The present invention relates to a synchronous generator and a synchronous generator system driven by a windmill.
In order to use an AC-excited synchronous generator in a wind power generation system, it is essential to reduce the weight of the AC-excited synchronous generator as compared with the conventional counterparts. The requirement for weight reduction comes from the following reason. When a wind power generation system is constructed, the generator must be lifted up to the nacelle by a crane. In a wind power generation system using a large-sized windmill, the nacelle is located at more than 100 m above the ground level. Since the strength and therefore the diameter of the pillar for supporting the windmill is determined by the weight of the generator, the reduction of the weight of the generator is taken into much more consideration for the wind power generation system than for other types of power generation systems.
One way of reducing the weight of an AC-excited synchronous generator is to reduce the length of the air gap between the stator and the rotor. Reducing the air-gap length leads to reducing the magnetic resistance in the air gap so that the exciting current flowing through the field winding can be decreased. Accordingly, the cross section area of the conductor of the field winding can be diminished so that the resultant generator can be decreased in size and weight.
However, if the air-gap length is reduced, the spatial change in the magnetic resistance in the air gap becomes large due to the existence of slots in the stator and rotor so that the distortion of the armature current waveform is enhanced.
JP-A-3-270664 discloses a technique which is designed to improve the armature current waveform, wherein the numbers of the slots in the stator and rotor and the winding pitches for the stator and rotor are optimized to improve the waveform.
JP-A-7-15901 discloses a technique designed for improving the armature current waveform, wherein the winding pitches are so chosen that the winding factors relating to the slot-associated higher harmonics can be minimized.
JP-A-2005-304271 discloses a technique for suppressing the distortion of the armature current waveform by equating to ±6 the number of slots per two poles in stator minus the number of slots per two poles in rotor.
According to the technique disclosed in JP-A-3-270664, the stator winding is in the form of a fractional-slot winding so as to smooth the waveform of the output voltages. However, the effect of reducing the distortion of the armature current waveform is sometimes small in a rotary electric machine with fractional-slot stator winding.
The AC-excited synchronous generator generally has the same structure as conventional wound-rotor type induction machines. And the techniques disclosed in JP-A-7-15901 and JP-A-2005-304271 both employ the values recommended in the design of conventional induction machines which are disclosed in the article “Transformers, Induction machines and AC commutator machines”, Communicational Education Group of IEEJ, p. 112, 1967. Accordingly, the value indicating the number of slots per two poles in the stator minus the number of slots per two poles in the rotor is set between +6 and −6. On the other hand, the inventors of the present invention have revealed the fact that the influence by the higher harmonics in the armature current waveform seems to decrease as the absolute quantity of this value becomes larger. It, therefore, seems to be considered that the influence by the higher harmonics in the armature current waveform cannot be sufficiently suppressed, that is, the armature current waveform cannot be sufficiently smoothed, if this value is maintained between +6 and −6.
The object of the present invention is to provide an AC-excited synchronous generator which can reduce the distortion of the armature current waveform and such an AC-excited synchronous generator for use in a wind power generation system.
According to the present invention, there is provided a synchronous generator comprising a rotor in the plural slots of which the field winding is embedded, and a stator in the plural slots of which the armature winding is embedded, wherein the number of slots per two poles in the stator minus the number of slots per two poles in rotor is equal to or greater than +9, or equal to or smaller than −9.
Other objects, features and advantages of the invention will become apparent from the following description of the embodiments of the invention taken in conjunction with the accompanying drawings.
Embodiments of the present invention will be described below in reference to the attached drawings.
The first embodiment of the present invention will be described below. In the first embodiment of the present invention, the armature current waveform is smoothed by controlling the value indicating the number of slots per two poles in the stator minus the number of slots per two poles in the rotor.
The armature winding 13 comprises bottom coil sides 131, top coil sides 132 and coil ends 133. The coil ends 133 electrically connect the bottom coil sides 131 and the top coil sides 132.
