WO2016194227A1 - レゾルバ、回転電機、及びエレベータ用巻上機 - Google Patents
レゾルバ、回転電機、及びエレベータ用巻上機 Download PDFInfo
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- WO2016194227A1 WO2016194227A1 PCT/JP2015/066361 JP2015066361W WO2016194227A1 WO 2016194227 A1 WO2016194227 A1 WO 2016194227A1 JP 2015066361 W JP2015066361 W JP 2015066361W WO 2016194227 A1 WO2016194227 A1 WO 2016194227A1
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01D—MEASURING NOT SPECIALLY ADAPTED FOR A SPECIFIC VARIABLE; ARRANGEMENTS FOR MEASURING TWO OR MORE VARIABLES NOT COVERED IN A SINGLE OTHER SUBCLASS; TARIFF METERING APPARATUS; MEASURING OR TESTING NOT OTHERWISE PROVIDED FOR
- G01D5/00—Mechanical means for transferring the output of a sensing member; Means for converting the output of a sensing member to another variable where the form or nature of the sensing member does not constrain the means for converting; Transducers not specially adapted for a specific variable
- G01D5/12—Mechanical means for transferring the output of a sensing member; Means for converting the output of a sensing member to another variable where the form or nature of the sensing member does not constrain the means for converting; Transducers not specially adapted for a specific variable using electric or magnetic means
- G01D5/14—Mechanical means for transferring the output of a sensing member; Means for converting the output of a sensing member to another variable where the form or nature of the sensing member does not constrain the means for converting; Transducers not specially adapted for a specific variable using electric or magnetic means influencing the magnitude of a current or voltage
- G01D5/20—Mechanical means for transferring the output of a sensing member; Means for converting the output of a sensing member to another variable where the form or nature of the sensing member does not constrain the means for converting; Transducers not specially adapted for a specific variable using electric or magnetic means influencing the magnitude of a current or voltage by varying inductance, e.g. by a movable armature
- G01D5/204—Mechanical means for transferring the output of a sensing member; Means for converting the output of a sensing member to another variable where the form or nature of the sensing member does not constrain the means for converting; Transducers not specially adapted for a specific variable using electric or magnetic means influencing the magnitude of a current or voltage by varying inductance, e.g. by a movable armature by influencing the mutual induction between two or more coils
- G01D5/2046—Mechanical means for transferring the output of a sensing member; Means for converting the output of a sensing member to another variable where the form or nature of the sensing member does not constrain the means for converting; Transducers not specially adapted for a specific variable using electric or magnetic means influencing the magnitude of a current or voltage by varying inductance, e.g. by a movable armature by influencing the mutual induction between two or more coils by a movable ferromagnetic element, e.g. a core
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B66—HOISTING; LIFTING; HAULING
- B66B—ELEVATORS; ESCALATORS OR MOVING WALKWAYS
- B66B11/00—Main component parts of lifts in, or associated with, buildings or other structures
- B66B11/04—Driving gear ; Details thereof, e.g. seals
- B66B11/043—Driving gear ; Details thereof, e.g. seals actuated by rotating motor; Details, e.g. ventilation
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B66—HOISTING; LIFTING; HAULING
- B66B—ELEVATORS; ESCALATORS OR MOVING WALKWAYS
- B66B5/00—Applications of checking, fault-correcting, or safety devices in elevators
- B66B5/0006—Monitoring devices or performance analysers
- B66B5/0018—Devices monitoring the operating condition of the elevator system
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01D—MEASURING NOT SPECIALLY ADAPTED FOR A SPECIFIC VARIABLE; ARRANGEMENTS FOR MEASURING TWO OR MORE VARIABLES NOT COVERED IN A SINGLE OTHER SUBCLASS; TARIFF METERING APPARATUS; MEASURING OR TESTING NOT OTHERWISE PROVIDED FOR
- G01D5/00—Mechanical means for transferring the output of a sensing member; Means for converting the output of a sensing member to another variable where the form or nature of the sensing member does not constrain the means for converting; Transducers not specially adapted for a specific variable
- G01D5/12—Mechanical means for transferring the output of a sensing member; Means for converting the output of a sensing member to another variable where the form or nature of the sensing member does not constrain the means for converting; Transducers not specially adapted for a specific variable using electric or magnetic means
- G01D5/14—Mechanical means for transferring the output of a sensing member; Means for converting the output of a sensing member to another variable where the form or nature of the sensing member does not constrain the means for converting; Transducers not specially adapted for a specific variable using electric or magnetic means influencing the magnitude of a current or voltage
- G01D5/20—Mechanical means for transferring the output of a sensing member; Means for converting the output of a sensing member to another variable where the form or nature of the sensing member does not constrain the means for converting; Transducers not specially adapted for a specific variable using electric or magnetic means influencing the magnitude of a current or voltage by varying inductance, e.g. by a movable armature
- G01D5/204—Mechanical means for transferring the output of a sensing member; Means for converting the output of a sensing member to another variable where the form or nature of the sensing member does not constrain the means for converting; Transducers not specially adapted for a specific variable using electric or magnetic means influencing the magnitude of a current or voltage by varying inductance, e.g. by a movable armature by influencing the mutual induction between two or more coils
- G01D5/2086—Mechanical means for transferring the output of a sensing member; Means for converting the output of a sensing member to another variable where the form or nature of the sensing member does not constrain the means for converting; Transducers not specially adapted for a specific variable using electric or magnetic means influencing the magnitude of a current or voltage by varying inductance, e.g. by a movable armature by influencing the mutual induction between two or more coils by movement of two or more coils with respect to two or more other coils
Definitions
- the present invention relates to a resolver having a detection stator and a detection rotor rotatable relative to the detection stator, a rotating electric machine having a resolver, and an elevator hoisting machine having a resolver.
- Patent Document 1 shows that the sine phase output winding and the cosine phase output winding are arranged separately from each other in the protruding direction of the teeth. Since the cosine phase output winding and the excitation winding are arranged in the protruding direction of the teeth, if the length of the teeth is left as it is, the thickness of the partition wall of the insulating member is reduced, and the partition wall is deformed. Winding collapse due to is likely to occur.
- the width of each winding in the protruding direction of the teeth can be reduced, but in this case, the thickness in the circumferential direction of each winding increases. As a result, collapse of each winding is likely to occur.
- the present invention has been made to solve the above-described problems, and an object thereof is to obtain a resolver, a rotating electric machine, and an elevator hoisting machine that can suppress an increase in angle detection error.
- the resolver according to the present invention includes a detection stator and a detection rotor that is rotatable with respect to the detection stator.
- the detection rotor has a plurality of salient poles arranged in the circumferential direction, and the detection rotor is radially detected.
- the salient poles are arranged to face each other, and the detection stator includes a detection stator core, a first detection winding group, a second detection winding group, and a plurality of excitations provided on the detection stator core, respectively.
- the detection stator core includes a plurality of teeth arranged in the circumferential direction, the first detection winding group includes a plurality of first windings as detection windings, and a second The detection winding group includes a plurality of second windings having a detection voltage phase different from that of the first winding as detection windings, and the excitation windings are wound around the respective teeth.
- the winding and the second winding are not wound on the same tooth, Made is wound teeth, and the excitation winding detection winding wound around the same tooth, are disposed apart from each other in the radial direction.
- the first winding and the second winding are not wound around the same tooth but are wound around different teeth as detection windings, Since the excitation winding and the detection winding wound around the same tooth are arranged apart from each other in the radial direction of the detection stator, the excitation winding, the first winding, and the second winding Of these, it is possible to prevent another winding from being wound around the outer periphery of any of the windings. Further, since it is possible to avoid the exciting winding, the first winding, and the second winding from being wound around the same tooth, the thickness of each winding in the circumferential direction of the detection stator is increased. There is no need to let them. Thereby, it can suppress that the conducting wire of an exciting winding, a 1st coil
- FIG. 6 is an enlarged view showing an excitation winding and a first winding wound around a tooth number 5 in FIG. 1.
- FIG. 8 is an enlarged view showing an excitation winding and a first winding wound around a tooth number 7 in FIG. 1.
