Monday, December 2, 2013

Electric Energy Transfer in AC form


This post is a continuation of the last past <What really AC (Alternate Current) and Power are ?>.

Electric Energy - wiki (05-Dec-2013)

Electrical energy is energy newly derived from electrical potential energy. When loosely used to describe energy absorbed or delivered by an electrical circuit (for example, one provided by an electric power utility) "electrical energy" refers to energy which has been converted from electrical potential energy. This energy is supplied by the combination of electric current and electrical potential that is delivered by the circuit. At the point that this electrical potential energy has been converted to another type of energy, it ceases to be electrical potential energy. Thus, all electrical energy is potential energy before it is delivered to the end-use. Once converted from potential energy, electrical energy can always be described as another type of energy (heat, light, motion, etc.).

words by words 

<newly> -  may indicate some sense of time and have special meaning but can be deleted with no significant difference. 
This energy is supplied by the combination of electric current and electrical potential
By using a formula this can be express electric current (I) and electrical potential (V), ie, I x V = Power. And Energy = Power x Time.
<this electrical potential energy has been converted to another type of energy, it ceases to be electrical potential energy.>

Now back to the last post





We then consider the resistor as the resistance value of the the whole system of the right hand side. This whole system may consist of  several actual Resistors, Capacitors, Inductors, Diodes, Transistor, ICs, etc and consume Electrical Power or Energy (Energy is Power x Time) to do something for you. Now we consider the power consumed by this one system Resistor.

Power = I x V
                                                                                                               
You may know that in terms of Power AC or DC does not matter as
P = I^2 R = \frac{V^2}{R},

<At the point that this electrical potential energy has been converted to another type of energy, it ceases to be electrical potential energy.>

<At the point> - what point ?
this electrical potential energy> - what does <this> mean ?

< all electrical energy is potential energy before it is delivered to the end-use.>

 These statements seem to contradict <return path> in the last post as all the potential energy seem to be consumed in the circuit.

All (or some) returns ? or only one way and never return ? Which is correct ? Both are wrong.

Consider the amount of current at 1)  the (2nd winding ) upper line (as hot wire) and 2) the center tap wire (as the neutral wire), the current must be the same. I = V/R.  Even when V or R or both change (which is common) I at the above two locations (more precisely at the same points) always the same or more precisely become the same instantly and continuously.

Again, 

Still a big question remains - how actually and exactly Electrical Energy is transferred from a power station to a household in a big picture and how Energy (reached a household) is transferred from the inlet to the power consuming home appliance(s) in a small picture? Either in a big picture or small picture the basic behavior of Electric Energy Transfer may be the same.

Introduction of Electromagnetic Filed

Electromagnetic Filed - wiki (05-Dec-2013)

Electromagnetic field as a feedback loop- wiki

The behavior of the electromagnetic field can be resolved into four different parts of a loop:
  • the electric and magnetic fields are generated by electric charges,
  • the electric and magnetic fields interact with each other,
  • the electric and magnetic fields produce forces on electric charges,
  • the electric charges move in space.
A common misunderstanding is that (a) the quanta of the fields act in the same manner as (b) the charged particles that generate the fields. In our everyday world, charged particles, such as electrons, move slowly through matter, typically on the order of a few inches (or centimeters) per second[citation needed], but fields propagate at the speed of light - approximately 300 thousand kilometers (or 186 thousand miles) a second. The mundane speed difference between charged particles and field quanta is on the order of one to a million, more or less. Maxwell's equations relate (a) the presence and movement of charged particles with (b) the generation of fields. Those fields can then affect the force on, and can then move other slowly moving charged particles. Charged particles can move at relativistic speeds nearing field propagation speeds, but, as Einstein showed[citation needed], this requires enormous field energies, which are not present in our everyday experiences with electricity, magnetism, matter, and time and space.
The feedback loop can be summarized in a list, including phenomena belonging to each part of the loop:
  • charged particles generate electric and magnetic fields
  • the fields interact with each other
    • changing electric field acts like a current, generating 'vortex' of magnetic field
    • Faraday induction: changing magnetic field induces (negative) vortex of electric field
    • Lenz's law: negative feedback loop between electric and magnetic fields
  • fields act upon particles
    • Lorentz force: force due to electromagnetic field
      • electric force: same direction as electric field
      • magnetic force: perpendicular both to magnetic field and to velocity of charge
  • particles move
    • current is movement of particles
  • particles generate more electric and magnetic fields; cycle repeats

The underline is made by me. I have found some articles mentioning this misunderstanding but most of them do not show satisfactory "correct" understanding. The feedback theory of this wiki explanation is also not so satisfactory (or rather confusing to me) and did not say anything about AC, which is actually used in our daily lives.

