Application of the Principle of Virtual Work in the Determination of Force and Torque

S

J· dS. (1.72)

Inside the area under observation, when a closed line integral according to Equation (1.71) is written only for the areaS (<S), the flux of a flux tube in a current-carrying area becomes

Φ^= µ0l

h b

_

SJ· dS (1.73)

and thus, in that case, if (h/b)^= (h/b), then in fact Φ^< Φ. If the current density J in the current-carrying area is constant,Φ^= ΦS/S is valid. When crossing the bound-ary between a current-carrying slot and currentless iron, the flux of the flux tube cannot change. Therefore, the dimensions of the line grid have to be altered. When J is constant and

Φ^= Φ, Equations (1.72) and (1.73) yield for the dimensions in the current-carrying area

h b

_

= Sh

Sb. (1.74)

This means that near the indifference point d the ratio (h/b) increases. An orthogonal field dia-gram can be drawn for a current-carrying area by correcting the equivalent linear current den-sity by iterating the created diagram. For a current-carrying area, gradient lines are extended from potential lines up to the indifference point. Now, bearing in mind that the gradient lines have to divide the current-carrying area into sections of equal size, next the orthogonal flux lines are plotted by simultaneously paying attention to changing dimensions. The diagram is altered iteratively until Equation (1.74) is valid to the required accuracy.

1.4 Application of the Principle of Virtual Work in the Determination of Force and Torque

When investigating electrical equipment, the magnetic circuit of which changes form during operation, the easiest method is to apply the principle of virtual work in the estimation of force and torque. Examples of this kind of equipment are double-salient-pole reluctant machines, various relays and so on.

Faraday’s induction law presents the voltage induced in the winding, which creates a current that tends to resist the changes in flux. The voltage equation for the winding is written as

u = Ri +dΨ

dt = Ri + d

dtLi, (1.75)

where u is the voltage connected to the coil terminals, R is the resistance of the winding and Ψ is the coil flux linkage, and L the self-inductance of the coil consisting of its magnetizing inductance and leakage inductance: L= Ψ /i = NΦ/i = N²Λ = N²/Rm(see also Section 1.6).

If the number of turns in the winding is N and the flux isΦ, Equation (1.75) can be rewritten as

u= Ri + NdΦ

dt . (1.76)

The required power in the winding is written correspondingly as

ui = Ri²+ NidΦ

dt , (1.77)

and the energy

dW = P dt = Ri²dt+ Ni dΦ. (1.78)

The latter energy component Ni dΦ is reversible, whereas Ri²dt turns into heat. Energy cannot be created or destroyed, but may only be converted to different forms. In isolated systems, the limits of the energy balance can be defined unambiguously, which simplifies the energy analysis. The net energy input is equal to the energy stored in the system. This result, the first law of thermodynamics, is applied to electromechanical systems, where electrical energy is stored mainly in magnetic fields. In these systems, the energy transfer can be represented by the equation

dWel= dWmec+ dWΦ+ dWR (1.79)

where

dWelis the differential electrical energy input, dWmecis the differential mechanical energy output, dW_Φis the differential change of magnetic stored energy, dWRis the differential energy loss.

Here the energy input from the electric supply is written equal to the mechanical energy together with the stored magnetic field energy and heat loss. Electrical and mechanical energy have positive values in motoring action and negative values in generator action. In a magnetic system without losses, the change of electrical energy input is equal to the sum of the change of work done by the system and the change of stored magnetic field energy

dW_el= dWmec+ dW_Φ, (1.80)

dWel= ei dt. (1.81)

In the above, e is the instantaneous value of the induced voltage, created by changes in the energy in the magnetic circuit. Because of this electromotive force, the external electric circuit converts power into mechanical power by utilizing the magnetic field. This law of energy conversion combines a reaction and a counter-reaction in an electrical and mechanical

Φ R

F i

u

x

N turns F_Φ

Ψ, e

Figure 1.14 Electromagnetic relay connected to an external voltage source u. The mass of a moving yoke is neglected and the resistance of the winding is assumed to be concentrated in the external resistor R. There are N turns in the winding and a fluxΦ flowing in the magnetic circuit; a flux linkage Ψ ≈ NΦ is produced in the winding. The negative time derivative of the flux linkage is an emf, e. The force F pulls the yoke open. The force is produced by a mechanical source. A magnetic force F_Φtries to close the air gap

system. The combination of Equations (1.80) and (1.81) yields

dW_el= ei dt = dΨ

dt i dt= i dΨ = dWmec+ dW_Φ. (1.82) Equation (1.82) lays a foundation for the energy conversion principle. Next, its utilization in the analysis of electromagnetic energy converters is discussed.