The stator 10 has the bottom coil sides 131 and the top coil sides 132 inserted in the stator slots 12 cut in a stator iron core 11 and immobilized by means of stator wedges 14. In the example shown in
The rotor 20 has a field winding 23 inserted in rotor slots 22 cut in an armature iron core 21 and immobilized by means of rotor wedges 24. The rotary shaft 25 is fitted in the rotor iron core 21. As shown in
With the AC-excited synchronous generator 1, power generation is performed, that is, armature current is caused to flow through the armature winding 13, by rotating the shaft 25 by rotational force imparted thereto while exciting current is flowing through the field winding 23. The frequency of the generated armature current varies depending on the rotational speed of the rotor 20 and also on the frequency of the exciting current flowing through the field winding 23. Even in the case where a windmill drives the rotor shaft 25 as in a wind power generation system and therefore the rotational speed of the rotor 20 continually changes, the frequency of the generated current can be maintained at a fixed value by controlling the frequency of the exciting current flowing through the field winding 23.
[Three-Phase Rotary Electric Machine]
Now, description is made of how a three-phase rotary electric machine is designed. The article extracted from “Electric Machinery (I)” of Applied Electrical Engineering Treatise, by Sakutaro Nonaka, published by Morikita Publishing Co. Ltd., p. 227 (1973), recommends, in the design of a three-phase rotary electric machine, that the number Npp of slots per pole per phase in either of the stator or the rotor should be set within a range given by the following inequality (1).
3≦Npp≦7 (1)
[Value of N1−N2]
Concrete description will now be made of the value of N1−N2.
It is recommended in the design of an induction machine to set the total number n1 of slots in the stator and the total number n2 of slots in the rotor within a range given by the following inequality (2) which is described in “Transformers, Induction machines and AC commutator machines”, Communicational Education Group of IEEJ, p. 112, 1967.
0.80n1≦n2≦1.25n1 (2)
The value of N1−N2 ranges between +6 and −6 when calculated under the condition given by the above inequality (2). In general, since AC-excited synchronous generators are almost the same in structure as wound-rotor type induction machines, they have been designed employing the above recommended value of N1−N2.
Namely, in the design of AC-excited synchronous generators, the value of N1−N2 has been generally set between +6 and −6 in accordance with the condition given by the above inequality (2).
[Derivation of Expression for Giving Current Flowing Through Armature Winding]
The expression for giving the armature current I flowing through the armature winding 13 will now be derived. Here, the expression for giving the armature current I is derived in simplified consideration of phase-related effects. First, let the magneto-motive force (mmf) AT associated with the frequency components of the armature current I flowing through the armature winding be represented by the following expression (3).
where x is fixed to the stator coordinate system and takes a value of 2π per two poles; ωo is the angular frequency corresponding to synchronous speed; t is the time; k is the order of mmf; and fwk is the stator windings factor for the k-th harmonic wave.
The stator windings factor fwk is given by the following expressions (4), (5) and (6).
fwk=fpk×fdk (4)
fpk=sin(pkπ/2) (5)
fdk=sin(kπ/2q)/(n×sin(kπ/2Nsppq)) (6)
where fpk is the short-pitch winding factor for the stator; fdk is the distributed winding factor for the stator; p is the ratio of the armature winding pitch to the stator pole pitch; q is the number of phases in the stator; and Nspp is the number of slots per pole per phase in the stator.
Let the spatial distribution P of permeance, which is the reciprocal of magnetic resistance, be represented by the following expression (7), with the spatial change in the magnetic resistance due to the slots in the rotor and stator taken into consideration.
P∝(1+K1 cos N1x)×(1+K2 cos N2(x−(1−s)ωot)) (7)
where K1 is the factor of pulsation of permeance due to stator slots, K2 is the factor of pulsation of permeance due to rotor slots, and s is the slip. The magnetic flux density B is proportional to the product of the magneto-motive force AT and the permeance P, and can be represented by the following expression (8).