1) charged particles, such as electrons, move slowly through matter, typically on the order of a few inches (or centimeters) per second[citation needed]  

You can find some citations in some websites.

Speed of electricity - Wiki (05-Dec-2013)

Electric drift
 
The drift velocity deals with the average velocity that a particle, such as an electron, gets due to an electric field. In general, an electron will 'rattle around' in a conductor at the Fermi velocity randomly.[3] Free electrons in a conductor vibrate randomly, but without the presence of an electric field there is no net velocity. When a DC voltage is applied the electrons will increase in speed proportional to the strength of the electric field. These speeds are on the order of millimeters per hour. AC voltages cause no net movement; the electrons oscillate back and forth in response to the alternating electric field.[4]


Propagation Times
http://www.ultracad.com/articles/propagationtime.pdf

Speed of Electricity
http://www.cartage.org.lb/en/themes/sciences/physics/Electromagnetism/Electrostatics/ElectricCurrent/Mysteryofelectric/Mysteryofelectric.htm



2) Maxwell's equations relate (a) the presence and movement of charged particles with (b) the generation of fields.

This is a big issue and complicated too. At least you master Gradient, Divergence and Curl to some extent.

Maxwell's Equations - wiki (05-Dec-2013)

Maxwell's equations describe how electric and magnetic fields are generated and altered by each other and by charges and currents.

The equations have two major variants. The "microscopic" set of Maxwell's equations uses total charge and total current, including the complicated charges and currents in materials at the atomic scale; it has universal applicability, but may be unfeasible to calculate. The "macroscopic" set of Maxwell's equations defines two new auxiliary fields that describe large-scale behavior without having to consider these atomic scale details, but it requires the use of parameters characterizing the electromagnetic properties of the relevant materials.

(Simple summary:  The Maxwell's equations have two major variants - "microscopic"and "macroscopic")

Vector calculus formalism

Throughout this article, symbols in bold represent vector quantities, and symbols in italics represent scalar quantities, unless otherwise indicated.
To describe electromagnetism in the powerful language of vector calculus, the Lorentz force law defines the electric field E, a vector field, and the magnetic field B, a pseudovector field, where each generally have time-dependence. The sources of these fields are electric charges and electric currents, which can be expressed as the total amounts of electric charge Q and current I within a region of space, or as local densities of these - namely charge density ρ and current density J.
In this language there are four equations. Two of them describe how the fields vary in space due to sources, if any; electric fields emanating from electric charges in Gauss's law, and magnetic fields as closed field lines not due to magnetic monopoles in Gauss's law for magnetism. The other two describe how the fields "circulate" around their respective sources; the magnetic field "circulates" around electric currents and time varying electric fields in Ampère's law with Maxwell's correction, while the electric field "circulates" around time varying magnetic fields in Faraday's law.

(Simple summary:  the electric field E - source - electric charges and the  magnetic field B - source - electric currents ((each generally have time-dependence)), which can be expressed as the total amounts of electric charge Q and current I within a region of space, or as local densities of these - namely charge density ρ and current density J.)

(Please note that Power and Energy (Power x Time) are scalar and The E and B fields are vectors. And Maxwell's equations are vector equations)

Conventional formulation in SI units  - "microscopic"

