This application claims the benefit of Korean Patent Application No. 10-2011-0088494, filed on Sep. 1, 2011, entitled “Switched Reluctance Motor”, which is hereby incorporated by reference in its entirety into this application.
1. Technical Field
The present invention relates to a switched reluctance motor.
2. Description of the Related Art
Recently, a demand for a motor has largely increased in various industries such as vehicles, aerospace, military, medical equipment, or the like. In particular, a cost of a motor using a permanent magnet is increased due to the sudden price increase of a rare earth material, such that a switched reluctance (SR) motor has become interested as a new alternative.
A driving principle of an SR motor rotates a rotor using a reluctance torque generated according to a change in magnetic reluctance.
As shown in
Further, the rotor 110 is configured of only an iron core without any type of excitation device, for example, a winding of a coil or a permanent magnet.
Therefore, when current flows in the coil 130 from the outside, a reluctance torque moving the rotor 110 toward the coil 130 by magnetic force generated from the coil 130 is generated, such that the rotor 110 rotates in a direction in which resistance of a magnetic circuit is minimized.
However, the switched reluctance motor 100 according to the prior art may lead to core loss since a magnetic flux path passes through both of the stator 120 and the rotor 110.
The present invention has been made in an effort to provide a switched reluctance motor having a double rotor structure capable of reducing core loss by reducing a magnetic flux path through a structural change of a stator core corresponding to an in rotor and an out rotor and doubling operating efficiency by inserting a magnet.
According to a preferred embodiment of the present invention, there is provided a switched reluctance motor including: an out rotor including a plurality of out rotor salient poles formed at equidistance along a circular inner circumferential surface thereof; an in rotor received in an inner portion of the out rotor and including a plurality of in rotor salient poles formed at equidistance along a circular outer circumferential surface thereof; and a stator core formed between the out rotor and the in rotor and including a plurality of out stator salient poles each including a main salient pole, a first auxiliary salient pole, and a second auxiliary salient pole that correspond to the out rotor salient poles and are sequentially formed along an outer circumferential surface thereof and a plurality of in stator salient poles each including a first salient pole and a second salient pole that correspond to the in rotor salient poles and are sequentially formed along an inner circumferential surface thereof, wherein each of coils is wound around the main salient pole and the first and second salient poles.
The first and second auxiliary salient poles of the out stator salient pole and the first and second salient poles of the in stator salient pole may be disposed to correspond to each other in a direction in which they face each other.
The switched reluctance motor may further include support materials formed between the first and second salient poles configuring the in stator salient pole and between the plurality of in stator salient poles.
The support material may be a non-magnetic material or an insulation material.
The switched reluctance motor may further include cooling pipes inserted into the support material and disposed between the plurality of in stator salient poles.
The switched reluctance motor may further include sound proofing materials formed between the plurality of out rotor salient poles formed at equidistance.
The main salient pole configuring the out stator salient pole may have a width wider than those of the first and second auxiliary salient poles in a circumferential direction.
The switched reluctance motor may further include magnets inserted into an annular stator core connecting the first and second salient poles configuring the in stator salient pole to each other.
According to another preferred embodiment of the present invention, there is provided a switched reluctance motor including: an out rotor including a plurality of out rotor salient poles formed at equidistance along a circular inner circumferential surface thereof; an in rotor received in an inner portion of the out rotor and including a plurality of in rotor salient poles formed at equidistance along a circular outer circumferential surface thereof; and a stator core formed between the out rotor and the in rotor and including a plurality of out stator salient poles each including a main salient pole, a first auxiliary salient pole, and a second auxiliary salient pole that correspond to the out rotor salient poles and are sequentially formed along an outer circumferential surface thereof and a plurality of in stator salient poles each including a first salient pole and a second salient pole that correspond to the in rotor salient poles and are sequentially formed along an inner circumferential surface thereof, wherein each of coils is wound around the first and second auxiliary salient poles and the first and second salient poles.