- FIG. 4 is a schematic diagram showing an excitation winding and a maximum width winding wound around the same tooth of FIG. 2 and an excitation winding and a non-maximum width winding wound around the same tooth of FIG. 3.
- It is a schematic diagram which shows magnetic flux density distribution formed around the teeth of FIG. 5 is a graph showing the relationship between the radial positions of the maximum width winding and the non-maximum width winding of FIG.
- FIG. 5 is a schematic diagram showing the relationship between the radial winding width and radial position of the maximum width winding of FIG. 4 and the radial winding width and radial position of a non-maximum width winding.
- FIG. 8 is a schematic diagram showing a state in which the center position of the non-maximum width winding in FIG. 7 matches the center position of the maximum width winding in the radial direction of the detection stator. It is a graph which shows the relationship between the positional offset amount of the center position of the maximum width winding of FIG.
- FIG. 14 is an enlarged view showing an excitation winding and a maximum width winding wound around a tooth number 5 in FIG. 13.
- FIG. 14 is an enlarged view showing an excitation winding and a non-maximum width winding wound around a tooth number 7 in FIG. 13.
- FIG. 17 is an enlarged view showing an excitation winding and a maximum width winding wound around a tooth number 1 in FIG. 16.
- FIG. 17 is an enlarged view showing an excitation winding and a non-maximum width winding wound around a tooth number 3 in FIG. 16.
- FIG. 20 is a sectional view taken along line XX-XX in FIG. It is a longitudinal cross-sectional view which shows the winding machine for elevators by Embodiment 5 of this invention.
- FIG. 1 is a front view showing a resolver according to Embodiment 1 of the present invention.
- the resolver 1 includes a detection stator 2 and a detection rotor 3 that is a magnetic body that can rotate with respect to the detection stator 2.
- an outer rotor type resolver in which a detection stator 2 is arranged radially inside an annular detection rotor 3 is used as the resolver 1.
- the detection stator 2 includes a detection stator core 21 that is a magnetic material, a first detection winding group 23, a second detection winding group 24, and a plurality of excitation windings 22 provided on the detection stator core 21. And an insulator (not shown) that is a non-magnetic material interposed between each of the first detection winding group 23, the second detection winding group 24, and each excitation winding 22 and the detection stator core 21. Have. The insulation state between each of the first detection winding group 23, the second detection winding group 24, and each excitation winding 22 and the detection stator core 21 is determined by the insulation film of the conductive wire and the insulator constituting the winding. It is secured.
- the detection stator core 21 includes an annular core back 26 and a plurality of teeth 27 that protrude from the core back 26 toward the detection rotor 3 radially outward of the core back 26 and are arranged in the circumferential direction of the detection stator core 21.
- 30 teeth 27 are arranged at equal intervals in the circumferential direction of the detection stator core 21.
- a slot 28 which is a groove opened toward the detection rotor 3 is formed.
- numbers that are consecutively assigned to the teeth 27 in the circumferential direction are shown as teeth numbers.
- the excitation winding 22 is wound around each tooth 27. Each excitation winding 22 is electrically connected in series with each other.
- the first detection winding group 23 has a plurality of first windings 231 as detection windings. Each first winding 231 is electrically connected in series with each other. Thereby, each 1st coil
- the second detection winding group 24 has a plurality of second windings 241 as detection windings. Each second winding 241 is electrically connected in series with each other. Thus, the second windings 241 are detection windings of the same phase.
- the first winding 231 and the second winding 241 are detection windings having different electrical angle phases of the detection voltage.
- the first winding 231 is a COS phase detection winding
- the second winding 241 is a SIN phase detection winding. That is, the first winding 231 and the second winding 241 are windings that detect phases that are electrically 90 ° out of phase with each other.
- first winding 231 and the second winding 241 are wound around different teeth 27 without being wound around the same tooth 27. Further, the first winding 231 and the second winding 241 are arranged so that the detection coils of the same phase are not provided on the two teeth 27 adjacent to each other in the circumferential direction of the detection stator core 21. 21 is provided.
- the first winding 231 is wound around each of the teeth 27 selected every other circumferential direction among the plurality of teeth 27, and is different from the teeth 27 around which the first winding 231 is wound.
- a second winding 241 is wound around at least one of the plurality of teeth 27.
- the detection rotor 3 has a plurality of salient poles 31 arranged in the circumferential direction of the detection rotor 3.
- 20 salient poles 31 are arranged at equal intervals in the circumferential direction of the detection rotor 3.
- the detection rotor 3 is arranged coaxially with the detection stator 2 in a state where the salient poles 31 are opposed to the outer peripheral surface of the detection stator 2 in the radial direction.
- a magnetomotive force is generated in each excitation winding 22 by supplying AC power to the excitation winding 22. Thereby, a magnetic flux passing through the detection rotor 3 and the detection stator core 21 is generated. When this magnetic flux links the first winding 231 and the second winding 241, a voltage is generated in the first winding 231 and the second winding 241. Since the permeance between the detection rotor 3 and the detection stator 2 changes in a sine wave shape according to the rotation angle of the detection rotor 3, the rotation angle of the detection rotor 3 is changed to the first winding 231 and This is detected by measuring the voltage output from each of the second windings 241.
- the conducting wire of the excitation winding 22 is wound around all the teeth 27 by the same number of turns so that the winding direction is reversed for each adjacent tooth 27.
- the winding width of each excitation winding 22 in the radial direction of the detection stator 2 that is, the protruding direction of the teeth 27
- the radial winding width of each excitation winding 22 is all the same.
- the positions of the respective excitation windings 22 in the radial direction of the detection stator 2, that is, the radial positions of the respective excitation windings 22 are all the same.
- the first detection winding group 23 includes an adjustment winding group including two types of first windings 231 having different winding widths in the radial direction of the detection stator 2, that is, radial winding widths. It has become. Further, in the first detection winding group 23, the plurality of first windings 231 having the largest radial winding width among the first windings 231 are set as the maximum width windings 231A. Among the single windings 231, a plurality of first windings 231 having a radial winding width smaller than the maximum width winding 231A are non-maximum width windings 231B.
- each maximum width winding 231A is larger than the number of turns of the conducting wire of each non-maximum width winding 231B.
- Each maximum width winding 231A is a forward winding wound in the forward direction
- each non-maximum width winding 231B is a backward winding wound in the opposite direction to the forward winding. It has been split to adjust the offset.
- the winding width of each second winding 241 in the radial direction of the detection stator 2 that is, the radial winding width of each second winding 241 is all the same. It has become. Thereby, all the number of turns of the conducting wire of each second winding 241 is the same.
- the conductive wire of the second winding 241 is wound around each of the teeth 27 having the teeth numbers 4, 6, 10, 12, 16, 18, 22, 24, 28, 30 with the same number of turns one or more times. ing.
- the winding direction of the conducting wire of the second winding 241 wound around each of the teeth 27 having the teeth numbers 6, 12, 18, 24, and 30 is the winding of the conducting wire of each maximum width winding 231A.
- the winding direction of the conducting wire of the second winding 241 wound around each of the teeth 27 having the teeth numbers 4, 10, 16, 24, and 28 is wound in the same direction as the direction.
- the winding direction of the conducting wire of the second winding 241 wound around each of the teeth 27 of 18, 24 and 30 is opposite to the winding direction.
- the second winding 241 wound around the teeth 27 having the teeth numbers 6, 12, 18, 24, and 30 is a forward winding, and the teeth numbers are 4, 10, 16,
- the second winding 241 wound around the teeth 27 of 24 and 28 is a reverse winding.
- the first and second windings 231 and 241 are not wound around the teeth 27 having the tooth numbers 2, 8, 14, 20, and 26 in order to distribute the detection windings in a sine wave shape.
- the total number of turns of each maximum width winding 231A that is a forward direction winding and the total number of turns of each non-maximum width winding 231B that is a reverse direction winding are equal to each other. It has become. Also, in the second detection winding group 24, the total number of turns of the forward winding and the total number of turns of the backward winding among the second windings 241 are equal to each other.
- the spatial distribution of the number of turns of each of the first winding 231 and the second winding 241 wound around the plurality of teeth 27 of the detection stator core 21 is determined by each tooth 27 of the detection stator core 21.
