If You Are Asking Which Will Cost Less. That Is Say A Motor ( Dual Voltage ) It Will Cast The Same To Operate On 110V As It Will 220 Volts. Reason You Only Pay For Killowatts. Watts And Voltage Are Two Different things. If You Will Look On Name Tag Of Said Item You Will Find Amperage At A Given Voltage. example 110V 10 amp == 220v 5 amp Volts X Amps = Watts in either equation you are using 1100 watts. So You Will Pay The Same Price For Usage Of Said Unit. If Whatever You Are Running And It Was Built To Run On Either Voltage, The Cost Will Be The Same. Will It Run As Efficient ? It Should If It Was Designed To Run On Either Voltage. HOPE THIS HELPS
The main difference is the amount of power that can be delivered: 240 volts can deliver more power compared to 120 volts. Additionally, using 240 volts may require different outlets and wiring compared to 120 volts. The choice between the two voltages depends on the specific electrical requirements of the devices or appliances being used.
About 120 volts, Clever! Typically, the only difference to wiring something 120 vs 240 is the power factor of the unit. The larger the power requirement the more beneficial the higher the voltage rating becomes, in as far as installation costs are concerned mostly. The higher the voltage is the less the current is, which allows you to use smaller wire and equipment. Ex. a 1500w/120v hair dryer may draw close to 13 amps, while at 240v around 6.25. The less CURRENT the smaller the wire, breaker, disconnect...ect. The running/operating costs roughly, remains the same however.
Neither of these voltages "consumes more power" because a Voltage does not "consume" anything!
The voltage supplied by a source of power (like a battery or a generator) has to be multiplied by the current drawn from that source to give the power (measured in Watts) consumed by an appliance. An amount of voltage in electricity is often described as being similar to the height of a column of water above the ground in hydraulics. It may help if you think of a water reservoir up in the hills containing billions of gallons of water: The "potential difference" of a reservoir's supply of water power is measured by the height of the water, measured infeet or meters, that the water comes out at above its return level. The return level is often the average sea level.
Similarly: The "potential difference" of a source of electricity is the height of electrical potential, measured in Voltsthat exists between the supply wire coming from the source of electricity and its return wire.
For Direct Current (DC) the supply wire is usually called the Positive or "+" wire and the return wire is called the Negative or "-" wire.
For Alternating Current (AC) the supply wire is often called either the "Hot" or the "Live" wire and the return wire is called the "Neutral" wire.
It is also interesting to mention that Negative and Neutral wires are often - but not always - connected to Earth using a separate "Ground" or "Earth" wire.
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120 volts is used in Canada, 110 in the USA, 240 in the UK and Australia, 230 in Europe. 120 is less lethal than 240, but needs twice the amperage for a given task.
AnswerNorth America uses a split-phase system, in which the 240-V secondary winding of a distribution transformer is centre-tapped and earthed (grounded) to providing the neutral connection. This provides a supply voltage of 240 V across the outer terminals of the secondary winding, and 120 V between either outer terminal and the neutral terminal. Thus residences are supplied with a dual-voltage system: 240 V for heavy appliances (e.g. ranges, dryers) and 120 V for normal loads (receptacles, lighting circuits).
Most other countries use distribution Transformers with a two-terminal secondary winding, which provide just one supply voltage: 240 V in some countries, and 230 V in the UK and mainland Europe.
Yes, some models of Onan generators have the capability to output 240 volts. Make sure to check the specifications of the specific generator model you are using to confirm if it can provide 240 volts.
No, it is not possible to use 240 volts with a 120 volt supply directly. You would need a transformer to step up the voltage from 120 volts to 240 volts. Attempting to use 240 volts with a 120 volt supply without a transformer can damage equipment and pose a safety hazard.
Seeing that the question comes from North America the most common duplex receptacle has 110 - 120 volts potential to ground. The second most common potential difference is 220 - 240 volts. These voltages are obtained from a 120/240 volt system common to home connections from the local utility companies.
If you measure the voltage between the hot wire (480V) and the ground using a meter, the reading should be close to 480 volts. Ground is typically considered to be at 0 volts potential, so the voltage difference between the hot wire and ground should be around 480 volts.
When you multiply amps x volts the product is watts. Using this formula W = Amps x Volts should give you your answer.
voltage is the PUSH on electrons seriously 120 volts is the difference of 240...Simply said 240 volts is 2 times as strong as 120 volts.
One has an element designed to work on 120 volts, the other has an element designed to work on 240 volts.
Yes, some models of Onan generators have the capability to output 240 volts. Make sure to check the specifications of the specific generator model you are using to confirm if it can provide 240 volts.
It is simply a product of standardization.
No, it is not possible to use 240 volts with a 120 volt supply directly. You would need a transformer to step up the voltage from 120 volts to 240 volts. Attempting to use 240 volts with a 120 volt supply without a transformer can damage equipment and pose a safety hazard.
Seeing that the question comes from North America the most common duplex receptacle has 110 - 120 volts potential to ground. The second most common potential difference is 220 - 240 volts. These voltages are obtained from a 120/240 volt system common to home connections from the local utility companies.
In the USA it is usually 120/208 or 120/240 volts In Europe I think it's 220 volts
240 watts at 120 volts requires 2 amperes. Power = voltage * current
If that is the information that is stated on the nameplate of the device then yes it will operate on 120 volts.
If you measure the voltage between the hot wire (480V) and the ground using a meter, the reading should be close to 480 volts. Ground is typically considered to be at 0 volts potential, so the voltage difference between the hot wire and ground should be around 480 volts.
30 amps.
In North America 120/240 is the main voltages used. It is known as a three wire system. L1 to L2 supplies 240 volts. L1 to N supplies 120 volts and L2 to N supplies 120 volts.