Slot Harmonics Means
Slot Harmonics High-harmonics are to be determined first, and then the rotor cage high-frequency losses and rotor (stator) core surface losses are calculated. Generally, the 2 most important types of flux density slot harmonics in the induction machines air-gap are: a) Flux density harmonics (Bfh), due to MMF harmonics, produced by the. Harmonics in an Induction Motor Space harmonics fluxes are produced by the windings, slotting, magnetic saturation, inequalities in the air gap length. These harmonic fluxes induce voltages and circulate harmonic currents in the rotor windings.
- Slot Harmonics Means Using
- Slot Harmonics Means Meaning
- Slot Harmonics Means Test
- Slot Harmonics Define
Definition
Distribution factor is defined as the ratio of phasor sum of coil emfs to the arithmetic sum of coil emfs. It is also known as Belt or Breadth factor and denoted by kd.
In electrical machine, armature winding is distributed in the slots. It is not concentrated in a single slot. Therefore the total emf generated across the armature terminal is the phasor sum of emfs induced in individual coils. If these coils were concentrated, then the total induced emf would have been arithmetic sum of induced emf in a single turn of coil. Thus to find the factor of distribution or the degree of distribution of coils, distribution factor has been defined as the ratio of emf induced in distributed winding to the emf induced in concentrated winding. This definition of distribution factor is same stated earlier in the post.
Calculation of Distribution Factor
To get a general expression or formula of distribution factor, let us assume a 2 pole, 3 phase electrical machine having a total of 18 slots in its stator. These slots are distributed along the periphery of stator in 2 pole pitches. Therefore the angle between any two consecutive slots will be equal to 20 degree (2×180 / 18 = 20). This angle between two consecutive slots is called Angular Slot Pitch. It is in electrical degree not in mechanical degree.
Thus angular slot pitch for our example is 20 degree. The number of slots per pole per phase will be 3 [(18/2)/3 = 3]. This means that a particular phase will consists of three coils distributed in three slots under a single pole. This is shown in figure below.
In the above figure it can be seen that, coils are distributed in slot number 1,2,3 and 10,11,12. It can also be observed that, coil sides are connected in series in such a way that emf induced in coil side at 1 and 10 are additive. This means, if E1 and E10 are the emf induced in respective coil sides then the total emf induced will be E1+E10. Similarly, if the emf induced in coil sides 2 and 11 are E2 & E11, then the total emf in coil 2-11 is given as arithmetic sum of E2 and E11.
Thus the total emf at the coil terminal A & B is the phasor sum of (E1+E10), (E2+E11) and (E3+E12). Let us assume (E1+E10) as reference phasor and draw the phasor diagram of the above three emf to get the total emf available at terminal AB.
In the above phasor, ab represents (E1+E10). Since the slots are displaced from each other by angular slot pitch of γ (in our example, it is 20 degree), this means the emf induced in coil 2-11 will be displace by an angle of γ from reference phasor ab. This is shown by ‘bc’ in above phasor. Similarly, ‘cd’ represents the emf induced in coil 3-12 and is displaced by reference phasor by and angle of 2γ.
Thus the total emf across terminals AB of coil will be the phasor sum of ab, bd and cd which is equal to ‘ad’. Let us now calculate this phasor sum.
Since ab, bc and cd are lying in stator slot, therefore their perpendicular bisector must meet at the centre of the circle. Let us now draw perpendicular bisector oe and of on ab and ad respectively as shown in above figure. In general, the angle aob should be equal to angular slot pitch γ, angle aod equal to qγ and angle aof equal to (qγ/2) where q is number of slots per pole per phase.
In right angled triangle aoe,
Sin (γ/2) = ae / oa
ae = oaSin(γ/2)
Thus, ab = 2oaSin(γ/2) as oe is perpendicular bisector of ab.