As is known, a magnetic circuit (Figure 1.14) can be described by an inductance L deter-mined from the number of turns of the winding, the geometry of the magnetic circuit and the permeability of the magnetic material. In electromagnetic energy converters, there are air gaps that separate the moving magnetic circuit parts from each other. In most cases – because of the high permeability of iron parts – the reluctance Rmof the magnetic circuit consists mainly of the reluctances of the air gaps. Thus, most of the energy is stored in the air gap. The wider the air gap, the more energy can be stored. For instance, in induction motors this can be seen from the fact that the wider is the gap, the higher is the magnetizing current needed.

According to Faraday’s induction law, Equation (1.82) yields

dWel= i dΨ. (1.83)

The computation is simplified by neglecting for instance the magnetic nonlinearity and iron losses. The inductance of the device now depends only on the geometry and, in our example, on the distance x creating an air gap in the magnetic circuit. The flux linkage is thus a product

of the varying inductance and the current

Ψ = L(x)i. (1.84)

A magnetic force F_Φis determined as

dW_mec= F_Φdx. (1.85)

From Equations (1.83) and (1.85), we may rewrite Equation (1.80) as

dW_Φ = i dΨ − F_Φdx. (1.86)

Since it is assumed that there are no losses in the magnetic energy storage, dW_Φis deter-mined from the values ofΨ and x. dWΦis independent of the integration path A or B, and the energy equation can be written as

W_Φ(Ψ0, x0)=

With no displacement allowed (dx= 0), Equations (1.86) now (1.87) yield

W_Φ(Ψ, x0)=

Ψ

0

i (Ψ, x0)dΨ. (1.88)

In a linear system,Ψ is proportional to current i, as in Equations (1.84) and (1.88). We there-fore obtain

The magnetic field energy can also be represented by the energy density w_Φ = WΦ/V = B H/2 [J/m³] in a magnetic field integrated over the volume V of the magnetic field. This gives

Assuming the permeability of the magnetic medium constant and substituting B = µH gives

This yields the relation between the stored energy in a magnetic circuit and the electrical and mechanical energy in a system with a lossless magnetic energy storage. The equation for differential magnetic energy is expressed in partial derivatives

dW_Φ(Ψ, x) = ∂WΦ

∂Ψ dΨ +∂WΦ

∂x dx. (1.92)

SinceΨ and x are independent variables, Equations (1.86) and (1.92) have to be equal at all values of dΨ and dx, which yields

i =∂W_Φ(Ψ, x)

∂Ψ , (1.93)

where the partial derivative is calculated by keeping x constant. The force created by the electromagnet at a certain flux linkage levelΨ can be calculated from the magnetic energy

F_Φ = −∂WΦ(Ψ, x)

∂x . (1.94a)

The minus sign is due to the coordinate system in Figure 1.14. The corresponding equation is valid for torque as a function of angular displacementθ while keeping flux linkage Ψ constant

T_Φ= −∂WΦ(Ψ, θ)

∂θ . (1.94b)

Alternatively, we may employ coenergy (see Figure 1.15a), which gives us the force directly as a function of current. The coenergy W_Φ^ is determined as a function of i and x as

W_Φ^ (i, x) = iΨ − WΦ(Ψ, x) . (1.95)

B

0 i 0 H

Ψ

energy density

coenergy density coenergy

(a) (b) (c)

0 i

Ψ

energy energy

coenergy

W' W'

W x, const. W ^{x, co}

nst.

Figure 1.15 Determination of energy and coenergy with current and flux linkage (a) in a linear case (L is constant), (b) and (c) in a nonlinear case (L saturates as a function of current). If the figure is used to illustrate the behaviour of the relay in Figure 1.14, the distance x remains constant

In the conversion, it is possible to apply the differential of iΨ

d(iΨ ) = i dΨ + Ψ di. (1.96)

Equation (1.95) now yields

dW_Φ^ (i, x) = d (iΨ ) − dW_Φ(Ψ, x) . (1.97) By substituting Equations (1.86) and (1.96) into Equation (1.97) we obtain

dW_Φ^ (i, x) = Ψ di + F_Φdx. (1.98) The coenergy W_Φ^ is a function of two independent variables, i and x. This can be represented by partial derivatives

dW_Φ^ (i, x) = ∂W_Φ^

∂i di+∂W_Φ^

∂x dx. (1.99)

Equations (1.98) and (1.99) have to be equal at all values of di and dx. This gives us Ψ = ∂W_Φ^ (i, x)

∂i , (1.100)

F_Φ =∂W_Φ^(i, x)

∂x . (1.101a)

Correspondingly, when the current i is kept constant, the torque is

T_Φ= ∂W_Φ^(i, θ)

∂θ . (1.101b)

Equation (1.101) gives a mechanical force or a torque directly from the current i and dis-placement x, or from the angular disdis-placement θ. The coenergy can be calculated with i and x