- the number of poles of the exciting winding 22 wound that is, the number of teeth
- 2M the number of teeth
- N the number of salient poles 31 of the detection rotor 3
- N is And a function expressed by a sine wave having a spatial order corresponding to 1).
- the number of turns of each of the first winding 231 and the second winding 241 in each tooth 27 is set to w cos, i , w sin, i (i is 1, 2,..., 2M), respectively.
- the maximum number of turns of each of the first winding 231 and the second winding 241 is set to w max
- the spatial distribution of the number of turns of each of the first winding 231 and the second winding 241 is as follows. It is expressed by a formula. However, the compound numbers in the formulas (1) to (6) are in the same order.
- the number of turns of the first winding (COS phase detection winding) 231 and the second winding (SIN phase detection winding) 241 is the space
- the spatial distribution of the number of turns of each of the first winding 231 and the second winding 241 is a space
- FIG. 2 is an enlarged view showing the excitation winding 22 and the first winding 231 wound around the tooth 27 of the tooth number 5 in FIG.
- FIG. 3 is an enlarged view showing the excitation winding 22 and the first winding 231 wound around the tooth 27 of the tooth number 7 in FIG.
- the first winding 231 wound around the tooth 27 of the tooth number 5 is a maximum width winding 231A
- the first winding 231 wound around the tooth 27 of the tooth number 7 is a non-maximum width winding.
- the line is 231B.
- Each first winding 231 is disposed at a position closer to the core back 26 than the excitation winding 22.
- the maximum width winding 231 ⁇ / b> A and the non-maximum width winding 231 ⁇ / b> B are both arranged closer to the core back 26 than the excitation winding 22.
- the first winding 231 and the excitation winding 22 wound around the same tooth 27 are arranged apart from each other in the radial direction of the detection stator 2.
- Each second winding 241 is also disposed at a position closer to the core back 26 than the excitation winding 22. Further, the second winding 241 and the excitation winding 22 wound around the same tooth 27 are arranged apart from each other in the radial direction of the detection stator 2.
- each detection winding (that is, the first winding 231 and the second winding 241) is disposed at a position closer to the core back 26 than the excitation winding 22. Further, the detection winding (that is, the first winding 231 or the second winding 241) wound around the same tooth 27 and the excitation winding 22 are separated from each other in the radial direction of the detection stator 2. Has been placed.
- the envelopes of the detection voltages of the first winding 231 and the second winding 241 with respect to the exciting voltage of the resolver having the shaft angle multiplier N are ideally sine waves whose phases are shifted by 90 ° from each other.
- the mechanical angle of the detection rotor 3 is ⁇ [rad] and the voltage waveforms detected by the first winding 231 and the second winding 241 respectively
- the first winding 231 and the second winding The rotation angle of the detection rotor 3 obtained from each detection voltage on the line 241 is N ⁇ tan ⁇ 1 (Es ( ⁇ ) / Ec ( ⁇ )) in electrical angle.
- the resolver angle detection error ⁇ ( ⁇ ) [rad] (electrical angle) of the shaft multiple angle N is expressed by the following equation (7).
- the waveform Ec ( ⁇ ) of the detection voltage of the first winding 231 and the waveform Es ( ⁇ ) of the detection voltage of the second winding 241 are ideally expressed by the following equation (8). Is done. However, in Expression (8), normalization is performed so that the amplitude is 1.
- Ec ( ⁇ ) and Es ( ⁇ ) are ideal waveforms as shown in Equation (8), the angle detection error ⁇ ( ⁇ ) becomes 0 according to Equation (7).
- the actual detection voltage waveforms Ec ( ⁇ ) and Es ( ⁇ ) include amplitude difference and phase difference noise and harmonics superimposed on the detection voltage as shown in the following equation (9).
- the waveform may be different from an ideal sine wave.
- a S and A C are the N-th order of the detection voltages of the second winding 241 (SIN phase detection winding) and the first winding 231 (COS phase detection winding), respectively.
- Amplitude, ⁇ S , ⁇ C are the Nth order phases of the detected voltages of the second winding 241 and the first winding 231, and B Sk , B Ck are the second winding 241 and the first winding, respectively.
- the amplitudes of k (k ⁇ N) order harmonics other than the Nth order of the detected voltages of 231, ⁇ Sk , ⁇ Ck are the Nth order of the detected voltages of the second winding 241 and the first winding 231, respectively.
- the voltage signal waveform Ec ( ⁇ ) detected by the first detection winding group 23 is obtained as the sum of the voltages induced by the first windings 231 and is detected by the second detection winding group 24.
- the voltage signal waveform Es ( ⁇ ) is obtained as the sum of the voltages induced by the second windings 231.
- the voltage signal waveform is obtained as an envelope of a waveform obtained as a time derivative of the flux linkage. Therefore, from the equations (7) to (11), the angle detection error ⁇ ( ⁇ ) is suppressed by suppressing the increase of the offset that is a harmonic superimposed on the flux linkage, particularly the zeroth-order harmonic. Can do.
- FIG. 4 shows the excitation winding 22 and the maximum width winding 231A wound around the same tooth 27 of FIG. 2, and the excitation winding 22 and the non-maximum width winding wound around the same tooth 27 of FIG. It is a schematic diagram which shows 231B side by side.
- the teeth 27 are arranged in parallel to each other, and the excitation windings in the direction perpendicular to the teeth 27. The position of the end portion of the line 22 on the core back 26 side is matched. Further, in FIG.
- each tooth 27 shows an x-coordinate axis in which the end on the core back 26 side of the excitation winding 22 is the origin 0 and the direction toward the core back 26 is positive.
- the x coordinate axis is a coordinate axis along the radial direction of the detection stator 2.
- the maximum width winding 231A is arranged over a region between the coordinates x1 and the coordinates x2. Further, the non-maximum width winding 231B is disposed over a region between the coordinates x3 and the coordinates x4. In FIG. 4, x2> x4> x3> x1.
- FIG. 5 is a schematic diagram showing a magnetic flux density distribution formed around the teeth 27 of FIG.
- the value of the magnetic flux density distribution shown in FIG. 5 is merely an example, and this value is not necessarily taken.
- the excitation winding 22 forms a magnetic flux having the magnetic flux density distribution shown in FIG.
- the magnetic flux formed around each tooth 27 around which the excitation winding 22 is wound has a gradient in the radial direction of the detection stator 2 and substantially in the circumferential direction of the detection stator 2. Evenly distributed. That is, around each tooth 27, a gradient of magnetic flux density occurs in the direction along the x-coordinate axis, and the magnetic flux density is almost uniform at a position where the x-coordinate values are equal.
- the excitation winding 22 and the first winding 231 or the second winding 241 are formed with the diameter of the detection stator 2. They are arranged away from each other in the direction. Accordingly, the magnetic flux density of the magnetic flux interlinking with the first winding 231 and the second winding 241 has a gradient in the radial direction of the detection stator 2 and is distributed almost uniformly in the circumferential direction of the detection stator 2. Will do.
- 6 shows the radial position of each of the maximum width winding 231A and the non-maximum width winding 231B of FIG. 4, and the interlinkage magnetic flux density per turn number of each of the maximum width winding 231A and the non-maximum width winding 231B. It is a graph which shows the relationship. 6 shows the interlinkage magnetic flux density of the maximum width winding 231A in the IVA-IVA line of FIG. 4 and the interlinkage magnetic flux density of the non-maximum width winding 231B in the IVB-IVB line of FIG. . As shown in FIG.
- the amount of interlinkage magnetic flux of the detection winding differs depending on the radial position of the detection winding and the radial winding width of the detection winding.
- the amount of interlinkage magnetic flux of the maximum width winding 231A and the amount of interlinkage magnetic flux of the non-maximum width winding 231B are different from each other. From FIG. 6, when the position of the non-maximum width winding 231B is changed in the radial direction of the detection stator 2 with respect to the position of the maximum width winding 231A, the maximum width winding 231A and the non-maximum width winding 231B It can be seen that the relationship between the amounts of the interlinkage magnetic flux of each of these also changes.
- the output voltage of each first winding 231 is added to detect the COS phase.
