The amperage required to run a computer and monitor can vary depending on their power consumption. A typical desktop computer consumes around 3-6 amps, while a monitor can use around 1-2 amps. It's important to check the specifications of your specific devices to determine the exact amperage they require.
The Shop-vac 6 has 8.4 amps and has been a popular vaccuum for many years in shops and in homes as well! This particular one got above average reviews and it doesn't use too much power to run efficiently.
In the electrical trade the only time there is a reference to start and running amps is when dealing with motors. The running amps is always lower than the starting amps. A 78 amp electric furnace will take a 100 amp service for it to operate and be within the electrical code guide lines.
First the amperage of the 1500 watt device has to be established. I = W/E. Amps = Watts /Volts = 1500/24 = 62.5 amps. To answer this question the amp/hour rating of the 24 volt battery has to be stated. This is the capacity rating of the battery. Take that rating and divide it by 62.5 amps will give you the amount of hours that the battery will take before it drains and needs to be recharged.
A 60-watt lightbulb typically draws 0.5 amps of current when connected to a 120-volt power supply. This is calculated using the formula: Current (in amps) = Power (in watts) / Voltage (in volts).
Minimal 100. Depends on load draw of home. Can be 200 amps or 400 amps as well.
To answer this question the voltage needs to be known.
22o voltage
The amperage required to run a computer and monitor can vary depending on their power consumption. A typical desktop computer consumes around 3-6 amps, while a monitor can use around 1-2 amps. It's important to check the specifications of your specific devices to determine the exact amperage they require.
2,4789
None.
The formula you are looking for is W = I x E, Watts = Amps x Volts.
A 1,000 watt inverter giving 110 volts is rated at 9 amps.
A 1450 watt coffee maker will use around 13 amps at 110 volts.
Batteries are not measured in Amps, but rather as Amps they can emit in an hour. The standard home unit for battery power is AH our Ampere Hour.At 12 volts the amps in your battery are then described in Ampere Hours or Amps per hour.From that we get that if the battery was plugged into a 12v device that drew 225 amps, your battery would run out in 1 hour.Similarly if it was connected to a device requiring 112.5 amps it would take 2 hours to run down.Wikipedia has stated that this is an approximation, that at really high currents (measured in how many Amps you are currently using) the battery life is shorter than expected and that the Ampere hour is generally supposed to consider a 20 hour cycle of discharge(therefore meaning lower amps per hour)This brings the battery back to it's "normal" drainage pattern.@ 12v and 11.25A your battery would take 20 hours to drain.
The formula for amperage is I = W/E. Amps = Watts/Volts. As you can see there are two values missing from the question.
The Shop-vac 6 has 8.4 amps and has been a popular vaccuum for many years in shops and in homes as well! This particular one got above average reviews and it doesn't use too much power to run efficiently.