A watt is a unit of power: what is required is probably the amount of energy - which is measured in joules.
The question is so hopelessly confused that I can't even make an answerable question out of what's there.
-- dollars -- weeks -- kilograms -- degrees (of temperature) -- pages -- watts -- decibels -- joules -- lumens
You are confusing the units.If 80 watts can power a device for a second, the same 80 watts can power the same device for a year - assuming the generator, or whatever produces the power, continues working. A watt is a unit of power (energy / time), not a unit of energy. Thus, since you are using units of power, the 16 hours are completely irrelevant to the problem.Nor can you directly compare watts and volts. The relationship is: power = voltage x current. In SI units: watts = volts x amperes. If a device uses less than or equal to 80 watts, your 80 watts will be enough; otherwise they won't. If the specifications of an electrical device only specify volts and amperes, multiply them to get the watts required.
It the unit is watts, megawatts is millions of watts, so to convert watts to megawatts, multiply the number of watts be 1,000,000.
2.4705 watts/hour
1 gallon of water is 4540 cc and 1 degree F is 0.555 degrees C, so raising 4540 cc of water by 0.555 degree C would take 4540x0.555 calories, or 2520 calories. Multiply by 4.2 to convert to joules which gives 10590 joules. Therefore the energy required is 10590 joules which is the same as 10590 watt-seconds. That could be done by 100 watts in 105.9 seconds, or 1000 watts in 10.59 seconds.
Watts= rate of using energy Amps= current flow Think of it as a bucket of water with a hole in it. Watts is the amount of water leaking from the bucket (1 gallon) Amps is the size of the hole ( it took 3 minutes for that 1 gallon to leak out of the bucket)
A watt is a unit of power: what is required is probably the amount of energy - which is measured in joules.
it all depends on the amount of water you can usually get by with a 10 gallon heater
The amount of energy required to convert water to steam depends on the specific heat of water, latent heat of vaporization, and the mass of water. With the given information, it is not possible to provide an accurate estimate of the wattage required for the process. The rate at which the energy is applied also plays a crucial role in determining the wattage needed for such a conversion.
Well, the question your asking is basically impossible. It's like asking to convert a gallon of water into cans of pop. It is possible to convert the gallon of water into cans of water not soda. So you can convert dBm to watts, not dBi.
Well, the question your asking is basically impossible. It's like asking to convert a gallon of water into cans of pop. It is possible to convert the gallon of water into cans of water not soda. So you can convert dBm to watts, not dBi.
0.29308323563892147 watts per btu there for 5200 btu = 1524.0328253223915 watts 1 watt=3.412Btu/hr 1 Btu=the amount of energy needed to heat 1 Lb of water 1 degree. A gallon of water weighs aprox. 8 Lbs.
The amount of energy required to freeze water depends on the initial temperature of the water and the desired final temperature (0°C for freezing water). To calculate the power in watts needed to freeze water, you would need to know the mass of water, its initial temperature, and the time over which you want to freeze it.
Degrees and watts are not directly convertible because they are different units of measurement. Degrees usually measure temperature or angle, while watts measure power. If you are trying to convert temperature to watts for a specific application, you would need to use a relevant formula or conversion factor based on the specific context.
The conversion factor of 1 BTU = 0.293 watts. So, 60,000 * 0.293 watts = 17,580 watts. 17580 watts are required to run a craftsman 60,000 btu propane forced air heater.