1. Field of the Invention
The present invention relates to a motor which is provided with a stator core which has a noncircular outside shape, an apparatus for production of a motor, and a method for production of a motor.
2. Description of the Related Art
Known in the art is a motor which is provided with a stator core which is comprised of a plurality of stacked core sheets which are comprised of rolled magnetic steel sheets wherein the magnetic steel sheets are stacked with rolling directions made different from each other to thereby reduce cogging torque which is generated due to magnetic anisotropy of the magnetic steel sheets (for example, Japanese Patent Publication No. 2005-65479A).
The above core sheets are generally fabricated by press-working and thereby punching a hoop which is conveyed along its rolling direction. If the magnetic steel sheet which is described in the above patent publication has a regular polygonal outside shape, the maximum dimensions in the direction perpendicular to the rolling direction will differ between core sheets which are stacked so that the rolling directions differ from each other.
For this reason, if considering the case of punching out these core sheets from a common hoop, since the maximum dimension of the hoop in the direction perpendicular to the conveying direction differs, excess parts end up occurring in the hoop corresponding to the fluctuations in the maximum dimensions. Due to this, the amount of the hoop which is discarded ends up increasing. This has led to an increase in the manufacturing costs.
In one aspect of the present invention, a motor comprises a stator core which is formed by stacking a plurality of noncircular core sheets, each of which is made from a rolled magnetic steel sheet. The stator core includes a first core sheet, and a second core sheet which has an outside edge shape the same as the first core sheet. The second core sheet is stacked with respect to the first core sheet so that a rolling direction of the second core sheet becomes a direction rotated from a rolling direction of the first core sheet about a center axis of the stator core by an angle of an odd multiple of 360°/(number of poles of the motor×2).
The outside edge of the first core sheet has a first and second sides at both ends in a direction perpendicular to the rolling direction of the second core sheet, wherein the third and fourth sides are parallel to the rolling direction of the first core sheet. The outside edge of the second core sheet has a third and fourth sides at both ends in a direction perpendicular to the rolling direction of the second core sheet, wherein the third and fourth sides are parallel to the rolling direction of the second core sheet. The dimension in the direction perpendicular to the rolling direction of the first core sheet between the first side and the second side, and the dimension in the direction perpendicular to the rolling direction of the second core sheet between the third side and the fourth side are the same.
Each of the first core sheet and the second core sheet may have a shape which is line symmetric about an imaginary line which radially extends from its center axis to a direction rotated from its rolling direction about the center axis of the stator core by an angle expressed by (360°×(a+0.5))/(number of poles of the motor×2) where “a” is a whole number.
In another aspect of the present invention, a motor comprises a stator core which is formed by stacking a plurality of core sheets, each of which is made from a rolled magnetic steel sheet. The core sheet includes a noncircular outer sheet which has a hole; and a first and second inner sheets fit into the hole so as to be arranged at radially inside of the outer sheet.
The second inner sheet is stacked with respect to the first inner sheet so that its rolling direction becomes a direction rotated from the rolling direction of the first inner sheet about the center axis of the stator core by a predetermined angle.
Each of the hole, the first inner sheet, and the second inner sheet may have a regular b-gonal shape where “b” is a natural number. This natural number “b” may be one of divisors of the number of slots of the motor whereby the angle expressed by 360°/b becomes a value closest to 360°/(number of poles of the motor×2).
In this case, the second inner sheet may be stacked with respect to the first inner sheet so that its rolling direction becomes a direction rotated from the rolling direction of the first inner sheet about the center axis of the stator core by an angle of 360°/b.
Each of the hole, the first inner sheet, and the second inner sheet may be circular. In this case, the second inner sheet may be stacked with respect to the first inner sheet so that its rolling direction becomes a direction rotated from the rolling direction of the first inner sheet about the center axis of the stator core by an angle of 360°/(number of poles of the motor×2).
