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Why would you be charged for Energy cost and recovery on your electric bill?
Wiki User
∙ 16y ago
You should call your electric company for an explanation. Basically, without knowing your location, it looks like ECR (Energy Cost & Recovery) provides for the recovery of defined energy cost. It is combined for billing purposes with the charges in the applicable rate and shown as a single line item on the bill to the customer. In English, it looks like the ECR is a way for a utility to recover from unexpectedly high expenses for providing service. There is usually a state commission that has to approve the charge. I found some reference to this being charged to wholesale customers, so you might also enquire about that.
Wiki User
∙ 16y ago
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How is a circuit formed?
The amount of electric potential energy per unit of charge that would be possessed by a charged object if placed within an electric field at a given location.See related links below.
Does an electric can opener convert electric energy sound energy?
Not likely - any machine wastes some energy; that would reduce the useful output energy.
What force fields would be felt by a stationary charged object?
Newtonian gravitational field and an electric field. If it were moving then it would feel a magnetic field.
What type of field would deflect alpha and beta particles?
A magnetic field would deflect both alpha and beta particles, as would a charged electric field.
What is the electric field outside a charged spherical shell?
The electric field outside the shell is the same as it would be if all the charge of the shell was concentrated as a point charge in the centre of the shell.
Why are hybrid cars better than electric cars?
If electric cars are charged using renewable energy then they are better than hybrid cars, because hybrids still burn some fossil fuels. However, electric cars charged with fossil fuel energy would not be better than hybrid cars.
What Electrical potential energy?
Electric potential is like electric potential energy, except electric potential energy requires that you have at least two charged particles: one charged particle (can be considered to be stationary) to produce the electric field and another charged particle to be affected by that electric field. If both charged particles are positively charged, then when you move the nonstationary charged particle closer to the stationary charged particle, potential energy of the system increases, because the charged particles naturally want to repel. However, let's say you remove that nonstationary charged particle and are left with just the single charged particle. There is no more potential energy in the system, because there is no other charged particle to be acted upon by the electric field. However, the single charged particle still emits an electric field. This field is what creates "electric potential." Even though there is no second particle in the system, if you were to place a second particle into the system (let's call it a test particle), its potential energy would be equal to the electric potential multiplied by the charge of the test particle. U = kq1q2/r (electric potential energy with 2 charges, where the 0 of potential energy is infinitely far away) V = kq1/r (electric potential requiring only 1 charge) V = U/q2 (electric potential is potential energy without the second charge) U = Vq2 (electric potential energy is electric potential multiplied by second charge) There is also a concept called gravitational potential, where it's gravitational potential energy divided by the test mass. It can be a negatively charged particle. In that case, electric potential decreases as you get closer to the negatively charged particle. Even though electric potential decreases, if you have two negatively charged particles, electric potential energy increases as you move the 2nd negative charge closer to the first charge. This is because multiplying 2 negative charges makes a positive: U = k(-q1)*(-q2)/r = kq1q2/r (assuming q1 and q2 are the charge magnitudes) So in this case, it's a little weird because that's how the math works. Nature has a tendency to reduce potential energy, but potential is different and doesn't work the same way. However if the test charge was positive, the sign of electric potential energy will be the same as electric potential with respect to location. V = k(-q1)/r = -kq1/r U = k(-q1)(q2)/r = -kq1q2/r Potential energy is not the same as potential! They are related, but don't get them confused. Energy is measured in Joules. Potential is measured in Volts. Completely different units. Volts = Number of Joules / Number of Coulombs. Electric Potential = Electric Potential Energy / Charge of Test Particle
What has potential energy?
Potential energy is a energy stored within a system as a result of the position or configuration of the different parts of that system.The types of potential energy are gravitational potential energy, which is energy due to height, and elastic potential energy, which is energy involved with a stretched or compressed spring.
What does electrical potential mean?