The first and second auxiliary salient poles of the out stator salient pole and the first and second salient poles of the in stator salient pole may be disposed to correspond to each other in a direction in which they face each other.
The switched reluctance motor may further include support materials formed between the first and second salient poles configuring the in stator salient pole and between the plurality of in stator salient poles.
The support material may be a non-magnetic material or an insulation material.
The switched reluctance motor may further include cooling pipes inserted into the support material and disposed between the plurality of in stator salient poles.
The switched reluctance motor may further include sound proofing materials formed between the plurality of out rotor salient poles formed at equidistance.
The main salient pole configuring the out stator salient pole may have a width wider than those of the first and second auxiliary salient poles in a circumferential direction.
The switched reluctance motor may further include magnets inserted into an annular stator core connecting the first and second salient poles configuring the in stator salient pole to each other.
Various features and advantages of the present invention will be more obvious from the following description with reference to the accompanying drawings.
The terms and words used in the present specification and claims should not be interpreted as being limited to typical meanings or dictionary definitions, but should be interpreted as having meanings and concepts relevant to the technical scope of the present invention based on the rule according to which an inventor can appropriately define the concept of the term to describe most appropriately the best method he or she knows for carrying out the invention.
The above and other objects, features and advantages of the present invention will be more clearly understood from the following detailed description taken in conjunction with the accompanying drawings. In the specification, in adding reference numerals to components throughout the drawings, it is to be noted that like reference numerals designate like components even though components are shown in different drawings. In addition, the terms “first”, “second”, “one surface”, “the other surface” and so on are used to distinguish one element from another element, and the elements are not defined by the above terms. In describing the present invention, a detailed description of related known functions or configurations will be omitted so as not to obscure the gist of the present invention.
Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.
The switched reluctance motor according to the preferred embodiment of the present invention includes an out rotor 20 including a plurality of out rotor salient poles 21 formed at equidistance along a circular inner circumferential surface thereof; an in rotor 10 received in an inner portion of the out rotor 20 and including a plurality of in rotor salient poles 11 formed at equidistance along a circular outer circumferential surface thereof; and a stator core 30 formed to face each of the out rotor 20 and the in rotor 10 between the out rotor 20 and the in rotor 10 and including a plurality of out stator salient poles 31 each including a main salient pole 31a, a first auxiliary salient pole 31b, and a second auxiliary salient pole 31c that correspond to the out rotor salient poles 21 and are sequentially formed along an outer circumferential surface thereof and a plurality of in stator salient poles 32 each including a first salient pole 32a and a second salient pole 32b that correspond to the in rotor salient poles 11 and are sequentially formed along an inner circumferential surface thereof, wherein each of coils 33 is wound around the main salient pole 31a and the first and second salient poles 32a and 32b.
The switched reluctance motor having a double rotor structure according to the preferred embodiment of the present invention includes the out rotor 20, which is an outer rotor, the in rotor 10, which is an inner rotor, and the stator core 30 formed between the out rotor 20 and the in rotor 10. The stator core 30 may have a shape corresponding to those of the in rotor 10 and the out rotor 20, and may generally have an annular shape. Each of an outer circumferential surface and an inner circumferential surface of the annular stator core 30 is provided with the plurality of out stator salient poles 31 and in stator salient poles 32 each corresponding to the salient poles of the out rotor 20 and the salient poles of the in rotor 10.
As shown in
The in rotor 10 is received in an inner portion of the out rotor 20 and is disposed to be rotatable. The in rotor 10 may include the plurality of in rotor salient poles 11 protruded along the circular outer circumferential surface thereof. The in rotor 10, which is an inner rotor formed at an inner side, includes the in rotor salient poles 11 formed at equidistance so as to correspond to the in stator salient poles 32 of a stator core 30 to be described below. In this configuration, the in rotor salient poles 11 are formed to face the in stator salient poles 32. However, current is applied to the wound coil 33 in a sequence of an A phase, a B phase, and a C phase to electrically excite an A phase winding part 32A, a B phase winding part 32B, and a C phase winding part 32C, such that the in rotor 10 rotates.