In still another aspect of the present invention, an apparatus for producing a motor comprising a stator core formed by stacking a plurality of core sheets, each of which is made from a rolled magnetic steel sheet, comprises a punch die for punching out the core sheet from a conveyed hoop; and a rotation drive part for rotating the punch die about an axis of the punch die.
The rotation drive part rotates the punch die from a first position to a second position rotated from the first position about the axis of the punch die by a predetermined angle. The punch die includes a punch and a die which receives the punch. The outer circumferential surface of the punch has a first and second flat surfaces at both ends in a direction perpendicular to the conveying direction of the hoop when arranged at a first position, wherein the first and second flat surfaces become parallel to the conveying direction.
The outer circumferential surface of the punch also includes a third and fourth flat surfaces at both ends in a direction perpendicular to the conveying direction of the hoop when arranged at a second position, wherein the third and fourth flat surfaces become parallel to the conveying direction. The die has an inner circumferential surface which corresponds to the outer circumferential surface of the punch. The predetermined angle may be an odd multiple of 360°/(number of poles of the motor×2).
In still another aspect of the present invention, the method of producing the motor including the stator core, comprises conveying a hoop along a rolling direction of the hoop; punching out the first core sheet from the hoop; punching out the second core sheet from the hoop; and stacking the first core sheet and the second core sheet each other so that the rolling direction of the second core sheet becomes a direction rotated from the rolling direction of the first core sheet about a center axis of the stator core by an angle of an odd multiple of 360°/(number of poles of the motor×2).
The steps of punching out the first core sheet and punching out the second core sheet may be performed with a punch die. The method may further comprise rotating the punch die about a center axis of the punch die by an angle of an odd multiple of 360°/(number of poles of the motor×2), before punching out the second core sheet.
In still another aspect of the present invention, the method of producing the motor including the stator core, comprises conveying a hoop along a rolling direction of the hoop; punching out the plurality of core sheets from the hoop; rotating a first core sheet of the plurality of core sheets about the below imaginary line by 180°; and stacking the first core sheet on a second core sheet of the plurality of core sheets. Here, each of the plurality of core sheets has a shape which is line symmetric about the imaginary line which radially extends from its center axis to a direction rotated from the conveying direction of the hoop about the center axis of the core sheet by an angle expressed by (360°×(a+0.5))/(number of poles of the motor×2) where “a” is a whole number.
In still another aspect of the present invention, the method of producing the motor including the stator core, comprises conveying a hoop along a rolling direction of the hoop; punching out the first inner sheet from the hoop; and fitting the first inner sheet into a hole which is formed in the hoop by punching out the first inner sheet. Further, this method comprises punching out a second inner sheet from the hoop; rotating the second inner sheet about a center axis of the second inner sheet; and fitting the rotated second inner sheet into a hole which is formed in the hoop by punching out the second inner sheet.
Further, this method comprises punching out a first outer sheet so as to enclose the hole in which the first inner sheet is fit; punching out a second outer sheet so as to enclose the hole in which the second inner sheet is fit; and stacking the first outer sheet and the second outer sheet each other.
The step of punching out the first inner sheet and the step of punching out the second inner sheet may be performed with a punch die. In this case, the method may further comprise rotating the punch die about a center axis thereof by an angle of an odd multiple of 360°/(number of poles of the motor×2), before punching out the second inner sheet.
Each of the hole, the first inner sheet, and the second inner sheet may have a regular b-gonal shape where “b” is a natural number. In this case, in the step of rotating the second inner sheet about the center axis of the second inner sheet, the second inner sheet may be rotated by an angle expressed by 360°/b about the center axis.
The above and other objects, features, and advantages of the present invention will become further clearer by the following description of the preferred embodiments given while referring to the attached drawings, in which
Below, embodiments of the present invention will be explained in detail based on the drawings. Referring to
The motor 10 is an 8-pole, 36-slot motor includes a stator 11 and a rotor 12 rotatably supported at radially inside (inside in the radial direction) of the stator 11. The rotor 12 includes a columnar shaft 13 extending in the axial direction; and a plurality of magnets 14 fixed at radially outside (outside in the radial direction) of the shaft 13. The stator 11 includes a stator core 20 having a noncircular outside shape; and a coil (not shown) wound around the teeth of the stator core 20.