Electric potential is like electric potential energy, except electric potential energy requires that you have at least two charged particles: one charged particle (can be considered to be stationary) to produce the electric field and another charged particle to be affected by that electric field. If both charged particles are positively charged, then when you move the nonstationary charged particle closer to the stationary charged particle, potential energy of the system increases, because the charged particles naturally want to repel. However, let's say you remove that nonstationary charged particle and are left with just the single charged particle. There is no more potential energy in the system, because there is no other charged particle to be acted upon by the electric field. However, the single charged particle still emits an electric field. This field is what creates "electric potential." Even though there is no second particle in the system, if you were to place a second particle into the system (let's call it a test particle), its potential energy would be equal to the electric potential multiplied by the charge of the test particle. U = kq1q2/r (electric potential energy with 2 charges, where the 0 of potential energy is infinitely far away) V = kq1/r (electric potential requiring only 1 charge) V = U/q2 (electric potential is potential energy without the second charge) U = Vq2 (electric potential energy is electric potential multiplied by second charge) There is also a concept called gravitational potential, where it's gravitational potential energy divided by the test mass. It can be a negatively charged particle. In that case, electric potential decreases as you get closer to the negatively charged particle. Even though electric potential decreases, if you have two negatively charged particles, electric potential energy increases as you move the 2nd negative charge closer to the first charge. This is because multiplying 2 negative charges makes a positive: U = k(-q1)*(-q2)/r = kq1q2/r (assuming q1 and q2 are the charge magnitudes) So in this case, it's a little weird because that's how the math works. Nature has a tendency to reduce potential energy, but potential is different and doesn't work the same way. However if the test charge was positive, the sign of electric potential energy will be the same as electric potential with respect to location. V = k(-q1)/r = -kq1/r U = k(-q1)(q2)/r = -kq1q2/r Potential energy is not the same as potential! They are related, but don't get them confused. Energy is measured in Joules. Potential is measured in Volts. Completely different units. Volts = Number of Joules / Number of Coulombs. Electric Potential = Electric Potential Energy / Charge of Test Particle
How electrical potential produce?
Electric potential is like electric potential energy, except electric potential energy requires that you have at least two charged particles: one charged particle (can be considered to be stationary) to produce the electric field and another charged particle to be affected by that electric field.If both charged particles are positively charged, then when you move the nonstationary charged particle closer to the stationary charged particle, potential energy of the system increases, because the charged particles naturally want to repel.However, let's say you remove that nonstationary charged particle and are left with just the single charged particle. There is no more potential energy in the system, because there is no other charged particle to be acted upon by the electric field. However, the single charged particle still emits an electric field. This field is what creates "electric potential." Even though there is no second particle in the system, if you were to place a second particle into the system (let's call it a test particle), its potential energy would be equal to the electric potential multiplied by the charge of the test particle.U = kq1q2/r (electric potential energy with 2 charges, where the 0 of potential energy is infinitely far away)V = kq1/r (electric potential requiring only 1 charge)V = U/q2 (electric potential is potential energy without the second charge)U = Vq2 (electric potential energy is electric potential multiplied by second charge)There is also a concept called gravitational potential, where it's gravitational potential energy divided by the test mass.It can be a negatively charged particle. In that case, electric potential decreases as you get closer to the negatively charged particle. Even though electric potential decreases, if you have two negatively charged particles, electric potential energy increases as you move the 2nd negative charge closer to the first charge. This is because multiplying 2 negative charges makes a positive:U = k(-q1)*(-q2)/r = kq1q2/r (assuming q1 and q2 are the charge magnitudes)So in this case, it's a little weird because that's how the math works. Nature has a tendency to reduce potential energy, but potential is different and doesn't work the same way.However if the test charge was positive, the sign of electric potential energy will be the same as electric potential with respect to location.V = k(-q1)/r = -kq1/rU = k(-q1)(q2)/r = -kq1q2/rPotential energy is not the same as potential! They are related, but don't get them confused. Energy is measured in Joules. Potential is measured in Volts. Completely different units.Volts = Number of Joules / Number of Coulombs.Electric Potential = Electric Potential Energy / Charge of Test Particle
How is a circuit formed?
The amount of electric potential energy per unit of charge that would be possessed by a charged object if placed within an electric field at a given location.See related links below.
What is Photoelectric device?
In simple terms, we would look at the word broken down into roots. We have photo and electric. Photo means energy given by light, and electric means energy made through charged particles. Therefore, Photoelectric device would be a device that it's powered by electricity generated by light. An example would be your ordinary calculator. The solar strip at the top is a photoelectric device.
Is it true the strength of the electric field of a charged particle becomes greater as the distance from the particles increases?
I really doubt it. If it were, then the strength of the electric field from a charged particle on the far side of the Andromeda Galaxy would be totally unbearable, and it would be completely impossible to stick a charged balloon to the wall in my house.
If the electric fields of two charged objects form a closed pattern of field lines how are the objects charged?
They would be "oppositely" charged. In other words, one object would need to be positive and the other would need to be negative.
Does an electric can opener convert electric energy sound energy?
Not likely - any machine wastes some energy; that would reduce the useful output energy.
Where would you find electric energy?
In an elecrical socket.
What is better a solar or electric powered car?
I would say solar because it could run all day when it is light out, and pretty long at night since the energy is stored into the solar panels. Electric powered cars have to be charged and you don't get to many hours out the charging.