Therefore, if the coil were concentrated then the emf across coil terminal AB would have been arithmetic sum of emf. This is given as
Emf per coil = Number of slots per pole per phase x 2oeSin(γ/2)
= 2q(oa)Sin(γ/2)
Now, in right angled triangle aof,
Sin(qγ/2) = af / oa
af = (oa)Sin(qγ/2)
Hence the resultant emf ad equal to the phasor sum of ab, bc and cd is given as
ad = 2(oa)Sin(qγ/2)
Therefore as per the definition of distribution factor,
Kd = Phasor Sum of Coil emf / Arithmetic sum of coil emf
Slot Harmonics Means Using
= ad / q ab
= [2(oa)Sin(qγ/2)] / [2q(oa)Sin(γ/2)]
= Sin(qγ/2) / qSin(γ/2)
Thus the formula for distribution factor is given as below.
where q is number of slots per pole per phase and γ is angular slot pitch.
Slot Harmonics Means Meaning
Effect of Harmonics on Distribution Factor
In electrical machine, every effort is made to make the magnetic flux density wave sinusoidal in space. But practically, it is never distributed sinusoidally in space. Rather it contains various harmonics. Out of various harmonics, third harmonic is the most dominant. A third harmonic component of flux density wave may be assumed to be produced by 3 poles as compared to the one pole for fundamental component. In view of this, the angular slot pitch for third harmonic will be 3γ and hence nγ for nth harmonics.
Thus the distribution factor for nth harmonics is given as below.
Normally distribution factor for nth harmonics Kdn is less than Kd. This directly means that the emf generated due to nth harmonic component of flux density wave is less than that generated by fundamental component. Thus distribution of armature winding over the slots reduces the harmonics in generated emf and thus making it to approach the sine wave. This is one of the advantages of distributed winding.
In this article we will discuss about: 1. Definition of Harmonics 2. Harmonic Number (h) 3. Types 4. Causes.
Slot Harmonics Means Test
Definition of Harmonics:
Harmonics are sinusoidal voltages or currents having frequencies that are integer multiples of the frequency at which the supply system is designed to operate.
Harmonics as pure tones making up a composite tone in music. A pure tone is a musical sound of a single frequency, and a combination of many pure tones makes up a composite sound. Sound waves are electromagnetic waves travelling through space as a periodic function of time. Can the principle behind pure music tones apply to other functions or quantities that are time dependent?
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In the early 1800s, French mathematician, Jean Baptiste Fourier formulated that a periodic non-sinusoidal function of a fundamental frequency f may be expressed as the sum of sinusoidal functions of frequencies which are multiples of the fundamental frequency. In our discussions here, we are mainly concerned with periodic functions of voltage and current due to their importance in the field of power quality. In other applications, the periodic function might refer to radiofrequency transmission, heat flow through a medium, vibrations of a mechanical structure, or the motions of a pendulum in a clock.
A sinusoidal voltage or current function that is dependent on time t may be represented by the following expressions:
Voltage function,
v(t) = V sin (ωt) …(4.1)
Current function,
i(t) = I sin (ωt ± θ) …(4.2)
where, ω = 2πf is known as the angular velocity of the periodic waveform and 0 is the difference in phase angle between the voltage and the current waveforms referred to as a common axis. The sign of phase angle θ is positive if the current leads the voltage and negative if the current lags the voltage.
Figure 4.1 contains voltage and current waveforms expressed by Eqs. (4.1) and (4.2) and which by definition are pure sinusoids.
For the periodic non-sinusoidal waveform shown in Fig. 4.2, the simplified Fourier expression states-
V (t) = V0 + V1 sin(ωt) + V2 sin(2 ωt) + V3 sin(3 ωt) + … + Vn sin( n ωt) + Vn+1 sin (( n + 1) ωt) +………….. (4.3)
The Fourier expression is an infinite series. In this equation, V0 represents the constant or the DC component of the waveform.
