Well, darling, BTU stands for British Thermal Unit, which is a unit of energy. It's not directly convertible to Fahrenheit, which is a unit of temperature. It's like asking how many apples are in a mile - they just don't play in the same sandbox.
Heat quantity is measured by 3 different types of units. In the united states, Fahrenheit is the standard measurement. We also use Celsius. There is one more besides these two and it is Kelvin.
BTU
70000 BTU/hr = 20.5kW > 70000 BTU/min = 1230.9kW > 70000 BTU/sec = 73854.2kW
Does not computeKilowatts do not convert to BTU and vice versa. The watt is a unit of power, whereas the BTU is a unit of energy. Perhaps you meant BTU/hr. 1.5E5 BTU/hr = 43.96 kilowattsYou could do a direct conversion into Killowatt hours though one would assume.1.5E5 BTU = 43.96 KWh
To convert Cubic Feet to Btu's, multiply by 1,000 1 CF = 1,000 Btu's
One btu will heat a pound of water about one degree Fahrenheit in one hour.
It takes 1 BTU to raise 1 lb of water per degree Fahrenheit.
answer: 7680 btu 1 gallon= 8 lb 130F-50F=80F 12G*8LB*80F=7680 BTU
To calculate the BTUs required to raise the temperature by 1 degree Fahrenheit in a 500,000 cubic foot area, you first need to know the specific heat capacity of air, which is approximately 0.24 BTU/lb·°F, and the density of air, around 0.075 lb/ft³. Thus, the total weight of the air in the space is about 37,500 lbs (500,000 ft³ × 0.075 lb/ft³). Multiplying this by the specific heat gives approximately 9,000 BTU needed to raise the temperature by 1 degree Fahrenheit in that volume.
15000 BTU/hr is equivalent to approximately 139,500 BTU/day. To convert this to Fahrenheit, you would need to consider other factors like the specific heat capacity of the material involved. Temperature is a measure of the average kinetic energy of the particles in a substance, which is different from the energy being produced by the 15000 BTU/hr.
The latent heat of vaporization of water at 212 degrees Fahrenheit at atmospheric pressure involving only vaporization and no saturation is 970 BTU/lb, so to evaporate 15 lbs of water we need 970 x 15 = 14550 BTU's
The British Thermal Unit (BTU) was originally defined based on the Fahrenheit temperature scale, where one BTU is the amount of heat required to raise the temperature of one pound of water by one degree Fahrenheit.
If you're in Celsius, 13459.5 Btu's. If you're in Fahrenheit, 12632.5 Btu's.
To heat 1 pound of water by 1 degree Fahrenheit, you need 1 British Thermal Unit (BTU). This is based on the definition of a BTU, which is the amount of heat required to raise the temperature of one pound of water by one degree Fahrenheit at a constant pressure.
One btu is the amount of energy it takes to heat 1 pound of water 1 degree Fahrenheit.
It takes 1 BTU (British Thermal Unit) to cool 1 pound of water by 1 degree Fahrenheit.
That's going to depend on how much water you're responsible for. Teacup at 60 degrees . . . very few BTU. Swimming pool at 60 degrees . . . many more BTU. It's also going to depend on whether you're talking about Celsius or Fahrenheit degrees. Fahrenheit degrees . . . fewer BTU. Celsius degrees . . . more BTU. (Also, the water will escape as you pass 100.) In general, one BTU is approximately the energy required to raise the temperature of 1 pound of water 1 degree Fahrenheit. You can take it from there, when you reach the job site and determine the exact scope of the work.