Next, referring to
Next, referring to
The first core sheet 24 is made from a magnetic steel sheet rolled in the direction shown by the arrow 48 in
The side 34 and side 44 of the first core sheet 24 are located at both ends in the direction 50 perpendicular to the rolling direction 48 of the first core sheet 24, and extend in the top-bottom direction in
The first core sheet 24 includes a plurality of teeth 55 at its inside edge, wherein the teeth 55 are formed so as to be aligned at equal intervals in the circumferential direction. A slot 59 is formed between two teeth 55 adjoining each other in the circumferential direction. A coil is wound around each of the teeth 55. In the present embodiment, a total of 36 slots 59 are formed by the total 36 teeth 55.
The second core sheet 26 has a shape the same as the first core sheet 24. Specifically, the second core sheet 26 is a thin sheet member having a decagonal outside edge which is defined by a side 54, side 56, side 58, side 60, side 62, side 64, side 66, side 68, side 70, and side 72. The side 54, side 56, side 58, side 60, side 62, side 64, side 66, side 68, side 70, and side 72 of the second core sheet 26 respectively correspond to the side 28, side 30, side 32, side 34, side 36, side 38, side 40, side 42, side 44, and side 46 of the first core sheet 24.
Here, the second core sheet 26 is made from a magnetic steel sheet rolled in the direction shown by the arrow 74 in
The side 60 and side 70 of the second core sheet 26 are located at both ends in a direction perpendicular to the imaginary line 78 (same direction as the direction 50 in
Therefore, the side 58 intersects the side 60 so as to form an angle of (180°-θ1). Similarly, the side 68 intersects the side 70 so as to form an angle of (180°-θ1). These side 58 and side 68 define the both ends of the second core sheet 26 in the direction 76. Therefore, the maximum dimension of the second core sheet 26 in the direction 76 is determined by the dimension 80 between the side 58 and the side 68.
In the present embodiment, the dimension 52 and the dimension 80 are set to be the same. Similar to the first core sheet 24, the second core sheet 26 has a total of 36 teeth 82 formed so as to be aligned at equal intervals in the circumferential direction. A total of 36 slots 84 are formed between the teeth 82 adjoining each other in the circumferential direction.
The stator core 20 shown in
This angle θ1 is defined as an equation: θ1=(360°×n2)/(n1×2). Here, n1 is the number of poles of the motor 10, while n2 is an odd number. By setting the angle θ1 in this way, it is possible to reduce the cogging torque which is generated dependent on the number of poles of the motor 10. For example, in the case of the present embodiment, the motor 10 has eight poles, that is, n1=8. If n2=1, the angle θ1 becomes 22.5°.
The decagonal outside edge shapes of the first core sheet 24 and the second core sheet 26 are formed based on regular octagonal shapes. Specifically, the outside edges of the first core sheet 24 and the second core sheet 26 are formed by trimming the parts shown by the broken lines in
Next, referring to
The first core sheet 92 is a thin sheet member having a decagonal outside edge which is defined by a side 96, side 98, side 100, side 102, side 104, side 106, side 108, side 110, side 112, and side 114. The first core sheet 92 is made from a magnetic steel sheet rolled in the direction shown by the arrow 116 in
The rolling direction 116 is a direction rotated from the imaginary line 118 in
The first core sheet 92 according to the present embodiment has an outside edge shape which is line symmetric about the imaginary line 118. Specifically, the side 114, side 112, side 110, and side 108 of the first core sheet 92 are respectively line symmetric to the side 98, side 100, side 102, and side 104 with respect to the imaginary line 118.
The side 100 and side 110 of the first core sheet 92 are located at both ends in the direction 120 perpendicular to the rolling direction 116 of the first core sheet 92, and extend so as to be parallel to the rolling direction 116. These side 100 and side 110 define the both ends of the first core sheet 92 in the direction 120.