B∝AT×P (8)
The magnetic flux density B is then spatially integrated, and if the short-pitch winding factor of the stator is taken into consideration, the magnetic flux Φ linking the armature winding 13 is assumed to be given by the following expression (9).
Φ∝B×fpkB/kB (9)
where kB is the order of the spatial higher harmonic of the magnetic flux density B, and fpkB is the stator short-pitch winding factor for the kB-th harmonic of the magnetic flux density B.
The magnetic flux Φ is then temporally integrated, and the electro-motive force E induced in the armature winding 13 is assumed to be represented by the following expression (10).
E∝(B×fpkB/kB)×vB (10)
where vB is the order of the time-dependent higher harmonic of the magnetic flux density B.
If the armature current I is assumed to be equal to (induced electro-motive force E)/(reactance) and if the reactance is assumed to be proportional to the order vB of the time-dependent higher harmonic of the magnetic flux density B, then the armature current I can be assumed to be given by the following expression (11).
I∝((B×fpkB/kB)×vB)/vB=AT×P×fpkB/kB (11)
The relationship shown in
The inventors of the present invention have derived the expressions given below, paying attention to higher harmonic components related to the value of N1−N2.
If the expressions (3) and (7) given above are substituted into the last given expression (11) and if only the higher harmonic component with respect to the value of N1−N2 is considered, then, in the case where N1>N2, the expression (11) can be modified into the expression (12) as follows.
On the other hand, for N1<N2, the expression (11) can be modified into the expression (13) as follows.
From the expressions (12) and (13), it is understood that the pulsation of the output current results from the higher harmonic components attributable to the value of N1−N2.
As seen from
Accordingly, in order to suppress the distortion of the armature current waveform, it is required to choose the number of slots in such a manner that the value of N1−N2 is greater than +6 or smaller than −6, as is outside the range recommended with the above inequality (2).
Further, it is understood from
[Combinations of Number of Slots Per Pole Per Phase in Stator and Number of Slots Per Pole Per Phase in Rotor]
Consideration will now be given, in this embodiment, to the values of N1−N2 for the following four different combinations of the number of slots per pole per phase in the stator and the number of slots per pole per phase in the rotor.
COMBINATION 1: Case where the number of slots per pole per phase in the stator is an integer and the number of slots per pole per phase in the rotor is also an integer.
COMBINATION 2: Case where the number of slots per pole per phase in the stator is a fraction and the number of slots per pole per phase in the rotor is an integer.
COMBINATION 3: Case where the number of slots per pole per phase in the stator is an integer and the number of slots per pole per phase in the rotor is a fraction.
COMBINATION 4: Case where the number of slots per pole per phase in the stator is a fraction and the number of slots per pole per phase in the rotor is also a fraction.
[Combination 1]
In this combination, the number of slots per pole per phase in the stator is an integer and the number of slots per pole per phase in the rotor is also an integer.
In this case, it is seen from
As is apparent from
Further, if the number Npp of slots per pole per phase in a three-phase rotary electric machine is an integer, the three-phase windings of the rotary electric machine are of integral-slot winding. Since coil winding work becomes simplest in the case where the number Npp of slots per pole per phase is an integer in either of the stator and the rotor, that is, in this case of COMBINATION 1, cost reduction can be expected in this case.
COMBINATION 1 is the case where the number of slots per pole per phase in the stator is an integer and the number of slots per pole per phase in the rotor is also an integer. To be more concrete, in the AC-excited synchronous generator shown in
[Combination 2]
In this combination, the number of slots per pole per phase in the stator is a fraction and the number of slots per pole per phase in the rotor is an integer.
In this case, it is seen from
As is apparent from
If the number Npp of slots per pole per phase in a three-phase rotary electric machine is not an integer, the three-phase windings of the rotary electric machine are of fractional-slot winding.
[Combination 3]
In this combination, the number of slots per pole per phase in the stator is an integer and the number of slots per pole per phase in the rotor is a fraction.