- the position of the non-maximum width winding 231B with respect to the position of the maximum width winding 231A in the radial direction of the detection stator 2 harmonics that become noise are canceled out, and the angle due to the harmonic component Generation of detection errors is suppressed.
- the offset is a kind of harmonics superimposed on the voltage induced by the magnetic flux interlinked with the detection windings 231 and 241, the position of the non-maximum width winding 231 ⁇ / b> B is adjusted with respect to the position of the maximum width winding 231 ⁇ / b> A. In particular, the offset can be greatly reduced.
- FIG. 7 is a schematic diagram showing the relationship between the radial winding width and radial position of the maximum width winding 231A of FIG. 4 and the radial winding width and radial position of the non-maximum width winding 231B.
- the radial winding width of the maximum width winding 231A is shown as h A
- the radial winding width of the non-maximum width winding 231B is shown as h B.
- the position of the end of the maximum width winding 231A on the core back 26 side is the reference position in the radial direction of the detection stator 2, and the distance from the reference position to the center position of the non-maximum width winding 231B.
- the magnetic flux density formed around the teeth 27 varies greatly in the radial direction of the detection stator 2 at a position close to the excitation winding 22.
- the magnetic flux density around the teeth 27 changes substantially in proportion to the position in the radial direction of the detection stator 2 as shown in FIG. 5. Accordingly, since the winding direction of the conductor of the maximum width winding 231A and the winding direction of the conductor of the non-maximum width winding 231B are different from each other, the radial winding width h A of the maximum width winding 231A falls within the range.
- both ends in the radial direction of the non-maximum width winding 231B are in the radial direction of the maximum width winding 231A. so as not departing from the scope of the line width h a, and the range of the radial winding width h B of the range of non-maximum width winding 231B of the radial winding width h a of the widest winding 231A is seated.
- the relationship between the maximum width winding 231A and the non-maximum width winding 231B in the radial direction of the detection stator 2 is 0 ⁇ h B ⁇ h A and 0 ⁇ d ⁇ (h A ⁇ h B ). It is in a satisfying relationship.
- FIG. 8 is a schematic diagram showing a state in which the center position of the non-maximum width winding 231B in FIG. 7 matches the center position of the maximum width winding 231A in the radial direction of the detection stator 2.
- FIG. 8 when the first detection winding group 23 is viewed along the circumferential direction of the detection stator 2, the center position of the non-maximum width winding 231 ⁇ / b> B is the maximum width winding in the radial direction of the detection stator 2. It coincides with the center position of the line 231A. That is, in this embodiment, the positional deviation amount ⁇ d between the maximum width winding 231A and the non-maximum width winding 231B is zero.
- FIG. 9 is a graph showing the relationship between the positional deviation amount ⁇ d between the center position of the maximum width winding 231A and the center position of the non-maximum width winding 231B and the angle detection error of the resolver 1 in FIG.
- the center position of the maximum width winding 231A and the center position of the non-maximum width winding 231B are determined. It can be seen that the increase in the angle detection error of the resolver 1 is suppressed by matching each other in the radial direction.
- the angle detection error when the positional deviation amount ⁇ d is a specific value other than 0 is indicated by P1
- the angle detection error when the positional deviation amount ⁇ d is 0 is indicated by P0.
- the angle detection error P1 when the positional deviation amount ⁇ d is a specific value that is not 0, the angle detection error P1 may become large depending on the rotation angle of the detection rotor 3, whereas the positional deviation amount When ⁇ d is 0, it can be seen that the angle detection error P0 is suppressed regardless of the value of the rotation angle of the detection rotor 3. Therefore, also from FIG. 10, the angle detection error of the resolver 1 is increased by making the center position of the maximum width winding 231A and the center position of the non-maximum width winding 231B coincide with each other in the radial direction of the detection stator 2. It turns out that it is suppressed. This relationship is established when the function as a resolver is achieved regardless of the combination of the number of salient poles and the excitation order.
- the envelope waveforms of the detection voltages of the first winding 231 and the second winding 241 are expressed as shown in the equation (8). It is desirable that they have sinusoidal shapes that are electrically different from each other by 90 °.
- the detection voltages of the COS phase and the SIN phase are induced by the time change of the magnetic flux linked to the detection winding. Therefore, if the conductors of the detection windings are not aligned, or if the positions of the detection windings are greatly displaced from each other in the radial direction of the detection stator 2, detection of the detection windings is performed as shown in Equation (9). A difference in amplitude and phase occurs in the voltage, or an offset is superimposed, so that the angle detection error of the resolver 1 tends to increase.
- the first winding 231 and the second winding 241 are wound around different teeth 27 without being wound around the same tooth 27, and are excited windings wound around the same tooth 27. Since the wire 22 and the first winding 231 or the second winding 241 are arranged away from each other in the radial direction of the detection stator 2, the exciting winding 22, the first winding 231 and the first winding 231 It is possible to prevent another winding from being wound around one of the two windings 241. Further, since it is possible to avoid all of the exciting winding 22, the first winding 231 and the second winding 241 from being wound around the same tooth 27, each winding in the circumferential direction of the detection stator 2 can be avoided.
- An increase in the thickness of 22, 231, 241 can also be suppressed. As a result, it is possible to more reliably prevent the exciting winding 22, the first winding 231, and the second winding 241 from being collapsed and disturbed, and the conductors of the windings 22, 231, and 241 are connected to the teeth 27. It is possible to suppress the winding from being misaligned. Therefore, an increase in the angle detection error of the resolver 1 can be suppressed.
- first winding 231 and the second winding 241 are arranged away from the excitation winding 22 in the radial direction of the detection stator 2, the windings are overlapped as in the conventional case.
- the positions of the first winding 231 and the second winding 241 with respect to the excitation winding 22 can be independently adjusted in the radial direction of the detection stator 2.
- the magnitude of the voltage induced in each of the first winding 231 and the second winding 241 can be adjusted, and an increase in the angle detection error of the resolver 1 can be suppressed.
- the respective radial winding widths of the respective excitation windings 22 are the same, and the position of each excitation winding 22 is the diameter of the detection stator 2 when viewed along the circumferential direction of the detection stator 2. Since the directions coincide with each other, the magnetic flux density distribution in the radial direction of the detection stator 2 can be made the same in each tooth 27. Thereby, the offset, amplitude difference, and phase difference of the detection voltage caused by the positional deviation of each excitation winding 22 can be suppressed, and an increase in the angle detection error of the resolver 1 can be further suppressed.
- the range of the radial winding width h B of the non-maximum width winding 231B is in the range of the radial winding width h A of the widest winding 231A Therefore, the range in which the magnetic flux common to the non-maximum width winding 231B and the maximum width winding 231A is linked can be increased, and the harmonics superimposed on the detection voltage of each first winding 231; An increase in the angle detection error of the resolver 1 due to the occurrence of the amplitude difference and phase difference of the detection voltage can be further suppressed.
- the center position of the non-maximum width winding 231B and the center position of the maximum width winding 231A coincide with each other in the radial direction of the detection stator 2. It is possible to further suppress an increase in the angle detection error of the resolver 1 due to the superposition of harmonics to the detection voltage of each first winding 231 and the occurrence of the amplitude difference and phase difference of the detection voltage.
- the total number of turns of each maximum width winding 231A that is a forward direction winding and the total number of turns of each non-maximum width winding 231B that is a reverse direction winding are: Since they are equal to each other, the positive and negative voltages in the first detection winding group 23 can be canceled, and the offset of the detection voltage in the first detection winding group 23 can be reduced. Thereby, the increase in the angle detection error of the resolver 1 can be further suppressed. Further, in the second detection winding group 24, the total number of turns of the forward winding and the total number of turns of the backward winding are the same among the second windings 241. Similarly to the first detection winding group 23, the offset of the detection voltage of the second detection winding group 24 can be reduced, and an increase in the angle detection error of the resolver 1 can be further suppressed.
- the radial winding width h B of the non-maximum width winding 231B is smaller than the radial winding width h A of the maximum width winding 231A, the non-maximum winding width h A in the radial direction of the detection stator 2 is not.