Name Integral equations Differential equations
Gauss's law \oiint{\scriptstyle\partial \Omega }\mathbf{E}\cdot\mathrm{d}\mathbf{S} = \frac{1}{\varepsilon_0} \iiint_\Omega \rho \,\mathrm{d}V \nabla \cdot \mathbf{E} = \frac {\rho} {\varepsilon_0}
Gauss's law for magnetism \oiint{\scriptstyle \partial \Omega }\mathbf{B}\cdot\mathrm{d}\mathbf{S} = 0 \nabla \cdot \mathbf{B} = 0
Maxwell–Faraday equation (Faraday's law of induction) \oint_{\partial \Sigma} \mathbf{E} \cdot \mathrm{d}\boldsymbol{\ell}  = - \frac{d}{dt} \iint_{\Sigma} \mathbf{B} \cdot \mathrm{d}\mathbf{S} \nabla \times \mathbf{E} = -\frac{\partial \mathbf{B}} {\partial t}
Ampère's circuital law (with Maxwell's correction) \oint_{\partial \Sigma} \mathbf{B} \cdot \mathrm{d}\boldsymbol{\ell} = \mu_0 \iint_{\Sigma} \left(\mathbf{J} + \varepsilon_0 \frac{\partial \mathbf E}{\partial t} \right)\cdot \mathrm{d}\mathbf{S} \nabla \times \mathbf{B} = \mu_0\left(\mathbf{J} + \varepsilon_0 \frac{\partial \mathbf{E}} {\partial t} \right)
There are universal constants appearing in the equations; in this case the permittivity of free space ε0 and the permeability of free space μ0, a general characteristic of fundamental field equations.
In the differential equations, a local description of the fields, the nabla symbol ∇ denotes the three-dimensional gradient operator, and from it ∇· is the divergence operator and ∇× the curl operator. The sources are taken to be as local densities of charge and current.
In the integral equations; a description of the fields within a region of space, Ω is any fixed volume with boundary surface ∂Ω, and Σ is any fixed open surface with boundary curve ∂Σ. Here "fixed" means the volume or surface do not change in time. Although it is possible to formulate Maxwell's equations with time-dependent surfaces and volumes, this is not actually necessary: the equations are correct and complete with time-independent surfaces. The sources are correspondingly the total amounts of charge and current within these volumes and surfaces, found by integration. The volume integral of the total charge density ρ over any fixed volume Ω is the total electric charge contained in Ω:
Q = \iiint_\Omega \rho \, \mathrm{d}V\,,
and the net electrical current is the surface integral of the electric current density J, passing through any open fixed surface Σ:
I = \iint_{\Sigma} \mathbf{J} \cdot \mathrm{d} \mathbf{S}\,,
where dS denotes the differential vector element of surface area S normal to surface Σ. (Vector area is also denoted by A rather than S, but this conflicts with the magnetic potential, a separate vector field).
The "total charge or current" refers to including free and bound charges, or free and bound currents. These are used in the macroscopic formulation below.

--- end of quote

Let's take one by one (but only differential equations)

\nabla \cdot \mathbf{E} = \frac {\rho} {\varepsilon_0}

(Gauss's Law)

This equation states the relation between E (Electric field) and Charges under the conditions of  "microscopic", static (not dynamic related with time) and vacuum (permittivity of free space ε0)  The conditions are not very realistic, far from AC (the value changing with time). Anyway, we go on.

The right hand side is the divergence of E (Electric field). Since the divergence is the (3-dimesional) differentiation we see what is happening at a certain point (each or every point) of E (Electric field) and in terms of vector. As E (Electric field) is (a vector of the collection of ) every point vector the result becomes a scalar, So the right hand side should also scalar.

The right hand side is charge density ρ divided by permittivity of free space ε0. What does this mean ?

Charge desity = Cherges / Volume (3D). Q/V(Volume). In this case a very small volume (an infinitesimal volume). Charge is very small so we can count them even in an infinitesimal volume. The unit is Coulomb / m3 (cubic).

Permitivity. A bit difficult to understand.

Permitivity- wiki (05-Dec-2013)

In electromagnetism, absolute permittivity is the measure of the resistance that is encountered when forming an electric field in a medium. In other words, permittivity is a measure of how an electric field affects, and is affected by, a dielectric medium. The permittivity of a medium describes how much electric field (more correctly, flux) is 'generated' per unit charge in that medium. More electric flux exists in a medium with a high permittivity (per unit charge) because of polarization effects.

---- end of quote

<the measure of the resistance that is encountered when forming an electric field in a medium>.

The resistance here is like an inertia against status quo. To change the mechanical status que you need something like force. In the case of permitivity something should be additional voltage difference.

<The permittivity of a medium describes how much electric field (more correctly, flux) is 'generated' per unit charge in that medium.>

In this case <a medium> is vacuum (free space). <per unit charge> is very microscopic and this relates with  charge density ρ of the right hand side of the equation.

Or we could say

(Permittivity is the electric flux density in a body divided by the Electric Field strength (E) which created the flux. It is the quantity of a mediam that allows it (the medium) to store a Electric field (Energy ?))

< (more technically, flux)>

Does <more technically> have any special meaning, here ?

Electric flux is not a flow of charges (which is current). To understand the meaning of the right had side of the equation (or Maxwell's Equations in general) we need to know the concept of Electric flux - fictitious but having the unit (volt metres (V m)).