The stator core 30 is formed between the out rotor 20 and the in rotor 10. In consideration of a fact that the out rotor 20 and the in rotor 10 have a circular outer shape, the stator core 30 may also have an annular shape so as to correspond to the circular outer shape of the out rotor 20 and the in rotor 10. However, it is obvious to those skilled in the art that an appropriate design change may be made so that the stator core 30 has a shape corresponding to those of the in rotor 10 and the out rotor 20. The stator core 30 is provided with each of the out stator salient poles 31 and the in stator salient poles 32 corresponding to the out rotor salient poles 21 and the in rotor salient poles 11 each formed on the out rotor 20 and the in rotor 10.
The plurality of out stator salient poles 31 are formed at equidistance so as to be protruded outwardly on the outer circumferential surface of the stator core 30 and are formed to correspond to the out rotor salient poles 21 formed to be protruded from the inner circumferential surface of the out rotor 20. The out stator salient pole 31, which is configured of the main salient pole 31a, the first auxiliary salient pole 31b, and the second auxiliary salient pole 31c, includes the main salient pole 31a, the first auxiliary salient pole 31b, and the second auxiliary salient pole 31c that are sequentially formed in one direction (according to the preferred embodiment of the present invention, a unit of the out stator salient pole is based on the case in which the main salient pole, the first auxiliary salient pole, and the second auxiliary salient pole are sequentially formed in a counterclockwise direction as shown in
The plurality of in stator salient poles 32 are formed at equidistance so as to be protruded inwardly on the inner circumferential surface of the stator core 30 and are formed to correspond to the in rotor salient poles 11 formed to be protruded outwardly from the inner circumferential surface of the in rotor 10. The in stator salient pole 32, which is configured of the first and second salient poles 32a and 32b, generally forms a pi (π) shape together with the stator core 30 to which the first and second salient poles 32a and 32b are connected. The first and second salient poles 32a and 32b are formed to be spaced apart from each other in parallel with each other on the stator core 30 to reduce a magnetic flux path to be described below, thereby making it possible to reduce core loss.
As shown in
As shown in
As shown in
As shown in
Likewise, when an A′ phase winding part 31A′, which is a first phase, formed on the opposite side to the A phase winding part 31A and including the coil 33 wound around the main salient pole 31a of the out stator salient pole 31 has current applied thereto to be excited, a generated magnetic flux is bisected in the main salient pole 31a of the A′ phase winding part 31A. Then, the bisected magnetic fluxes flow in auxiliary salient poles of the out stator salient pole 31 adjacent thereto at both sides thereof, that is, a first auxiliary salient pole 31b of a B′ phase winding part 31B′ and a second auxiliary salient pole 31c of the A′ phase winding part 31A′, respectively, through the out rotor salient pole 21.
At the same time, in order to rotate the in rotor 10, when the in stator salient pole 32 of the stator core 30 including the coil 33 wound therearound has current applied thereto to be excited, thereby generating a magnetic flux, the magnetic flux flows from a second salient pole 32b of an A phase winding part 32A, which is an in stator salient pole 32 including the coil 33 wound therearound, to an in rotor salient pole 11 facing a distal end of the second salient pole 32b. Then, the magnetic flux sequentially passes through another in rotor salient pole 11 adjacent to the in rotor salient pole 11 and a first salient pole 32a facing another in rotor salient pole 11 and including the coil wound therearound and then flows in an annular stator core 30 connecting the first and second salient poles 32a and 32b to each other, thereby making it possible to implement a shorter magnetic flux path of the A phase winding part 32A as compared to the case according to the prior art.
Likewise, when an A′ phase winding part 32A′ formed on the opposite side to the A phase winding part 32A has current applied thereto, a magnetic flux flows from a first salient pole 32a of the A′ phase winding part 32A′ including the coil 33 wound therearound to an in rotor salient pole 11 facing the first salient pole 32a. Then, the magnetic flux sequentially passes through another in rotor salient pole 11 adjacent to the in rotor salient pole 11 and a second salient pole 32b facing another in rotor salient pole 11 and including the coil wound therearound and then flows in the annular stator core 30 connecting the first and second salient poles 32a and 32b to each other, thereby making it possible to implement a shorter magnetic flux path of the A′ phase winding part 32A′ as compared to the case according to the prior art.