V1, V2, V3, … , Vn are the peak values of the successive terms of the expression. The terms are known as the harmonics of the periodic waveform. The fundamental (or first harmonic) frequency has a frequency of f, the second harmonic has a frequency of 2 x f, the third harmonic has a frequency of 3 x f, and the nth harmonic has a frequency of n x f. If the fundamental frequency is 60 Hz (as in the U.S.), the second harmonic frequency is 120 Hz, and the third harmonic frequency is 180 Hz.
The significance of harmonic frequencies can be seen in Fig. 4.3. The second harmonic undergoes two complete cycles during one cycle of the fundamental frequency, and the third harmonic traverses three complete cycles during one cycle of the fundamental frequency.
V1, V2, and V3 are the peak values of the harmonic components that comprise the composite waveform, which also has a frequency of f.
The ability to express a non-sinusoidal waveform as a sum of sinusoidal waves allows us to use the more common mathematical expressions and formulas to solve power system problems. In order to find the effect of a non-sinusoidal voltage or current on a piece of equipment, we only need to determine the effect of the individual harmonics and then vectorially sum the results to derive the net effect. Figure 4.4 illustrates how individual harmonics that are sinusoidal can be added to form a non-sinusoidal waveform.
The Fourier expression in Eq. (4.3) has been simplified to clarify the concept behind harmonic frequency components in a nonlinear periodic function. For the purist, the following more precise expression is offered. For a periodic voltage wave with fundamental frequency of-
ω = 2πf,
v(t) = V0 + ∑(ak cos kωt + bk sin k ωr) (for k- 1 to ∞)…(4.4)
Where ak and bk are the coefficients of the individual harmonic terms or components. Under certain conditions, the cosine or sine terms can vanish, giving us a simpler expression. If the function is an even function, meaning f (-t) = f(t), then the sine terms vanish from the expression. If the function is odd, with f (- t) = – f(t) then the cosine terms disappear.
For our analysis, we will use the simplified expression involving sine terms only. It should be noted that having both sine and cosine terms affects only the displacement angle of the harmonic components and the shape of the nonlinear wave and does not alter the principle behind application of the Fourier series. The coefficients of the harmonic terms of a function-
f(t) contained in Eq. (4.4) are determined by- Coefficient
The coefficients represent the peak values of the individual harmonic frequency terms of the nonlinear periodic function represented by f (t).
Harmonic Number (h):
Harmonic number (h) refers to the individual frequency elements that comprise a composite waveform. For example, h = 3 refers to the third harmonic component with a frequency equal to third times the fundamental frequency. If the fundamental frequency is 60 Hz, then the 3rd (third) harmonic frequency is 3 x 60, or 180 Hz. The harmonic number 6 is a component with a frequency of 360 Hz.
Dealing with harmonic numbers and not with harmonic frequencies is done for two reasons. The fundamental frequency varies among individual countries and applications. The fundamental frequency in the U.S. is 60 Hz, whereas in Europe and many Asian countries it is 50 Hz. Also, some applications use frequencies other than 50 or 60 Hz; for example, 400 Hz is a common frequency in the aerospace industry, while some AC systems for electric traction use 25 Hz as the frequency.
The inverter part of an AC adjustable speed drive can operate at any frequency between zero and its full rated maximum frequency, and the fundamental frequency then becomes the frequency at which the motor is operating. The use of harmonic numbers allows us to simplify how we express harmonics. The second reason for using harmonic numbers is the simplification realized in performing mathematical operations involving harmonics.
Types of Harmonics:
Odd and Even Order Harmonics:
Slot Harmonics Define
As their names imply, odd harmonics have odd numbers (e.g., 3, 5, 7, 9, 11), and even harmonics have even numbers (e.g., 2, 4, 6, 8, 10). Harmonic number 1 is assigned to the fundamental frequency component of the periodic wave. Harmonic number 0 represents the constant or DC component of the waveform. The DC component is the net difference between the positive and negative halves of one complete waveform cycle.