W_Φ^ (i₀, x0)=

i

0

Ψ (i, x0)di. (1.102)

In a linear system,Ψ and i are proportional, and the flux linkage can be represented by the inductance depending on the distance, as in Equation (1.84). The coenergy is

W_Φ^ (i, x) =

i

0

L (x)i di =1

2L (x) i². (1.103)

Using Equation (1.91), the magnetic energy can be expressed also in the form

W_Φ=



V

1

2µH²dV. (1.104)

In linear systems, the energy and coenergy are numerically equal, for instance 0.5Li² = 0.5Ψ²/L or (µ/2)H² = (1/2µ)B². In nonlinear systems, Ψ and i or B and H are not pro-portional. In a graphical representation, the energy and coenergy behave in a nonlinear way according to Figure 1.15.

The area between the curve and flux linkage axis can be obtained from the integral i dΨ , and it represents the energy stored in the magnetic circuit W_Φ. The area between the curve and the current axis can be obtained from the integralΨ di, and it represents the coenergy W_Φ^. The sum of these energies is, according to the definition,

W_Φ+ W_Φ^ = iΨ. (1.105)

In the device in Figure 1.14, with certain values of x and i (orΨ ), the field strength has to be independent of the method of calculation; that is, whether it is calculated from energy or coenergy – graphical presentation illustrates the case. The moving yoke is assumed to be in a position x so that the device is operating at the point a, Figure 1.16a. The partial derivative in Equation (1.92) can be interpreted as WΦ/x, the flux linkage Ψ being constant and

x → 0. If we allow a change x from position a to position b (the air gap becomes smaller), the stored energy change−WΦ will be as shown in Figure 1.16a by the shaded area, and the energy thus becomes smaller in this case. Thus, the force F_Φis the shaded area divided by

x when x → 0. Since the energy change is negative, the force will also act in the negative x-axis direction. Conversely, the partial derivative can be interpreted asW_Φ^

x, i being constant andx → 0.

Ψ Ψ

0 i 0 i

a a

b b

c

initial state x, const.

after displ.

after displ.

initial state x, const.

x

x− x− x

Ψ

WΦ

− + W'^Φ

i

(a)Ψ is constant, i decreases (b) i is constant, flux linkage increases

Figure 1.16 Influence of the changex on energy and coenergy: (a) the change of energy, when Ψ is constant; (b) the change of coenergy, when i is constant

The shaded areas in Figures 1.16a and b differ from each other by the amount of the small triangle abc, the two sides of which arei and Ψ . When calculating the limit, x is allowed to approach zero, and thereby the areas of the shaded sections also approach each other.

Equations (1.94) and (1.101) give the mechanical force or torque of electric origin as partial derivatives of the energy and coenergy functions W_Φ(Ψ, x) and W_Φ^ (x, i).

Physically, the force depends on the magnetic field strength H in the air gap; this will be studied in the next section. According to the study above, the effects of the field can be repre-sented by the flux linkageΨ and the current i. The force or the torque caused by the magnetic field strength tends to act in all cases in the direction where the stored magnetic energy de-creases with a constant flux, or the coenergy inde-creases with a constant current. Furthermore, the magnetic force tends to increase the inductance and drive the moving parts so that the reluctance of the magnetic circuit finds its minimum value.

Using finite elements, torque can be calculated by differentiating the magnetic coenergy W^ with respect to movement, and by maintaining the current constant:

T = ldW^

In numerical modelling, this differential is approximated by the difference between two suc-cessive calculations:

T =l

W^(α + α) − W^(α)

α . (1.107)

Here, l is the machine length andα represents the displacement between successive field solutions. The adverse effect of this solution is that it needs two successive calculations.

Coulomb’s virtual work method in FEM is also based on the principle of virtual work. It gives the following expression for the torque:

T =

where the integration is carried out over the finite elements situated between fixed and moving parts, having undergone a virtual deformation. In Equation (1.108), l is the length, J denotes the Jacobian matrix, dJ/dϕ is its differential representing element deformation during the displacement dϕ, |J| is the determinant of J and d |J| /dϕ is the differential of the determinant, representing the variation of the element volume during displacement dϕ. Coulomb’s virtual work method is regarded as one of the most reliable methods for calculating the torque and it is favoured by many important commercial suppliers of FEM programs. Its benefit compared with the previous virtual work method is that only one solution is needed to calculate the torque.

Figure 1.17 Flux solution of a loaded 30 kW, four-pole, 50 Hz induction motor, the machine rotating counterclockwise as a motor. The figure depicts a heavy overload. The tangential field strength in this case is very large and produces a high torque. The enlarged figure shows the tangential and normal components of the field strength in principle. Reproduced by permission of Janne Nerg

In document Rotating Electrical Machines (Page 54-62)