The switched reluctance motor according to another preferred embodiment of the present invention includes an out rotor 20 including a plurality of out rotor salient poles 21 formed at equidistance along a circular inner circumferential surface thereof; an in rotor 10 received in an inner portion of the out rotor 20 and including a plurality of in rotor salient poles 11 formed at equidistance along a circular outer circumferential surface thereof; and a stator core 30 formed to face each of the out rotor 20 and the in rotor 10 between the out rotor 20 and the in rotor 10 and including a plurality of out stator salient poles 31 each including a main salient pole 31a, a first auxiliary salient pole 31b, and a second auxiliary salient pole 31c that correspond to the out rotor salient poles 21 and are sequentially formed along an outer circumferential surface thereof and a plurality of in stator salient poles 32 each including a first salient pole 32a and a second salient pole 32b that correspond to the in rotor salient poles 11 and are sequentially formed along an inner circumferential surface thereof, wherein each of coils 33 is wound around the first and second auxiliary salient poles 31a and 31b and the first and second salient poles 32a and 32b.
However, a description of a configuration overlapped with that of the switched reluctance motor according to the preferred embodiment of the present invention described above will be omitted.
Here, as the magnet 60, a ferrite permanent magnet, a rare earth permanent magnet, an Alico permanent magnet may be used. Particularly, as the rare earth permanent magnet, there are SmCo and NdFeB. The SmCo has advantages in that it has a high residual magnetic flux density, a high coercive force, a high energy product, and a temperature coefficient such as a demagnetizing curve, and the NdFeB has advantages in that it has residual magnetic flux density and coercive force characteristics higher than those of the SmCo.
Particularly, as shown in
The magnet 60 is inserted into an annular stator core 30 connected between the first and second salient poles 32a and 32b configuring the in stator salient pole 32. The magnet 60 is formed between the first and second salient poles 32a and 32b, such that when the magnetic flux flows in the stator core 30 connected between the first and second salient poles 32a and 32b as described above, magnetic force by the magnetic flux relatively increases due to the insertion of the magnet 60. Likewise, the same magnet 60 is inserted into a path of a magnetic flux bisected and in the main salient pole 31a and flowing through the out stator saline pole 31, thereby making it possible to obtain the same effect.
More specifically, a description will be provided with reference to a flow of a magnetic flux in the case in which the switched reluctance motor having a double rotor structure and including the magnet 60 inserted thereinto as shown in
As shown in
Likewise, when an A′ phase winding part 31A′, which is a first phase, formed on the opposite side to the A phase winding part 31A and including the coil 33 wound around the main salient pole 31a of the out stator salient pole 31 has current applied thereto to be excited, a generated magnetic flux is bisected in the main salient pole 31a. Then, the bisected magnetic fluxes flow in auxiliary salient poles of the out stator salient pole 31 adjacent thereto at both sides thereof, that is, a first auxiliary salient pole 31b of a B′ phase winding part 31B′ and a second auxiliary salient pole 31c of the A′ phase winding part 31A′, respectively, through the out rotor salient pole 21. At this time, each of the magnets 60 is insertedly disposed on paths of the magnetic fluxes, thereby making it possible to obtain increased magnetic force.