- the range in which the position of the large winding 231B can be adjusted can be made larger than that of the maximum width winding 231A. Therefore, even when there is little room for adjusting the position of the maximum width winding 231A in the radial direction, an increase in the angle detection error of the resolver 1 is suppressed by adjusting the position of each non-maximum width winding 231B in the radial direction. be able to. Thereby, the freedom degree in the design of the resolver 1 can be improved.
- the number of non-maximum width windings 231B is larger than the number of maximum width windings 231A. Therefore, when there is sufficient room for adjusting the position of the maximum width winding 231A in the radial direction, the position of each maximum width winding 231A having a smaller number than the non-maximum width winding 231B should be adjusted. Thus, the number of windings for position adjustment can be reduced. Thereby, the burden of the position adjustment work of each detection winding 231 and 241 can be reduced.
- first windings 231 and the second windings 241 are disposed closer to the core back 26 than the respective excitation windings 22, but as shown in FIG.
- Each excitation winding 22 may be disposed at a position closer to the core back 26 than each first winding 231 and each second winding 241. That is, the first windings 231 and the second windings 241 may be arranged at positions closer to the detection rotor 3 than the excitation windings 22.
- the radial winding widths of the respective excitation windings 22 are made the same, and the radial positions of the respective excitation windings 22 are also made the same. Even if it does in this way, the increase in the angle detection error of the resolver 1 can be suppressed, preventing the enlargement of the resolver 1.
- the number of teeth 27 of the detection stator 2 is 30 and the number of salient poles 31 of the detection rotor 3 is 20.
- the combination fulfills the function of a resolver
- the combination of the number of 27 and the number of salient poles 20 is not limited to this. Accordingly, the combination of the number of teeth 27 and the number of salient poles 31 (that is, the shaft angle multiplier) is different from the above example of the combination of 30 teeth 27 and 20 salient poles 31.
- FIG. The present invention can also be applied to Example 1-1 to Example 1-6, and an increase in resolver angle detection error can be suppressed.
- FIG. 12 is a table showing combinations of the number of teeth 27, the number of salient poles 31 (that is, the shaft multiple angle), and the order of the excitation winding 22 in each of the embodiments 1-1 to 1-6 of the present invention. is there.
- the shaft angle multiplier N and the order M of the excitation winding 22 are applied to the equations (1) to (6).
- the winding distribution of the first winding 231 and the second winding 241 is determined to be a discrete sine wave, and the order of the angle detection error of the resolver is determined by the equations (7) to (11). It is determined.
- the detection winding group As long as the distribution of the number of turns of the windings forming a sine wave is sinusoidal and there is a magnitude relationship between the number of turns of the constituent windings or the winding width, the position of the windings constituting the detection winding group can be adjusted.
- the spatial distribution of the number of turns of the first detection winding group and the second detection winding group is expressed by a sine wave of the space
- the fifth order of the space in the formulas (1) to (6), the COS value is shifted to the 35th order (
- the fifth-order spatial distribution in the case of a resolver having 30 teeth, the fifth-order spatial distribution consists of the same winding pattern every 6 teeth, and the first is electrically 90 ° out of phase within one winding pattern. It means that the winding of the detection winding group and the winding of the second detection winding group are each constituted by three teeth. Therefore, when the number of turns is the fifth space, the maximum width winding 231A and the non-maximum width winding 231B can exist in the first detection winding group, and thus the above-described argument holds.
- the turn distribution can adopt the space fifth order or the space third order, and constitutes the first detection winding group and the second detection winding group. Since the windings are configured so that there is a magnitude relationship, winding position adjustment for reducing angle detection errors can be performed based on the above discussion.
- each of the windings 22, 231, 241 is arranged.
- the alignment of the conductors can be improved and the angle detection error of the resolver can be reduced by adjusting the positions of the first winding 231 and the second winding 241.
- the present invention can be achieved by combining the number of salient poles and the excitation order so as to obtain the spatial distribution of the number of turns as described above for the combination of the number of teeth 27 and the number of salient poles 31 not shown in FIG. Needless to say, is applicable.
- FIG. FIG. 13 is a front view showing a resolver according to Embodiment 2 of the present invention.
- the configuration of the resolver 1 is the same as that of the first embodiment except for the configuration of the insulator 30.
- An insulator 30 that is a nonmagnetic material and an insulator is interposed between each excitation winding 22, the first detection winding group 23, and the second detection winding group 24 and the detection stator core 21. Yes.
- the insulator 30 includes a plurality of partition portions 301 interposed between the excitation winding 22 and the detection windings 231 and 241 wound around the same tooth 27, and between the detection windings 231 and 241 and the core back 26.
- the excitation winding 22 and the detection windings 231 and 241 are arranged apart from each other via the partition portion 301 in the radial direction of the detection stator 2.
- the detection windings 231 and 241 and the core back 26 are arranged apart from each other via the protrusion 302 in the radial direction of the detection stator 2.
- FIG. 14 is an enlarged view showing the excitation winding 22 and the maximum width winding 231A wound around the tooth 27 of the tooth number 5 in FIG.
- FIG. 15 is an enlarged view showing the excitation winding 22 and the non-maximum width winding 231B wound around the tooth 27 of the tooth number 7 in FIG.
- the positioning of the maximum width winding 231A with respect to the excitation winding 22 is performed in the radial direction of the detection stator 2 by adjusting the thicknesses of the partition portion 301A and the protruding portion 302A. Yes.
- the positioning of the non-maximum width winding 231B with respect to the excitation winding 22 is performed in the radial direction of the detection stator 2 by adjusting the thicknesses of the partition portion 301B and the protruding portion 302B, as shown in FIG. Has been done.
- the thickness of the partition portion 301B is larger than the thickness of the partition portion 301A.
- the thickness of the protrusion 302B is greater than the thickness of the protrusion 302A.
- the insulator 30, which is a non-magnetic material, has a partition portion 301 interposed between the excitation winding 22 and the detection windings 231 and 241 that are wound around the same tooth 27.
- the electrical insulation state between the excitation winding 22 and the detection windings 231 and 241 can be more reliably maintained, and the alignment state of the conducting wires of the excitation winding 22 and the detection windings 231 and 241 can be further increased. Can keep good.
- the detection windings 231 and 241 can be more accurately positioned with respect to the excitation winding 22 in the radial direction of the detection stator 2. Thereby, the harmonic of a magnetic flux can be suppressed and the increase in the angle detection error of the resolver 1 can further be suppressed.
- the insulator 30 further includes a protruding portion 302 interposed between each of the first winding 231 and the second winding 241 and the core back 26, the radial direction of the detection stator 2 is determined. Therefore, the first winding 231 and the second winding 241 can be more accurately positioned with respect to the excitation winding 22, and the increase in the angle detection error of the resolver 1 can be further suppressed.
- FIG. FIG. 16 is a front view showing a resolver 1 according to Embodiment 3 of the present invention.
- an inner rotor type resolver in which a detection rotor 3 that is a magnetic body is arranged radially inside an annular detection stator 2 is used as the resolver 1.
- the detection stator 2 includes a detection stator core 21 that is a magnetic material, and a plurality of excitation windings 22, a first detection winding group 23, and a second detection winding group 24 that are respectively provided on the detection stator core 21. And an insulator 30, which is a non-magnetic material, interposed between each excitation winding 22, first detection winding group 23, and second detection winding group 24 and the detection stator core 21. is doing. The insulation state between each excitation winding 22, each of the first detection winding group 23 and the second detection winding group 24, and the detection stator core 21 is ensured by an insulator.
- the detection stator core 21 includes an annular core back 26 and a plurality of teeth 27 that protrude from the core back 26 toward the detection rotor 3 inward in the radial direction of the core back 26 and are arranged in the circumferential direction of the detection stator core 21.
- 18 teeth 27 are arranged at equal intervals in the circumferential direction of the detection stator core 21.
- a slot 28 which is a groove opened toward the detection rotor 3 is formed.
- numbers that are consecutively assigned to the teeth 27 in the circumferential direction are shown as teeth numbers.
- the excitation winding 22 is wound around each tooth 27. Each excitation winding 22 is electrically connected in series with each other.
- the first detection winding group 23 has a plurality of first windings 231 as detection windings. Each first winding 231 is electrically connected in series with each other. Thereby, each 1st coil
- the second detection winding group 24 has a plurality of second windings 241 as detection windings. Each second winding 241 is electrically connected in series with each other. Thus, the second windings 241 are detection windings of the same phase.
