There is insufficient information to peform the calculation. The key information required would be the flow rate.
This is because the flow rate could be anything for a given pressure (say 80psi) therefore the pressure value alone is insufficient for determination.
between 20000 and 37000 liters per hour
flow rate (gph gpm lph lpm) is how many units (gallon/liters) the pump can move in a specific rate of time. pressure is measured in psi (pounds per square inch). this comes into play when you are moving fluids beond 1ft called the pumps "head" or the distant the pump can move a fluid strait up. most pond pumps have a head height of 3-4ft where high pressure (psi) pumps, such as a fuel pump can move the same liters 15ft strait up. a 5psi pump with a flow rate of 1gpm can move water 12" high at a rate of 1 gallon of fluids in 1 minute (not real values just an explanation) where as a 50psi pump with a rate of 1gpm can force a fluid 25ft up at a rate of 1 gallon per minute the viscosity and diamiter of plumbing also affect these values you will get a higher head rate and increase psi with a smaller diamiter outlet than a larger but a larger diamiter outlet will decrese psi (head) but increase the flow (gpm,gph, lpm,lph)
1 liter per second is equal to 3.6 cubic meters per hour.
The measurement for an air pump typically refers to its pressure output, which is often expressed in pounds per square inch (PSI), bar, or kPa. Additionally, the volume flow rate can be measured in liters per minute (L/min) or cubic feet per minute (CFM), indicating how much air the pump can deliver over time. Other important dimensions may include the physical size of the pump and its weight, depending on its intended use.
As a rough rule of thumb, you can assume you will burn one third of a liter of fuel per kilowatt-hour generated. With a reasonable degree of instrumentation on a battery of 600kw diesel generators, we measured fuel flow vs power generated, and got a factor of .287 liters per kilowatt hour. These were relatively new generators powering a fairly level load. If the engines are smaller, if the load fluctuates, if the engines have high operating hours, the factor will increase.
To calculate the flow rate in liters per minute, first convert 25 seconds to minutes by dividing by 60 (25 seconds / 60 = 0.4167 minutes). Then, divide the volume (4 liters) by the time in minutes (0.4167 minutes) to get the flow rate: 4 liters / 0.4167 minutes ≈ 9.6 liters per minute.
To convert gallons per hour to liters per second, you can use the conversion factors: 1 gallon = 3.78541 liters and 1 hour = 3600 seconds. First convert 5.750 gallons to liters: 5.750 gallons * 3.78541 liters/gallon = 21.763 liters. Then, convert hours to seconds: 1 hour/3600 seconds. Finally, divide the liters by the seconds to get liters per second: 21.763 liters / 3600 seconds ≈ 0.00604 liters per second.
2 to 3 liters.
2/3 * 0.15 mols over liters times seconds, or 0.1 mols over liters times seconds.
40 litres of oil / 5 litres cans = 8 cans can be filled with 40 litres of oil.
1.615 litres
30 litres of petrol are filled because you're talking about more than one litre (plural).
An E cylinder typically holds around 680 liters of oxygen when filled to its working capacity at a pressure of 2,200 psi. This can vary slightly based on the manufacturer and filling pressure.
60 seconds in a minute, so multiply by 60.
A scuba tank typically holds about 11 liters of air at atmospheric pressure.
You don't. Liters is a unit of volume, atmospheres is a unit of pressure.
12