At the same time, in order to rotate the in rotor 10, when the in stator salient pole 32 of the stator core 30 has current applied thereto to be excited, thereby generating a magnetic flux, the magnetic flux flows from a second salient pole 32b of an A phase winding part 32A, which is an in stator salient pole 32 including the coil 33 wound therearound, to an in rotor salient pole 11 facing the second salient pole 32b. Then, the magnetic flux sequentially passes through another in rotor salient pole 11 adjacent to the in rotor salient pole 11 and a first salient pole 32a facing another in rotor salient pole 11 and including the coil wound therearound and then flows in the annular stator core 30 connecting the first and second salient poles 32a and 32b to each other, thereby making it possible to implement a shorter magnetic flux path as compared to the case according to the prior art. Even in this case, the magnetic flux flows in the stator core 30 connecting the first and second salient poles 32a and 32b to each other and the magnet 60 is disposed on the path of the magnetic flux, thereby making it possible to obtain relatively larger magnetic force when the same current is applied.
Likewise, a magnetic flux flows from a first salient pole 32a of an A′ phase winding part 32A′ of the in stator salient pole 32 formed on the opposite side to the A phase winding part 32A and including the coil 33 wound therearound to an in rotor salient pole 11 facing the first salient pole 32a. Then, the magnetic flux sequentially passes through another in rotor salient pole 11 adjacent to the in rotor salient pole 11 and a second salient pole 32b facing another in rotor salient pole 11 and including the coil wound therearound and then flows through the magnet 60 disposed in the annular stator core 30 connecting the first and second salient poles 32a and 32b to each other, thereby making it possible to implement a shorter magnetic flux path as compared to the case according to the prior art and obtain relatively larger magnetic force when the same current is applied.
The switched reluctance motor having the double rotor structure according to another preferred embodiment of the present invention may include six out stator salient poles 31 protruded outwardly in a circumferential direction of the annular stator core and formed at equidistance and six in stator salient poles 32 protruded inwardly in the circumferential direction of the annular stator core, as shown in
According to the preferred embodiments of the present invention, structures of salient poles of an annular stator core corresponding to each of salient poles formed on an in rotor and an out rotor of a switched reluctance motor having a double rotor structure including the in rotor and the out rotor are changed to reduce a magnetic flux path, such that the loss of magnetic force is prevented, thereby making it possible to efficiently drive the motor.
In addition, a magnetic flux path is reduced through a pi (π) shaped in stator salient pole structure of the stator core corresponding to the salient poles formed on the in rotor, thereby making it possible to reduce the loss of magnetic force.
Further, a magnetic flux path is reduced through an E shaped out stator salient pole structure of the stator core corresponding to the salient poles formed on the out rotor, thereby making it possible to reduce the loss of magnetic force.
In addition, an out stator salient pole is formed in a structure in which it includes a main salient pole and auxiliary salient poles, and the main salient pole has a width wider than those of the auxiliary salient poles in a circumferential direction. Therefore, a magnetic flux is bisected in the main salient pole to form a short magnetic flux path through each of the auxiliary salient poles adjacent to the main salient pole, such that the loss of magnetic force is prevented, thereby making it possible to efficiently drive the motor.
Further, support materials, which are non-magnetic materials, are formed between the in rotor salient poles formed on the in rotor, thereby making it possible to improve strength of the motor structure and reduce noise and vibration at the time of driving of the motor.
In addition, sound proofing materials are formed between the salient poles of the out rotor, thereby making it possible to prevent noise at the time of driving of the motor.
Further, coils are wound around each of the main salient pole or the auxiliary salient poles of the out stator core, thereby making it possible to change a structure of turns of the coil as desired.
Furthermore, each of magnets is formed on the stator core and is disposed at a point through which a magnetic flux path of the out stator core passes and at a point through which a magnetic flux path of the in stator core passes, such that all of the magnets form torque components at the time of driving of the switched reluctance motor having the double rotor structure, thereby making it possible to efficiently utilize the magnets.
Although the preferred embodiments of the present invention have been disclosed for illustrative purposes, they are for specifically explaining the present invention and thus a switched reluctance motor according to the present invention is not limited thereto, but those skilled in the art will appreciate that various modifications, additions and substitutions are possible, without departing from the scope and spirit of the invention as disclosed in the accompanying claims.
Accordingly, such modifications, additions and substitutions should also be understood to fall within the scope of the present invention.
Number | Date | Country | Kind |
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1020110088494 | Sep 2011 | KR | national |