- the first winding 231 and the second winding 241 are detection windings having different electrical angle phases of the detection voltage.
- the first winding 231 is a COS phase detection winding
- the second winding 241 is a SIN phase detection winding. That is, the first winding 231 and the second winding 241 are windings that detect phases that are electrically 90 ° out of phase with each other.
- first winding 231 and the second winding 241 are wound around different teeth 27 without being wound around the same tooth 27. Further, the first winding 231 and the second winding 241 are arranged so that the detection coils of the same phase are not provided on the two teeth 27 adjacent to each other in the circumferential direction of the detection stator core 21. 21.
- the first winding 231 is wound around each of the teeth 27 selected every other circumferential direction among the plurality of teeth 27, and is different from the teeth 27 around which the first winding 231 is wound.
- a second winding 241 is wound around at least one of the plurality of teeth 27.
- the detection rotor 3 has a plurality of salient poles 31 arranged in the circumferential direction of the detection rotor 3. In this example, fifteen salient poles 31 are arranged at equal intervals in the circumferential direction of the detection rotor 3. Further, the detection rotor 3 is arranged coaxially with the detection stator 2 with the salient poles 31 facing the inner peripheral surface of the detection stator 2 in the radial direction. When the detection rotor 3 rotates with respect to the detection stator 2, the permeance pulsation between the detection rotor 3 and the detection stator 2 changes in a sinusoidal shape due to the presence of each salient pole 31.
- a magnetomotive force is generated in each excitation winding 22 by supplying AC power to the excitation winding 22. Thereby, a magnetic flux passing through the detection rotor 3 and the detection stator core 21 is generated. When this magnetic flux links the first winding 231 and the second winding 241, a voltage is generated in the first winding 231 and the second winding 241. Since the permeance between the detection rotor 3 and the detection stator 2 changes in a sine wave shape according to the rotation angle of the detection rotor 3, the rotation angle of the detection rotor 3 is the first winding 231 and This is detected by measuring the voltage output from each of the second windings 241.
- the conducting wire of the excitation winding 22 is wound around all the teeth 27 by the same number of turns so that the winding direction is reversed for each adjacent tooth 27.
- the radial winding widths of the respective excitation windings 22 are all the same.
- the radial positions of the respective excitation windings 22 are all the same.
- the first detection winding group 23 is an adjustment winding group including two types of first windings 231 having different radial winding widths. Further, in the first detection winding group 23, the plurality of first windings 231 having the largest radial winding width among the first windings 231 are set as the maximum width windings 231A. Among the single windings 231, a plurality of first windings 231 having a radial winding width smaller than the maximum width winding 231A are non-maximum width windings 231B. The number of turns of the conducting wire of each maximum width winding 231A is larger than the number of turns of the conducting wire of each non-maximum width winding 231B. Each maximum width winding 231A is a forward winding wound in the forward direction, and each non-maximum width winding 231B is a backward winding wound in the opposite direction to the forward winding.
- the radial winding widths of the second windings 241 are all the same. Thereby, all the number of turns of the conducting wire of each second winding 241 is the same.
- the conductive wire of the second winding 241 is wound around each of the teeth 27 having the tooth numbers 2, 6, 8, 12, 14, 18 with the same number of turns one or more times.
- the winding direction of the conducting wire of the second winding 241 wound around each tooth 27 having the tooth numbers 2, 8, and 14 is the same as the winding direction of the conducting wire of each maximum width winding 231A.
- the winding direction of the second winding 241 wound around each of the teeth 27 having the teeth numbers 6, 12 and 18 is wound around each of the teeth 27 having the teeth numbers 2, 8, and 14.
- the winding direction of the second winding 241 is opposite to the winding direction of the conducting wire.
- the second winding 241 wound around the teeth 27 having the tooth numbers 2, 8, and 14 is set as the positive direction winding, and the teeth 27 having the teeth numbers 6, 12, and 18 are assigned to the teeth 27.
- the wound second winding 241 is a reverse winding.
- the first and second windings 231 and 241 are not wound around the teeth 27 having the teeth numbers 4, 10, and 16 in order to distribute the detection windings in a sine wave shape.
- the total number of turns of each maximum width winding 231A that is a forward direction winding and the total number of turns of each non-maximum width winding 231B that is a reverse direction winding are equal to each other. It has become. Also, in the second detection winding group 24, the total number of turns of the forward winding and the total number of turns of the backward winding among the second windings 241 are equal to each other.
- the spatial distribution of the number of turns of each of the first winding 231 and the second winding 241 wound around the plurality of teeth 27 of the detection stator core 21 is determined by each tooth 27 of the detection stator core 21.
- the number of poles of the exciting winding 22 wound that is, the number of teeth
- 2M the number of teeth
- N the number of salient poles 31 of the detection rotor 3
- N is And a function expressed by a sine wave having a spatial order corresponding to 1).
- Each detection winding (that is, the first winding 231 and the second winding 241) is disposed at a position closer to the core back 26 than the excitation winding 22. Further, the detection winding (that is, the first winding 231 or the second winding 241) wound around the same tooth 27 and the excitation winding 22 are separated from each other in the radial direction of the detection stator 2. Has been placed.
- the insulator 30 includes a plurality of partition portions 301 interposed between the excitation winding 22 and the detection windings 231 and 241 wound around the same tooth 27, and between the detection windings 231 and 241 and the core back 26. And a plurality of protrusions 302 interposed therebetween.
- the excitation winding 22 and the detection windings 231 and 241 are arranged apart from each other via the partition portion 301 in the radial direction of the detection stator 2.
- the detection windings 231 and 241 and the core back 26 are arranged apart from each other via the protrusion 302 in the radial direction of the detection stator 2.
- FIG. 17 is an enlarged view showing the excitation winding 22 and the maximum width winding 231A wound around the tooth 27 of the tooth number 1 in FIG.
- FIG. 18 is an enlarged view showing the excitation winding 22 and the non-maximum width winding 231B wound around the tooth 27 having the tooth number 3 in FIG.
- the positioning of the maximum width winding 231A with respect to the excitation winding 22 is performed in the radial direction of the detection stator 2 by adjusting the thicknesses of the partition portion 301A and the protruding portion 302A. Yes.
- the positioning of the non-maximum width winding 231B with respect to the excitation winding 22 is performed in the radial direction of the detection stator 2 by adjusting the thicknesses of the partition portion 301B and the protruding portion 302B, as shown in FIG. Has been done.
- the positional relationship in the radial direction between the maximum width winding 231A and the non-maximum width winding 231B when the first detection winding group 23 is viewed along the circumferential direction of the detection stator 2 is the same as that of the first embodiment. It is the same.
- the thickness of the partition portion 301B is larger than the thickness of the partition portion 301A.
- the thickness of the protrusion 302B is greater than the thickness of the protrusion 302A.
- the exciting winding 22, the first winding 231 and the second winding 241 can be more reliably prevented from being crushed and disturbed, and the angle of the resolver 1 can be detected. An increase in error can be suppressed.
- the number of teeth 27 of the detection stator 2 is 18 and the number of salient poles 31 of the detection rotor 3 is 15, but the combination of FIG. 12 shown in the first embodiment is used.
- the combination of the number of teeth 27 and the number of salient poles 31 is not limited to this as long as the combination fulfills the function of a resolver.
- FIG. 19 is a longitudinal sectional view showing a rotary electric machine according to Embodiment 4 of the present invention.
- FIG. 20 is a sectional view taken along line XX-XX in FIG.
- a rotating electrical machine 101 includes an annular stator 102, a rotor 103 that is disposed inside the stator 102 and is rotatable with respect to the stator 102, and a housing 104 that supports the stator 102 and the rotor 103. Yes.
- the housing 104 has a plate-shaped housing main body 105 and a cylindrical housing tube portion 106 fixed to the outer peripheral portion of the housing main body 105.
- a through hole 107 is provided at the center of the housing body 105.
- a support shaft 108 that is fixed to the housing main body 105 and disposed on the central axis of the housing tube portion 106 is fixed to the housing 104.
- the rotor 103 is rotatably attached to the support shaft 108 via a bearing 109.
