You need to look at a steam table first then Multiply lbs/hr steam x latent heat of evaporation in BTU/lb @ the operating pressure.
Divide the dollars per kWh by 3,412.14163
A 10,000 BTU heater will use about 1/2 pound of propane per hour. Conversions to different types of energy being used (ie steam, KwH, etc.) will vary the answer, as will variations such as leaks, 02, temperature setting, efficiency, etc.
Pounds per square foot x 0.006944 equals psi
Standard shower is taken to be 10 gallons at 8.35 pounds per gallon and 60 degrees F of heating = 5,000 BTU per shower in round numbers, assuming 100% efficiency water heating.
The answer will depend on what it is that you wish to convert into PSI. You cannot. Inches are a linear measure, PSI (pounds per square inch) is a measure of pressure. The units are incompatible.
btu per pound * pounds per gallon OK, it sounds as if you know the value of fuel in oil btu per pound.Now find out how much a gallon of fuel oil weighs and multiply the btu value x that weight in pounds and that is the value per gallon. Or simply, diesel fuel is #2 fuel oil which contains 140,000 btu per gallon.
To convert foot-pounds per minute (ft-lb/min) to British thermal units per hour (BTU/hr), you can use the conversion factor that 1 ft-lb/min is equivalent to 0.00063241 BTU/hr. Simply multiply the value in ft-lb/min by 0.00063241 to obtain the equivalent value in BTU/hr.
To change 10 pounds of ice at 20 degrees Fahrenheit to steam at 220 degrees Fahrenheit, you need to supply enough energy to first melt the ice, then heat the water to the boiling point, and finally convert it to steam. This process requires approximately 180 BTUs per pound of ice to melt it, 180 BTUs per pound of water to heat it to the boiling point, and then 970 BTUs per pound of water to convert it to steam. So, for 10 pounds of ice, the total BTUs required would be around 18,300 BTUs.
ONE BTU is about 778.16 ft lbs. Divide by 60 to change minutes to hours.
Divide the dollars per kWh by 3,412.14163
To convert watts per meter squared per degree Celsius to BTU per hour per degree Fahrenheit, you can use the following conversion factors: 1 Watt per meter squared per degree Celsius = 0.317 BTU per hour per foot squared per degree Fahrenheit.
1 BTU is required to raise 1lb of water 1 degree F in 1 hour. 212-75=137 degrees 600 lbs water x 137 degrees= 82,200 BTU's required to change 75 degree water to 212 degree water. To change 212 degree water to 212 degree steam it requires 970 btu's (latent heat of vaporization) per lb of water 970 btu x 600 lbs water = 582,000 btu Answer - 582,000 btu+ 82,200 btu = 664,200 btu's
To convert BTU per hour to frigorias per hour, you can use the conversion factor 0.251995760032 BTU per hour is equal to 1 frigoria per hour. Therefore, 3988777 BTU per hour is approximately equal to 15886.05 frigorias per hour.
How to convert kilocalorie to kilograme
To convert British thermal units (Btu) to millions of standard cubic feet (MMSCF), you can use the following conversion factor: 1 MMSCF = 1,000,000 Btu To perform the conversion, you can divide the number of Btu by 1,000,000 to get the equivalent number of MMSCF. For example, if you have 10,000,000 Btu, you can divide this number by 1,000,000 to get the equivalent number of MMSCF: 10,000,000 Btu / 1,000,000 Btu/MMSCF = 10 MMSCF It's important to note that this conversion factor assumes that the Btu and MMSCF are both based on the same standard temperature and pressure (STP). The STP for Btu is typically defined as 60 degrees Fahrenheit and 14.7 pounds per square inch, while the STP for MMSCF is typically defined as 60 degrees Fahrenheit and 14.73 pounds per square inch. If the Btu and MMSCF are based on different STP values, the conversion factor may be different. It's also worth noting that MMSCF is a unit of volume, while Btu is a unit of energy, so it's not really meaningful to convert directly between these two units. In order to convert Btu to MMSCF, you would need to know the energy content of the gas in question, as well as the volume of the gas at a given temperature and pressure.
Approximately 1725 MBH, assuming the steam is all condensed, since the heat of vaporization is approximately 1000 BTU/lb. Heat of vaporization varies with steam pressure, so the answer will vary somewhat, depending on the steam pressure delivered, but that will usually get you within 5% or so.
Btu / scf = Btu / lb X MW / 379.5 where: MW = molecular weight of the gas, lb / lb-mol The constant 379.5 is the molar volume at standard conditions of 14.696 psia and 60°F