Use the minimum temperature your crop needs overnight. Many seedlings prefer steady warmth, but humidity and disease risk matter too. Pick a setpoint you can maintain without heavy condensation.

2) How do I estimate ACH if I do not know it?

Start with 1.0 ACH for an average greenhouse, 0.5 for tight rooms, and 2–3 for drafty tunnel houses. Increase the value if wind exposure, vents, or frequent door openings are common.

3) Should I use custom U-values or presets?

Presets are reliable for planning when materials are typical. Use custom values only if you have manufacturer data or tested performance. Incorrect U-values can overstate savings or oversize equipment.

4) Why does glazing percentage change the result so much?

Glazing usually transfers heat faster than insulated panels. A larger glazed share increases transmission losses, especially at high ΔT. Improving covers or adding inner curtains can reduce this penalty.

5) What safety factor is reasonable?

Common values are 1.10 to 1.25 to cover wind spikes, door use, and uneven heat distribution. If your structure is exposed or you cannot tolerate drops, choose the higher end.

6) How should I use the monthly cost estimate?

It is a planning estimate for electric heating using your duty cycle, hours, and rate. Real use varies with weather and controls. Compare scenarios to see which upgrades reduce ongoing costs.