- the rotor 103 is supported by the housing 104 via a support shaft 108.
- the stator 102 is arranged coaxially with the rotor 103.
- the stator 102 is provided on the stator core 110, which is provided on the stator core 110 and arranged in the circumferential direction of the stator core 110, and on the stator core 110. 110 and an insulator 112 interposed between the stator windings 111.
- the stator 102 is supported by the housing 104 in a state in which the stator core 110 is fitted in the housing cylindrical portion 106. The insulation state between each stator winding 111 and the stator core 110 is ensured by the insulator 112.
- the stator core 110 is composed of steel plates that are a plurality of magnetic bodies stacked in the axial direction of the support shaft 108. Further, the stator core 110 protrudes radially inward from the annular back yoke portion 113 along the inner peripheral surface of the housing cylindrical portion 106 and the back yoke portion 113, and is arranged at intervals from each other in the circumferential direction of the stator core 110. And a plurality of magnetic pole tooth portions 114. The magnetic teeth portions 114 are arranged at equal intervals in the circumferential direction of the stator core 110.
- the stator winding 111 is individually provided in each magnetic tooth portion 114. Accordingly, the stator windings 111 are arranged at equal intervals in the circumferential direction of the stator core 110. A rotating magnetic field is generated in the stator 102 by energizing each stator winding 111. The rotor 103 is rotated about the axis of the support shaft 108 by the generation of the rotating magnetic field of the stator 102.
- the rotor 103 includes a rotor yoke 115 and a plurality of permanent magnets (rotor magnetic pole portions) 116 provided on the rotor yoke 115, respectively.
- the rotor yoke 115 is a casting made of cast iron. Further, as shown in FIG. 18, the rotor yoke 115 includes a rotor yoke main body 117 to which a bearing 109 is attached, and a cylindrical rotor cylinder portion 118 that is fixed to the outer peripheral portion of the rotor yoke main body 117 and arranged coaxially with the support shaft 108. And have.
- the rotor yoke 115 is disposed inside the stator 102 with the outer peripheral surface of the rotor cylinder portion 118 facing the stator 102 in the radial direction of the rotor 103. Thereby, the outer peripheral surface of the rotor cylinder part 118 is opposed to the front end face of each magnetic pole tooth part 114 in the radial direction.
- Each permanent magnet 116 is provided on the outer peripheral surface of the rotor cylinder 118.
- the permanent magnets 116 are arranged at intervals in the circumferential direction of the rotor 103 (that is, the rotational direction of the rotor 103) in the space between the rotor cylinder portion 118 and the stator 102.
- the permanent magnets 116 are arranged at equal intervals in the circumferential direction of the rotor 103.
- a through hole 121 is provided in the central portion of the rotor yoke body 117.
- a resolver shaft 122 reaching the inside of the through hole 121 is provided coaxially with the support shaft 108 at the distal end portion of the support shaft 108.
- the outer diameter of the resolver shaft 122 is smaller than the outer diameter of the support shaft 108.
- an outer rotor type resolver 1 that detects the rotation angle of the rotor 103 is provided.
- the resolver 1 includes a detection stator 2 fixed to a resolver shaft 122 and a detection rotor 3 that is opposed to the detection stator 2 in the radial direction and is a magnetic body that can rotate with respect to the detection stator 2. is doing.
- the detection rotor 3 is fixed to the inner surface of the through hole 121 of the rotor yoke body 117. Thereby, the detection rotor 3 is coaxially rotated with respect to the support shaft 108 and the resolver shaft 122 integrally with the rotor yoke body 117.
- the configurations of the detection stator 2 and the detection rotor 3 are the same as those in the first embodiment.
- the resolver 1 in the first embodiment is provided in the rotating electrical machine 101, but the resolver 1 in the second embodiment may be provided in the rotating electrical machine 101.
- the resolver 1 may be applied to the rotating electrical machine 101 as a motor, or the resolver 1 may be applied to the rotating electrical machine 101 as a generator.
- FIG. 21 is a longitudinal sectional view showing an elevator hoist according to Embodiment 5 of the present invention.
- an elevator hoisting machine 130 includes the inner rotor type resolver 1 according to the third embodiment, a motor 131, and a drive sheave 132 that is rotated by the driving force of the motor 131.
- the motor 131 is a rotating electrical machine that includes an annular stator 102, a rotor 103 that is disposed inside the stator 102 and is rotatable with respect to the stator 102, and a housing 104 that supports the stator 102 and the rotor 103.
- the support shaft 108 of the housing 104 is a hollow, that is, a cylindrical shaft whose inside communicates with the through hole 107 of the housing body 105.
- the rotor yoke 115 of the rotor 103 further includes a resolver shaft 119 that is fixed to the central portion of the rotor yoke body 117 and reaches the inside of the through hole 107 through the support shaft 108 in addition to the rotor yoke body 117 and the rotor cylinder portion 118.
- Other configurations of the motor 131 are the same as the configuration of the rotating electrical machine 101 in the fourth embodiment.
- An inner rotor type resolver 1 that detects the rotation angle of the rotor 103 is provided in the through hole 107 of the housing body 105.
- the resolver 1 includes a detection stator 2 fixed to the housing body 105 in the through-hole 107 and a detection rotor that is a magnetic body that faces the detection stator 2 in the radial direction and is rotatable with respect to the detection stator 2. 3.
- the detection rotor 3 is fixed to a resolver shaft 119.
- the detection rotor 3 is rotated integrally with the rotor 103 about the axis of the resolver shaft 119 by energizing the stator winding 111.
- the drive sheave 132 is formed integrally with the rotor yoke 115. As a result, the drive sheave 132 is rotatably supported by the support shaft 108 via the bearing 109.
- the material constituting the drive sheave 132 and the rotor yoke 115 is cast iron.
- the drive sheave 132 is provided at a position outside the range of the stator 102 in the axial direction of the support shaft 108.
- the drive sheave 132 is rotated about the axis of the support shaft 108 as the rotor 103 rotates.
- a plurality of main rope grooves 133 are provided on the outer peripheral surface of the drive sheave 132 along the circumferential direction of the drive sheave 132.
- a plurality of main ropes that suspend a car and a counterweight are wound around the drive sheave 132 along each main rope groove 133.
- the car and the counterweight are moved up and down in the hoistway by the rotation of the drive sheave 132.
- a brake device 134 that provides a braking force to the drive sheave 132 and the rotor 103 is provided inside the rotor cylinder portion 118.
- the brake device 134 has a brake shoe (not shown) that can be displaced in the radial direction of the rotor 103 with respect to the rotor cylinder portion 118.
- the brake device 134 applies a braking force to the drive sheave 132 and the rotor 103 by bringing the brake shoe into contact with the inner peripheral surface of the rotor cylinder portion 118, and the drive sheave 132 and the rotor 103 by separating the brake shoe from the rotor cylinder portion 118. Release the braking force against.
- the resolver 1 is provided in the elevator hoisting machine 130 in which the drive sheave 132 is integrated with the rotor 103.
- a gear device including a plurality of gears meshing with each other is used as a motor as a rotating electrical machine.
- the resolver 1 may be provided in a geared hoisting machine (elevator hoisting machine) that is mounted on the motor and transmits the rotation of the rotor included in the motor to the drive sheave 132 via a gear device.
- the drive sheave 132 is rotated at a rotational speed that is reduced at a constant gear ratio with respect to the rotational speed of the rotor as the rotor included in the motor rotates.
- the rotary electric machine 101 according to the fourth embodiment may be applied to the elevator hoisting machine as the motor 131.
- the rotating electrical machine 101 according to the fourth embodiment is applied to an elevator hoist as the motor 131, the motor 131 is provided with the outer rotor type resolver 1 according to the first or second embodiment.
- the inner rotor type resolver 1 of the third embodiment may be provided in the same rotating electrical machine as the configuration of the motor 131 in the fifth embodiment.
- the present invention is applied to an inner rotor type rotating electrical machine in which the outer periphery of the rotor 103 is surrounded by the annular stator 102, but the outer rotor type of the stator 102 is surrounded by the annular rotor 103. You may apply this invention to a rotary electric machine.