Electric flux - wiki (05-Dec-2013)

In electromagnetism, electric flux is the rate of flow of the electric field through a given area (*1). Electric flux is proportional to the number of electric field lines (*2) going through a virtual surface. If the electric field is uniform, the electric flux passing through a surface of vector area S is

\Phi_E = \mathbf{E} \cdot \mathbf{S} = ES \cos \theta,
where E is the electric field (having the unit of V/m), E is its magnitude, S is the area of the surface, and θ is the angle between the electric field lines and the normal (perpendicular) to S. For a non-uniform electric field, the electric flux dΦE through a small surface area dS is given by
d\Phi_E = \mathbf{E} \cdot d\mathbf{S}
(the electric field, E, multiplied by the component of area perpendicular to the field). The electric flux over a surface S is therefore given by the surface integral:
\Phi_E = \iint_S \mathbf{E} \cdot d\mathbf{S}

where E is the electric field and dS is a differential area on the closed surface S with an outward facing surface normal defining its direction.
For a closed Gaussian surface, electric flux is given by:
\Phi_E =\,\!\oiint\scriptstyle S\mathbf{E}\cdot d\mathbf{S} = \frac{Q}{\epsilon_0}\,\!
where
E is the electric field,
S is any closed surface,
Q is the total electric charge inside the surface S,
ε0 is the electric constant (a universal constant, also called the "permittivity of free space") (ε0 ≈ 8.854 187 817... x 10−12 farads per meter (F·m−1)).
This relation is known as Gauss' law for electric field in its integral form and it is one of the four Maxwell's equations.

It is important to note that while the electric flux is not affected by charges that are not within the closed surface, the net electric field, E, in the Gauss' Law equation, can be affected by charges that lie outside the closed surface. While Gauss' Law holds for all situations, it is only useful for "by hand" calculations when high degrees of symmetry exist in the electric field. Examples include spherical and cylindrical symmetry.
Electrical flux has SI units of volt metres (V m), or, equivalently, newton meters squared per coulomb (N m2 C−1). Thus, the SI base units of electric flux are kg·m3·s−3·A−1.
Its dimensional formula is [L3MT–1I–1].

--- end of quote

(*1) Electric flux is the rate of flow of the electric field through a given area.

This is wrong as "flux" is not a flow (despite the name) and so not the rate of flow either. Electric flux is static presence of the electric field through a given area. However it reminds us of the definition of electric current - the rate of flow of the charges through a given area.

(*2) as the field line is fictitious the number of field lines is also fictitious.

\Phi_E =\,\!\oiint\scriptstyle S\mathbf{E}\cdot d\mathbf{S} = \frac{Q}{\epsilon_0}\,\!

You can see Q/ε0 in the right hand side of this equation, similar to the right hand side of our original equation

\nabla \cdot \mathbf{E} = \frac {\rho} {\varepsilon_0}

where  charge density ρ. Q is the total electric charge inside the surface S (i.e. the total Charges in a volume, not a small volume as this is an integral equation while our original equation is a differential one.


  ------

Let's look at the following Capacitor equation.

I(t) = C \frac{\mathrm{d}V(t)}{\mathrm{d}t}.
When the voltage over a capacitor (across the two plates) does not change with time the derivative is zero so I is zero. We can think of a special time when a non-charged capacitor becomes charged only once (the voltage do not change after it is fully charged). Now the derivative is not zero so during this special period I changes with time too, that is, the current flows. Please note that in this case (capacitor equation with I and V) I (the does not relate with the value of V but the rate change of V with time.

Meanwhile we can use this equation as checking the electrical units.

Permittivity of a capacitor (of vacuum)

C = \frac{\varepsilon A}{d}
A = Area of one of the two plates of a capacitor (the area of the both plates are considered to be equal and exactly face to face at 90 deg.)
d = distance of the two plate

So unit wise

C =   ε x m x m / m --->   ε x  m

therefore

ε  = C / m

Meanwhile from the equation

I(t) = C \frac{\mathrm{d}V(t)}{\mathrm{d}t}.


I = CV/t  ----> Q/t = CV/t   ---->   Q = CV

So  C = Q /V

To put into ε  = C / m

ε  = Q / Vm

 The 1st Maxwell's equation of differential form is

\nabla \cdot \mathbf{E} = \frac {\rho} {\varepsilon_0}

where ρ is Charge density, Q / m x m x m

so the right hand side becomes

Q / m x m x m
----------------          ---> V / m x m
Q / Vm (in vacuum)

and the left hand side is a differentiation of E (Electric Field vector) in 3D space so the unit is also V / m x m. So unit wise the Maxwell's equation is correct. But what does this mean ?

Charge density (ρ)  is in a way the strength of Charges and the more Charges per unit volume the stronger. ε is a value of Q / Vm, which indicates the ration of Q to Vm - how many Charges per Vm, or the relation between Q and Vm. If Vm is constant the higher ε  the more Charges.

Vm is Electric Flux.




sptt


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