Figure 4.5 shows a periodic waveform with net DC content. The DC component of a waveform has undesirable effects, particularly on transformers, due to the phenomenon of core saturation. Saturation of the core is caused by operating the core at magnetic field levels above the knee of the magnetization curve. Transformers are designed to operate below the knee portion of the curve.
When DC voltages or currents are applied to the transformer winding, large DC magnetic fields are set up in the transformer core. The sum of the AC and the DC magnetic fields can shift the transformer operation into regions past the knee of the saturation curve. Operation in the saturation region places large excitation power requirements on the power system. The transformer losses are substantially increased, causing excessive temperature rise. Core vibration becomes more pronounced as a result of operation in the saturation region.
We usually look at harmonics as integers, but some applications produce harmonic voltages and currents that are not integers. Electric arc furnaces are examples of loads that generate non-integer harmonics. Arc welders can also generate non-integer harmonics. In both cases, once the arc stabilizes, the non-integer harmonics mostly disappear, leaving only the integer harmonics.
The majority of nonlinear loads produce harmonics that are odd multiples of the fundamental frequency. Certain conditions need to exist for production of even harmonics. Uneven current draw between the positive and negative halves of one cycle of operation can generate even harmonics. The uneven operation may be due to the nature of the application or could indicate problems with the load circuitry. Transformer magnetizing currents contain appreciable levels of even harmonic components and so do arc furnaces during startup. Sub-harmonics have frequencies below the fundamental frequency and are rare in power systems.
When sub-harmonics are present, the underlying cause is resonance between the harmonic currents or voltages with the power system capacitance and inductance. Sub-harmonics may be generated when a system is highly inductive (such as an arc furnace during startup) or if the power system also contains large capacitor banks for power factor correction or filtering. Such conditions produce slow oscillations that are relatively un-damped, resulting in voltage sags and light flicker.
Causes of Voltage and Current Harmonics:
A pure sinusoidal waveform with zero harmonic distortion is a hypothetical quantity and not a practical one. The voltage waveform, even at the point of generation, contains a small amount of distortion due to non-uniformity in the excitation magnetic field and discrete spatial distribution of coils around the generator stator slots. The distortion at the point of generation is usually very low, typically less than 1.0%.
The generated voltage is transmitted many hundreds of miles, transformed to several levels, and ultimately distributed to the power user. The user equipment generates currents that are rich in harmonic frequency components, especially in large commercial or industrial installations. As harmonic currents travel to the power source, the current distortion results in additional voltage distortion due to impedance voltages associated with the various power distribution equipment, such as transmission and distribution lines, transformers, cables, buses, and so on.
Figure 4.9 illustrates how current distortion is transformed into voltage distortion. Not all voltage distortion, however, is due to the flow of distorted current through the power system impedance. For instance, static uninterruptible power source (UPS) systems can generate appreciable voltage distortion due to the nature of their operation. Normal AC voltage is converted to DC and then reconverted to AC in the inverter section of the UPS. Unless waveform shaping circuitry is provided, the voltage waveforms generated in UPS units tend to be distorted.
As nonlinear loads are propagated into the power system, voltage distortions are introduced which become greater moving from the source to the load because of the circuit impedances. Current distortions for the most part are caused by loads. Even loads that are linear will generate nonlinear currents if the supply voltage waveform is significantly distorted.
When several power users share a common power line, the voltage distortion produced by harmonic current injection of one user can affect the other users. This is why standards are being issued that will limit the amount of harmonic currents that individual power users can feed into the source.
The major causes of current distortion are nonlinear loads due to adjustable speed drives, fluorescent lighting, rectifier banks, computer and data-processing loads, arc furnaces, and so on. One can easily visualize an environment where a wide spectrum of harmonic frequencies are generated and transmitted to other loads or other power users, thereby producing undesirable results throughout the system.