- the resolver 1 is provided in the permanent magnet motor in which the permanent magnet 116 is included in the rotor 103.
- the present invention is not limited to this.
- the resolver 1 may be provided in an induction motor or the like. .
- each first winding 231 is a COS-phase detection winding
- each second winding 241 is a SIN-phase detection winding
- the winding 231 may be a SIN phase detection winding
- each second winding 241 may be a COS phase detection winding.
- first detection winding group 23 may include three or more types of first windings 231.
- one type of first windings 231 having the largest radial winding width are set as the maximum width winding, and other types of plural windings having a radial winding width smaller than the maximum width winding are used.
- the first winding 231 is a non-maximum width winding.
- the radial direction of each non-maximum width winding is within the radial winding range of the maximum width winding.
- the first detection winding group 23 is used as an adjustment winding group including a plurality of types of detection windings having different radial winding widths.
- the line group 24 may be an adjustment winding group.
- the number of radial winding widths of each second winding 241 included in the second detection winding group 24 may be two, or three or more.
- the first detection winding portion 23 is an adjustment winding group including a plurality of types of first windings 231 having different radial winding widths.
- the first windings 231 included in the detection winding group 23 may have the same radial winding width. Even in this case, it is possible to avoid the exciting winding 22, the first winding 231, and the second winding 241 from being wound around the same tooth 27. , 241 can be prevented from collapsing and turbulent. That is, the present invention can be applied to two or more types of winding widths even when the number of windings is the same.
- the present invention is applied to a variable reluctance type resolver.
- the present invention may be applied to a rotary transformer type resolver.
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Abstract
Description
実施の形態1.
図1は、この発明の実施の形態1によるレゾルバを示す正面図である。レゾルバ1は、検出用ステータ2と、検出用ステータ2に対して回転可能な磁性体である検出用ロータ3とを有している。この例では、円環状の検出用ロータ3の径方向内側に検出用ステータ2が配置されているアウタロータ型のレゾルバがレゾルバ1として用いられている。
図13は、この発明の実施の形態2によるレゾルバを示す正面図である。本実施の形態では、レゾルバ1の構成が、インシュレータ30の構成を除いて、実施の形態1と同様である。各励磁巻線22、第1の検出巻線群23及び第2の検出巻線群24のそれぞれと検出用ステータコア21との間には、非磁性体かつ絶縁体であるインシュレータ30が介在している。インシュレータ30は、同一のティース27に巻かれている励磁巻線22と検出巻線231,241との間に介在する複数の仕切り部301と、検出巻線231,241とコアバック26との間に介在する複数の突出部302とを有している。励磁巻線22と検出巻線231,241とは、検出用ステータ2の径方向について仕切り部301を介して互いに離して配置されている。検出巻線231,241とコアバック26とは、検出用ステータ2の径方向について突出部302を介して互いに離して配置されている。
図16は、この発明の実施の形態3によるレゾルバ1を示す正面図である。本実施の形態では、円環状の検出用ステータ2の径方向内側に磁性体である検出用ロータ3が配置されているインナロータ型のレゾルバがレゾルバ1として用いられている。
図19は、この発明の実施の形態4による回転電機を示す縦断面図である。また、図20は、図19のXX-XX線に沿った断面図である。図において、回転電機101は、円環状のステータ102と、ステータ102の内側に配置され、ステータ102に対して回転可能なロータ103と、ステータ102及びロータ103を支持するハウジング104とを有している。
上記実施の形態3によるインナロータ型のレゾルバ1をエレベータ用巻上機に適用してもよい。即ち、図21は、この発明の実施の形態5によるエレベータ用巻上機を示す縦断面図である。図において、エレベータ用巻上機130は、実施の形態3でのインナロータ型のレゾルバ1と、モータ131と、モータ131の駆動力により回転される駆動シーブ132とを有している。
Claims (9)
- 検出用ステータ、及び
前記検出用ステータに対して回転可能な検出用ロータ
を備え、
前記検出用ロータは、周方向へ並ぶ複数の突極を有し、径方向について前記検出用ステータに各前記突極を対向させて配置されており、
前記検出用ステータは、検出用ステータコアと、前記検出用ステータコアにそれぞれ設けられている第1の検出巻線群、第2の検出巻線群及び複数の励磁巻線とを有し、
前記検出用ステータコアは、周方向へ並ぶ複数のティースを有し、
前記第1の検出巻線群は、複数の第1の巻線を検出巻線として有し、
前記第2の検出巻線群は、検出電圧の位相が前記第1の巻線と異なる複数の第2の巻線を検出巻線として有し、
前記励磁巻線は、各前記ティースにそれぞれ巻かれており、
前記第1の巻線及び前記第2の巻線は、同一の前記ティースに巻かれずに互いに異なる前記ティースに巻かれており、
同一の前記ティースに巻かれている前記検出巻線と前記励磁巻線とは、径方向について互いに離して配置されているレゾルバ。 - 前記第1の検出巻線群及び前記第2の検出巻線群の少なくともいずれかは、前記検出用ステータの径方向についての巻線幅が互いに異なる複数種の前記検出巻線が含まれている調整巻線群になっており、
前記調整巻線群における各前記検出巻線の中で巻線幅が最大である前記検出巻線を最大幅巻線とし、巻線幅が前記最大幅巻線よりも小さい前記検出巻線を非最大幅巻線とすると、
前記検出用ステータを周方向に沿って見たとき、前記検出用ステータの径方向について、前記非最大幅巻線の巻線幅の範囲が前記最大幅巻線の巻線幅の範囲内に収まっている請求項1に記載のレゾルバ。 - 前記検出用ステータを周方向に沿って見たとき、前記検出用ステータの径方向について、前記非最大幅巻線の中心位置が前記最大幅巻線の中心位置と一致している請求項2に記載のレゾルバ。
- 前記第1の検出巻線群及び前記第2の検出巻線群の少なくともいずれかには、正方向に巻かれた前記検出巻線である正方向巻線と、逆方向に巻かれた前記検出巻線である逆方向巻線とが含まれており、
前記正方向巻線の巻数の総和と、前記逆方向巻線の巻数の総和とが、互いに等しくなっている請求項1~請求項3のいずれか一項に記載のレゾルバ。 - 前記励磁巻線の極対数は、1以上の整数であるMとされ、
前記突極の数は、1以上の整数であるNとされており、
前記第1の巻線及び前記第2の巻線のそれぞれの巻数の空間分布が、空間|M±N|次の正弦波で表される関数と、前記空間|M±N|次の正弦波の振幅と等しい振幅を持つ空間|M-|M±N||次の正弦波で表される関数との和によって得られ、
前記励磁巻線の極対数Mは、9であり、
前記突極の数Nは、15、24又は30である請求項1~請求項4のいずれか一項に記載のレゾルバ。 - 前記励磁巻線の極対数は、1以上の整数であるMとされ、
前記突極の数は、1以上の整数であるNとされており、
前記第1の巻線及び前記第2の巻線のそれぞれの巻数の空間分布が、空間|M±N|次の正弦波で表される関数と、前記空間|M±N|次の正弦波の振幅と等しい振幅を持つ空間|M-|M±N||次の正弦波で表される関数との和によって得られ、
前記励磁巻線の極対数Mは、15であり、
前記突極の数Nは、10又は20である請求項1~請求項4のいずれか一項に記載のレゾルバ。 - 前記検出用ステータは、前記励磁巻線及び前記検出巻線のそれぞれと前記ティースとの間に介在する非磁性体をさらに有し、
前記非磁性体は、同一の前記ティースに巻かれている前記励磁巻線と前記検出巻線との間に介在する仕切り部を有している請求項1~請求項6のいずれか一項に記載のレゾルバ。 - ステータ、
前記ステータに対して回転可能なロータ、及び
請求項1~請求項7のいずれか一項に記載のレゾルバ
を備え、
前記検出用ロータは、前記ロータと一体に回転される回転電機。 - ステータと、前記ステータに対して回転可能なロータと、請求項1~請求項7のいずれか一項に記載のレゾルバとを有するモータ、及び
前記ロータの回転に伴って回転される駆動シーブ
を備え、
前記検出用ロータは、前記ロータと一体に回転されるエレベータ用巻上機。
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