In this case, it is seen from
As is apparent from
Since the number of slots per pole per phase in the stator is an integer when the number of slots per pole per phase in the rotor is a fraction, then the winding factor corresponding to the order of higher harmonic equal to the value of N1−N2 does not occur, that is, the higher harmonic current component generated due to the value of N1−N2 is reduced to zero. Accordingly, the armature current waveform can be smoothed to a greater extent.
COMBINATION 3 is the case where the number of slots per pole per phase in the stator is an integer and the number of slots per pole per phase in the rotor is a fraction. To be more concrete, the number of slots in the stator is 108, the number of slots in the rotor is 81, the number of poles is 6, and the number of phases is 3. In this case, the number of slots per pole per phase in the stator is 6 and the number of slots per pole per phase in the rotor is 4.5. Also, the number N1 of slots per two poles in stator is 36, the number N2 of slots per two poles in rotor is 27, and the value of N1−N2 is 9. Accordingly, as seen from
In this EMBODIMENT 1-3, the number of slots in the stator is 72, the number of slots in the rotor is 54, the number of poles is 4, and the number of phases is 3. In this case, the number of slots per pole per phase in the stator is 6 and the number of slots per pole per phase in the rotor is 4.5. Also, the number N1 of slots per two poles in stator is 36, the number N2 of slots per two poles in rotor is 27, and the value of N1−N2 is 9. Accordingly, as seen from
[Combination 4]
In this combination, the number of slots per pole per phase in the stator is a fraction and the number of slots per pole per phase in the rotor is also a fraction.
In this case, it is seen from
As is apparent from
The second embodiment of the present invention will be described below. In the second embodiment, the armature current waveform is smoothed to a greater extent by setting within a range described later the ratio of armature winding pitch to stator pole pitch, for the AC-excited synchronous generator (with the value of N1−N2 greater than +9 or smaller than −9).
Accordingly, if the ratio of the armature winding pitch to the stator pole pitch is equated to 80% in the AC-excited synchronous generator with the value of N1−N2 equal to ±12, the armature current can be smoothed.
The AC-excited synchronous generator as the embodiment 2-1 is so constructed as shown in
In the exemplary case of the AC-excited synchronous generator shown in
Even in the case where a given AC-excited synchronous generator has a number of slots and a number of poles which are different from those of the AC-excited synchronous generator shown as the embodiment 2-1 in
Let it be assumed in
If the armature winding pitch is assumed to take values given in the table in
Although only AC-excited synchronous generators wherein the number Nspp of slots per pole per phase in the stator is such that 3≦Nspp≦7, the number of poles is equal to or less than 12, and the number of slots in the stator is equal to or less than 144, are shown in
Alternatively, maintaining the ratio of the field winding pitch to the rotor pole pitch within a range of 77.8%˜88.9% can also lead to the reduction in the magnitudes of the higher harmonic current components.
The third embodiment will now be described. In this third embodiment, the pulsation factor of magnetic flux can be reduced by reducing the ratio of the width s of slot opening in the rotor to the gap length g in the AC-excited synchronous generator (i.e., AC-excited synchronous generator wherein the value of N1−N2 is equal to or greater than +9, or equal to or less than −9) according to the first embodiment, and therefore the armature current waveform can be further improved.
However, as shown in
On the other hand, if the slot is in the shape of a conventional open slot, as shown in
In this embodiment 3-1, the shape of the rotor slot in an AC-excited synchronous generator is made circumferentially asymmetric as shown in
The AC-excited synchronous generator of the embodiment 3-1 employs the semi-closed slot shape as shown in
Thus, by employing the rotor slot in the shape of a circumferentially asymmetric semi-closed slot as in the embodiment 3-1, the higher harmonic components of the armature current can be reduced by about 30% as compared with the conventional open slot as shown in
In this third embodiment, it is also possible to decrease the magnetic flux pulsation factor and therefore to improve the armature current waveform, by reducing the ratio of rotor slot opening width s to gap length g in the AC-excited synchronous generator in the second embodiment.
