If there are 93,000 btu's per gallon of propane, and you are burning 25,000 per hour. That would be 3.72 hours per gallon or approx .27 gallons per hour. 6.45 gallons per day.
A 10-kilowatt heater produces 34,120 BTUs per hour.
BTUs, or British Thermal Units, measure the amount of heat energy required to raise the temperature of one pound of water by one degree Fahrenheit. The formula to calculate BTUs is: BTUs = weight of water (in pounds) x temperature change (in degrees Fahrenheit) x 1. Alternatively, the formula can be expressed as: BTUs = (Flow rate in gallons per minute x change in temperature in degrees Fahrenheit) / 500.
x BTUs / 3412.141633128 BTUs/KWH = KWH For example: -------------- If you burned 1,000,000 BTUs per month, then calculate the following: 1,000,000 BTUs / 3412.141633128 BTUs/KWH = ~293 KWHs per month Notes: ------- 1. Energy = the capacity/measure of a body/system to do work (expressed as the work that it does in changing to some specified reference state. It is measured in joules (SI units)). 2. 1 Joule = 1 Watt-second 3. 1 BTU = 1055.05585262 Joules (or Watt-seconds) 4. 1 WH (Watt-Hour) = 3.412141633 BTUs created/used in 1 hour = 3600 Joules or Watt-seconds (i.e. 1 Joule or Watt-second created/used every second for 1 hour) 5. 1 KWH = 1000 WH = 3412.141633 BTUs created/used in 1 hour = 3,600,000 Joules or Watt-seconds created/used every hour (i.e. 1000 Joules or Watt-seconds created/used every second for 1 hour) ======================================================== (1 KWH) = (1,000 watt-hour) = (1,000 joule / second) (hour) (BTU / 1055 joule) (3,600 sec / hour) = [ (1,000 x 3,600) / (1,055) ] [ joule - hour - BTU - second / second - joule - hour ] = 3412.3 BTU That's the amount of energy equivalent to 1 KWH . . . . . 3,412.3 BTU.
1 Watt is approximately equal to 3.412 BTUs per hour.
To convert BTUs to kilowatts, you can use the conversion factor where 1 BTU per hour is approximately equal to 0.000293 kilowatts. Therefore, to convert 14,000 BTUs to kilowatts, you multiply 14,000 by 0.000293, which equals approximately 4.1 kilowatts.
To convert ghp hr (gallons per hour) to kWhp hr (kilowatt-hours per hour), you need to know the energy content of the fuel being used, typically measured in BTUs per gallon. First, convert gallons to BTUs using the fuel's specific energy content, then convert BTUs to kilowatt-hours using the conversion factor of 1 kWh = 3,412 BTUs. Finally, you can express the result in kWhp hr.
To calculate the BTUs required to heat 120 gallons of water to 210°F, first determine the temperature rise needed. Assuming the initial water temperature is around 60°F, you would need to raise it 150°F (210°F - 60°F). The BTU calculation is: [ \text{BTUs} = \text{gallons} \times \text{temperature rise} \times 8.34 ] So, [ \text{BTUs} = 120 \text{ gallons} \times 150°F \times 8.34 \approx 1,500,600 \text{ BTUs}. ] To heat this in 2 hours, you would need about 750,300 BTUs per hour.
To calculate the BTUs removed per hour, use the formula: BTUs = flow rate (lbs/min) × temperature change (°F) × 1.0 (specific heat of water). First, convert the flow rate to pounds per hour: 10 lbs/min × 60 min/hour = 600 lbs/hour. Then, calculate the BTUs: BTUs = 600 lbs/hour × 15°F × 1.0 = 9,000 BTUs/hour. Thus, 9,000 BTUs of heat are removed per hour.
A 10-kilowatt heater produces 34,120 BTUs per hour.
To convert watts to BTUs (British Thermal Units), you can use the formula: 1 watt is approximately equal to 3.412 BTUs per hour. So, if you have a certain number of watts, you can multiply that by 3.412 to convert it to BTUs per hour.
A boiler rated at 125 MBH (thousand BTU per hour) has an output of 125,000 BTU per hour. MBH stands for "thousand BTUs per hour," so to convert to BTUs, you simply multiply by 1,000. Therefore, a 125 MBH boiler delivers 125,000 BTUs of heating capacity each hour.
To calculate the BTUs needed to raise the temperature of a 40-gallon water heater by 60 degrees Fahrenheit, you can use the formula: BTUs = gallons × temperature rise × 8.34. For a 40-gallon heater, it would be 40 gallons × 60°F × 8.34 BTU/gallon°F, resulting in approximately 20,016 BTUs. Therefore, it takes about 20,016 BTUs to achieve that temperature increase.
To calculate the BTUs needed to reduce the temperature of 50 gallons of water by 20°F, you can use the formula: BTU = gallons × weight of water (8.34 lbs/gallon) × temperature change (°F). For 50 gallons, that would be 50 × 8.34 × 20 = 8,340 BTUs. Therefore, you need approximately 8,340 BTUs to achieve this temperature reduction.
To convert BTUs to tons, you can use the conversion factor that 1 ton of cooling is equivalent to 12,000 BTUs per hour. Therefore, 18,000 BTUs divided by 12,000 BTUs per ton equals 1.5 tons. So, 18,000 BTUs is equivalent to 1.5 tons of cooling capacity.
To estimate how long a 100-pound propane tank will last with a 15,000 BTU wall heater, you first need to know that propane contains about 91,500 BTUs per gallon, and there are approximately 37 gallons in a 100-pound tank. This results in about 8.8 million BTUs total. If the heater runs continuously at 15,000 BTUs, the tank would last roughly 8.8 million BTUs ÷ 15,000 BTUs/hour = about 586 hours. However, actual usage may vary based on heating cycles and efficiency.
Depends on the BTUs of the heater.
To convert BTUs to horsepower, you can use the conversion factor that 1 horsepower is approximately equal to 2,545 BTUs per hour. Therefore, for 18,000 BTUs, the calculation would be 18,000 BTUs ÷ 2,545 BTUs/hp, which equals about 7.07 horsepower. So, you would need approximately 7.1 hp to provide 18,000 BTUs of cooling or heating.