🌡️ kW/(m·K) to BTU/(h·ft·°F) — Kilowatt/(Meter·Kelvin) to BTU/(Hour·Foot·°F) Converter

Convert thermal conductivity units — W/(m·K), BTU/(h·ft·°F), cal/(s·cm·°C) and more.

1 unit =
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To
Formula 1 kW/(m·K) = 577.8 BTU/(h·ft·°F)
All Kilowatt/(Meter·Kelvin) conversions
UnitNameValue
W/(m·K) Watt/(Meter·Kelvin) 1000
BTU/(h·ft·°F) BTU/(Hour·Foot·°F) 577.79087
cal/(s·cm·°C) Calorie/(Second·cm·°C) 2.388459
kcal/(h·m·°C) Kilocalorie/(Hour·m·°C) 859.84523
Related Thermal Conductivity conversions
W/(m·K) → BTU/(h·ft·°F) BTU/(h·ft·°F) → W/(m·K) W/(m·K) → cal/(s·cm·°C)

Quick Answer

Formula: BTU/(h·ft·°F) = kW/(m·K) × 577.8

Multiply any kW/(m·K) value by 577.8 to get BTU/(h·ft·°F).

Reverse: kW/(m·K) = BTU/(h·ft·°F) × 0.001731

Copper reference: 0.401 kW/(m·K) = 231.7 BTU/(h·ft·°F)

Worked Examples

2.6000e-5 kW/(m·K)
2.6000e-5 kW/(m·K) × 577.8 = 0.01502 BTU/(h·ft·°F)
Air — lowest practical value.
0.001 kW/(m·K)
0.001 kW/(m·K) × 577.8 = 0.5778 BTU/(h·ft·°F)
Glass — moderate insulator.
0.05 kW/(m·K)
0.05 kW/(m·K) × 577.8 = 28.89 BTU/(h·ft·°F)
Steel — structural metal.
0.401 kW/(m·K)
0.401 kW/(m·K) × 577.8 = 231.7 BTU/(h·ft·°F)
Copper — excellent conductor.

Thermal Conductivity of Common Materials

Factor: 1 kW/(m·K) = 577.8 BTU/(h·ft·°F)

kW/(m·K) (kW/(m·K))BTU/(h·ft·°F) (BTU/(h·ft·°F))Material
2.2 kW/(m·K)1271 BTU/(h·ft·°F)Diamond
0.429 kW/(m·K)247.9 BTU/(h·ft·°F)Silver
0.401 kW/(m·K)231.7 BTU/(h·ft·°F)Copper
0.318 kW/(m·K)183.7 BTU/(h·ft·°F)Gold
0.237 kW/(m·K)136.9 BTU/(h·ft·°F)Aluminum
0.052 kW/(m·K)30.05 BTU/(h·ft·°F)Cast iron
0.05 kW/(m·K)28.89 BTU/(h·ft·°F)Steel (carbon)
0.0025 kW/(m·K)1.444 BTU/(h·ft·°F)Marble
0.0017 kW/(m·K)0.9822 BTU/(h·ft·°F)Concrete
0.001 kW/(m·K)0.5778 BTU/(h·ft·°F)Glass
0.0006 kW/(m·K)0.3467 BTU/(h·ft·°F)Water (20°C)
0.00017 kW/(m·K)0.09822 BTU/(h·ft·°F)Wood (oak)
4.000e-05 kW/(m·K)0.02311 BTU/(h·ft·°F)Fiberglass batt
2.600e-05 kW/(m·K)0.01502 BTU/(h·ft·°F)Air (25°C)
1.500e-05 kW/(m·K)0.008667 BTU/(h·ft·°F)Aerogel

Mental Math Tricks

Exact factor

1 kW/(m·K) = 577.8 BTU/(h·ft·°F).

Material anchors

Copper ≈ 401 W/(m·K). Steel ≈ 50 W/(m·K). Glass ≈ 1 W/(m·K). Air ≈ 0.026 W/(m·K).

Reverse

Multiply result by 0.001731 to recover the original kW/(m·K) value.

Who Uses This Conversion?

Building Physicist

Specifies insulation and wall assembly thermal conductivity in W/(m·K) for energy compliance calculations.

HVAC Engineer

Uses BTU/(h·ft·°F) for US building code compliance and W/(m·K) for metric heat transfer calculations.

Materials Engineer

Compares thermal conductivity of metals, polymers, and composites in W/(m·K) for thermal management design.

Electronics Cooling Engineer

Selects thermal interface materials and heatsinks using conductivity data in W/(m·K).

Chemical Process Engineer

Designs heat exchangers using shell and tube thermal conductivity specifications in W/(m·K).

Research Physicist

Measures and reports thermal conductivity of novel materials (graphene, CNTs, aerogels) in W/(m·K) or kW/(m·K).

Related Conversions

Reverse: BTU/(h·ft·°F) to kW/(m·K) kW/(m·K) to W/(m·K) kW/(m·K) to cal/(s·cm·K) kW/(m·K) to kcal/(h·m·°C) W/(m·K) to BTU/(h·ft·°F) cal/(s·cm·K) to BTU/(h·ft·°F) kcal/(h·m·°C) to BTU/(h·ft·°F) Specific Heat Converter Energy Converter All Thermal Conductivity Converters

Frequently Asked Questions

About kW/(m·K) and BTU/(h·ft·°F)

kW/(m·K) (kW/(m·K))

Kilowatt per meter per kelvin (kW/(m·K)) equals 1,000 W/(m·K) and is used for highly thermally conductive materials. Diamond at 2.2 kW/(m·K) and silver at 0.429 kW/(m·K) are examples where kW/(m·K) provides convenient values.

kW/(m·K) is used in research papers and data tables for metallic and crystalline materials with very high conductivity. Carbon nanotubes can reach 3–6 kW/(m·K) along their axis — the highest known at room temperature.

Interesting fact: Graphene, a single layer of carbon atoms, has a thermal conductivity of about 4–5 kW/(m·K) in-plane — the highest of any known material. This makes it a promising material for next-generation thermal management in electronics.

BTU/(h·ft·°F) (BTU/(h·ft·°F))

BTU per hour per foot per degree Fahrenheit (BTU/(h·ft·°F)) is the Imperial thermal conductivity unit, equal to 1.73073 W/(m·K). It is the standard in US building codes, insulation specifications, and HVAC engineering.

US building energy codes (ASHRAE, IBC) specify insulation conductivity in BTU/(h·ft·°F). R-values in North American insulation are derived from this unit: R-value = thickness (inches) ÷ (k × 12), where k is in BTU/(h·ft·°F). Air = 0.015 BTU/(h·ft·°F); fiberglass batt = 0.025 BTU/(h·ft·°F).

Interesting fact: US insulation is marketed using R-values (thermal resistance), not k-values (conductivity). R-13 wall insulation has a conductivity of about 0.025 BTU/(h·ft·°F). The confusion between R-value and k-value is a common source of error in building energy calculations.

About kW/(m·K) to BTU/(h·ft·°F) Conversion

Thermal conductivity measures how readily a material conducts heat. The SI unit W/(m·K) is universal in science; US building codes use BTU/(h·ft·°F); older European engineering uses kcal/(h·m·°C); CGS physics uses cal/(s·cm·K). Key anchors: air 0.026 W/(m·K), glass 1.0, steel 50, copper 401, diamond 2,200.

Exact factor: 1 kW/(m·K) = 577.8 BTU/(h·ft·°F). Reverse: 1 BTU/(h·ft·°F) = 0.001731 kW/(m·K).

All conversions use IEEE 754 double-precision arithmetic, accurate to at least 8 significant figures.