The fourth embodiment will now be described. In this fourth embodiment, the armature current waveform can be further improved by providing magnetic wedges 15 in the openings of the stator slot 12 and the rotor slot 22 in the AC-excited synchronous generator (i.e., AC-excited synchronous generator wherein the value of N1−N2 is equal to or greater than +9, or equal to or less than −9) according to the first embodiment.
In this fourth embodiment, as shown in
In this fourth embodiment, it is also possible to improve the armature current waveform by providing magnetic wedges 15 in the openings of the stator slots 12 and the rotor slots 22 in the AC-excited synchronous generator according to the second or third embodiment.
The fifth embodiment will now be described.
The AC-excited synchronous generator 1 used in this fifth embodiment is similar in structure to the AC-excited synchronous generators described in the above first to fourth embodiments, and has an armature winding terminal 31 and a field winding terminal 32. The field winding terminal 32 of the AC-excited synchronous generator 1 is connected with the output terminal of the variable-frequency AC exciting device 30. The armature winding terminal 31 of the AC-excited synchronous generator 1 and the input terminal of the variable-frequency AC exciting device 30 are both connected with a power system 33.
The rotor 20 of the AC-excited synchronous generator 1 is rotated by the drive force supplied from the drive power source 40. The variable-frequency AC exciting device 30 supplies an exciting current to the AC-excited synchronous generator via the field winding terminal 32. As a result, electric power can be supplied to the power system 33 via the armature winding terminal 31.
Since the power required to cause exciting current to flow into the AC-excited synchronous generator 1 via the field winding terminal 32 is only 20 or 30% of the power outputted from the armature winding terminal 31 of the AC-excited synchronous generator 1, the capacity of the variable-frequency AC exciting device 30 can be made smaller, and therefore cost reduction can be further expected, by connecting the output terminal of the variable-frequency AC exciting device 30 with the field winding terminal 32, as described in this fifth embodiment, than by connecting the output terminal of the variable-frequency AC exciting device 30 with the armature winding terminal 31.
Moreover, since the AC-excited synchronous generator 1 used in this fifth embodiment is similar in structure to the AC-excited synchronous generators described in the above first to fourth embodiments, the distortion of the waveform of the current delivered out of the armature winding terminal 31 is suppressed. Therefore, in this embodiment, there is no need for providing a converter between the armature winding terminal 31 of the AC-excited synchronous generator 1 and the power system 33.
In the case where there is no converter between the armature winding terminal 31 of the AC-excited synchronous generator 1 and the power system 33, current flows from the armature winding terminal 31 directly into the power system 33. It is therefore required to previously shape the waveform of the current delivered from the armature winding terminal 31 so that the power system 33 may not be adversely affected. However, according to this mode of practice, the distortion of the waveform of the current delivered from the armature winding terminal 31 of the AC-excited synchronous generator 1 is suppressed to such a great extent that the waveform no more imposes any adverse effect on the power system 33.
Accordingly, in this aspect, too, it is especially advantageous to use the AC-excited synchronous generator as described in the first to fourth embodiments, in the AC-excited synchronous generator system according to this fifth embodiment, wherein the armature winding terminal 31 is connected directly with the power system 33 to directly supply power to the power system 33.
One example of rotary electric machines having the same structure as the AC-excited synchronous generator is a wound-rotor induction motor. Even though such a wound-rotor induction motor is connected directly with the power system 33 without any means for improving current waveform connected between them, the induction motor seldom affects the power system 33 adversely since the induction motor does not supply power to but receives power from, the power system 33.
The sixth embodiment will now be described.
The AC-excited synchronous generator 1 used in this sixth embodiment is similar in structure to the AC-excited synchronous generators described in the above first to fourth embodiments, and has an armature winding terminal 31 and a field winding terminal 32. The field winding terminal 32 of the AC-excited synchronous generator 1 is connected with the output terminal of the variable-frequency AC exciting device 30. The armature winding terminal 31 of the AC-excited synchronous generator 1 and the input terminal of the variable-frequency AC exciting device 30 are both connected with a power system 33.
