In electricity, voltage is analogous to water pressure. Just as water pressure drives water through pipes, voltage drives electric current through a circuit. Higher voltage means a greater potential for current to flow, similar to how higher water pressure results in a stronger flow of water.
Just make a physics model of the properties which are associated with electricity but are tangible in the real world. I.e. the water analogy of electricity. Water pressure is voltage, electrical current is analogous to water flow rate and a restriction in a water pipe could be resistance. but it is important that this is only a model for certain circumstances and will break down if you try to carry the analogy too far.
No, air does - electricity does not.
"Yes we can" , unless you use a electric pump to transfer the water directly to your house. Usually there will be a raised reservoir to store water (raised to provide pressure). Therefore (normally) electricity is not needed when you open the tap unless the reservoir is empty. Hope this helped!
Water, when in contact with electricity, conducts the electricity to spread throughout the water instantly cause major electricity flow throughout the water. Water conducts electricity making it dangerous.
The exhaust system of your automobile is analogous.
Voltage in an electric circuit is analogous to water pressure in a pipe. Voltage is the force that drives electric current through a circuit, similar to how water pressure pushes water through a pipe.
Moving water and electricity are related through the principle of hydropower, where flowing water is used to generate electricity. In a hydroelectric power plant, the kinetic energy of moving water spins turbines, which then convert this mechanical energy into electrical energy. Additionally, both water and electricity can exhibit similar behaviors in terms of flow and pressure, such as in fluid dynamics and electrical circuits, where they can be analyzed using analogous principles.
5kV means 5 kilovolts or 5,000 volts. Electricity is analogous to water flowing through a pipe. Voltage is water pressure, current is water flow. Resistance is the resistance of the hose to the flow of water. The larger the hose, the less resistance and the more flow you can move with the least amount of pressure.
No, it uses water pressure.
Volts(v) x Amps (a) = Watts (w) voltage is analogous to water pressure and amperage is analogous to water volume, so wattage is analogous to cu.ft. per minute.
Just make a physics model of the properties which are associated with electricity but are tangible in the real world. I.e. the water analogy of electricity. Water pressure is voltage, electrical current is analogous to water flow rate and a restriction in a water pipe could be resistance. but it is important that this is only a model for certain circumstances and will break down if you try to carry the analogy too far.
Electrical pressure is called "electro-motive force" (EMF). It is measured in volts. Pressure and the quantity of electricity transmitted can be considered analogous to pressure and quantity of water flowing in pipes: the longer the distance, the higher is the pressure (called the "voltage" for electricity) that is necessary to pump the flow of water (called the "flow of electrical charge, which is also known as the "electric current"). That is why, for long distance transmission, high pressure (voltage for electricity) is required, failing which, the current - and therefore the power - will not reach the intended destination. Instead, it will be lost (also called "dissipate") along the way. We can think of electrical current as the quantity of electricity which will be drawn from the pipeline (= cables for electricity) at the pressure (= voltage) required.
When the water here is like a dam, water weight creates pressure on water depth. The term refers to the pressure of the hydraulic turbine driven generators and electricity is produced and run. The water flow of electricity is produced. Electricity can be generated from tidal water. Hydraulic fluid power is used.
Yes. If you compare the effect water pressure has on flow rates and from an open tap, more pressure allows more water to flow out of and away from the source. In electrical circuitry, an increase in voltage - say from a battery - will in most cases enable a larger current to flow around the circuit that the battery is connected to. Voltage can be seen as the pressure force pushing another quantity around the loop and that quantity is electrical current . Electrical pressure and the quantity of electricity transmitted can be considered analogous to water flowing in pipes. Electrical pressure is called voltage: the longer the distances, the higher is the pressure (voltage) required to pump the current. That is why, for long distance transmission, high pressure (voltage here) is required, failing which, the power will not reach the destined end. It will dissipate on the way. <><><> We can think of electrical current as the quantity of electricity which will be drawn from the pipeline (= cables for electricity) at the pressure (= voltage) required.
One of two ways: 1. Drop large amounts of water through turbines (generators) and electricity is created in the turbine windings. 2. Press water at high pressure through micro-tubes in a disk of glass. A small amount of electricity is generated. But, it takes electricity to pump the water up to high pressure, so no new energy can be created.
gallons per minute could be considered analogous to amperes
A lot of water and pressure is needed to create a small amount of electricity. In many places, its not a viable solution.