The drive power source 40 used in the sixth embodiment comprises a windmill 41 and a speed increasing unit 42. The speed increasing unit 42 is provided between the AC-excited synchronous generator 1 and the windmill 41. The rotational speed of the windmill 41 is increased by means of the speed increasing unit 42.
In general, the rotational speed of an AC-excited synchronous generator increases as the number of poles decreases. It is therefore understood from
With an AC-excited synchronous generator having two poles in either of the stator and the rotor, however, acoustic noise from the generator itself and the speed increasing unit 42 becomes considerable so that such a generator is not adaptable for use in a wind power generation system because of the unfavorable impact on the environment. Therefore, if the number of poles is set to 4 or 6, the optimal size for such an AC-excited synchronous generator can be obtained. This optimal size can lead to the reduction of cost, too.
Further, since such an AC-excited synchronous generator 1 as described in the first to fourth embodiments is used in the wind power generation system according to this sixth embodiment, the influence of higher harmonic components on the armature current waveform can be lessened even if the length of the gap between the stator 10 and the rotor 20 is decreased. Accordingly, the size of the AC-excited synchronous generator 1 can be further reduced.
According to this embodiment, the size of the AC-excited synchronous generator 1 can be reduced so that it can be easily placed in a high-raised position such as in the nacelle of a large-scale windmill.
According to the wind power generation system described in the sixth embodiment, stable power that is directly supplied to the power system 33 can be generated by adjusting the voltage and frequency of the output of the variable-frequency AC exciting device 30 connected with the field winding terminal 32 of the AC-excited synchronous generator 1 in response to the change in the rotational speed of the windmill 41, and thereby maintaining the rotational speed of the rotor 20 constant.
As described hitherto, the present invention can provide an AC-excited synchronous generator and an AC-excited synchronous generator system used for wind power generation, in which the distortion of the armature current waveform is suppressed.
Further, according to the present invention, the distortion of the armature current waveform is suppressed so that the influence of higher harmonic components on the armature current waveform can be lessened even if the length of the gap between the stator 10 and the rotor 20 is decreased. Accordingly, the size of the AC-excited synchronous generator 1 can be reduced. Therefore, it can be easily placed in a high-raised position such as in the nacelle of a large-scale windmill.
Moreover, according to the present invention, since the distortion of the armature current wave form is suppressed, the current outputted from the armature winding terminal 31 of the AC-excited synchronous generator 1 can be directly supplied to the power system 33, that current having such a waveform as imposing no adverse influence on the power system 33.
It should be further understood by those skilled in the art that although the foregoing description has been made on embodiments of the invention, the invention is not limited thereto and various changes and modifications may be made without departing from the spirit of the invention and the scope of the appended claims.
Number | Date | Country | Kind |
---|---|---|---|
2008-195093 | Jul 2008 | JP | national |
Number | Name | Date | Kind |
---|---|---|---|
4566179 | Sawyer et al. | Jan 1986 | A |
5483111 | Kuznetsov | Jan 1996 | A |
5590003 | Dunfield et al. | Dec 1996 | A |
5654602 | Willyoung | Aug 1997 | A |
7355293 | Bernhoff et al. | Apr 2008 | B2 |
20070278797 | Flannery et al. | Dec 2007 | A1 |
Number | Date | Country |
---|---|---|
3-270664 | Dec 1991 | JP |
7-15901 | Jan 1995 | JP |
07015901 | Jan 1995 | JP |
2005-304271 | Oct 2005 | JP |
2005304271 | Oct 2005 | JP |
Entry |
---|
Machine translation of JP07-015901. |
Machine translation of JP2005-304271. |
Transformers, Induction machines and AC commutator machines, Communicational Education Group of IEEJ, pp. 112, 1967. |
S. Nonaka, Electric Machinery (I), Applied Electrical Engineering Treatise, Morikita Publishing Co. Ltd., p. 227, 1973. |
Number | Date | Country | |
---|---|---|---|
20100026008 A1 | Feb 2010 | US |