Therefore, the maximum dimension of the first core sheet 92 in the direction 120 is determined by the dimension 122 between the side 100 and the side 110. Similar to the above-mentioned embodiment, the first core sheet 92 has a total of 36 teeth 124. Between the teeth 124, a total of 36 slots 126 are formed.
The second core sheet 94 has a shape the same as the first core sheet 92. Specifically, the second core sheet 94 is a thin sheet having a decagonal outside edge which is defined by a side 128, side 130, side 132, side 134, side 136, side 138, side 140, side 142, side 144, and side 146. The second core sheet 94 is made from a magnetic steel sheet rolled in the direction shown by an arrow 148 in
The rolling direction 148 is a direction rotated from the imaginary line 150 in
The second core sheet 94 has an outside edge shape which is line symmetric about the imaginary line 150. Specifically, the side 146, side 144, side 142, and side 140 of the second core sheet 94 are respectively line symmetric to the side 130, side 132, side 134, and side 136 with respect to the imaginary line 150.
The side 134 and side 144 of the second core sheet 94 define both ends of the second core sheet 94 in the direction 152 perpendicular to the rolling direction 148, and extend in parallel with the rolling direction 148. The maximum dimension of the second core sheet 94 in the direction 152 is determined by the dimension 154 between the side 134 and the side 144 in the direction 152. Here, in the present embodiment, the dimension 122 and the dimension 154 are set to be the same. In the same way as the first core sheet 92, the second core sheet 94 has a total of 36 teeth 156. Between the teeth 156, a total of 36 slots 158 are formed.
By stacking the first core sheets 92 and the second core sheets 94 in the axial direction in the same way as the stator core 20 shown in
In the present embodiment, these angles θ2 and θ3 are defined as an equation: θ2=θ3=(360°×(n3+0.5))/(n1×2). Here, n1 is the number of poles of the motor, while n3 is an integer. By setting the angles θ2 and θ3 in this way, it is possible to reduce the cogging torque which is generated dependent on the number of poles of the motor 10. As a specific example, if making the number of poles of the motor n1=8 and making n3=0, the angles θ2 and θ3 become 11.25°. Therefore, the angle between the rolling directions 116 and 148 becomes 22.5°.
The octagonal outside edge shapes of the first core sheet 92 and the second core sheet 94 can be formed based on regular octagonal shapes. Specifically, the outside edges of the first core sheet 92 and the second core sheet 94 are formed by trimming the parts shown by the broken lines of
Similarly, the vertexes 162 at the lower-right side in
Next, referring to
The first core sheet 174 includes an outer sheet 180 having a hole 178 at its center; and a first inner sheet 182 fit into the hole 178 so as to be arranged radially inside of the outer sheet 180. Further, the second core sheet 176 includes an outer sheet 180 the same as the first core sheet 174; and a second inner sheet 184 fit into the hole 178 so as to be arranged radially inside of the outer sheet 180.
Each of the outer sheets 180 included in each of the first core sheet 174 and the second core sheet 176 is a thin sheet having a regular octagonal outside edge, and includes a circular hole 178 having a predetermined diameter at its center. The outer sheets 180 are made from a magnetic steel sheet rolled in a predetermined direction.
Next, referring to
The first inner sheet 182 is made from a magnetic steel sheet rolled in the direction shown by the arrow 190 in
The second inner sheet 184 has the same shape as the first inner sheet 182. Specifically, the second inner sheet 184 has a circular outside edge with the same diameter as the first inner sheet 182, and includes a total of 36 teeth 194 at its inside edge. Between these teeth 194, a total of 36 slots 196 are formed.
The second inner sheet 184 is made from a magnetic steel sheet rolled in the direction shown by the arrow 198 in
As explained above, each of the first core sheets 174 shown in
At this time, the first core sheets 174 and the second core sheets 176 are stacked so that the imaginary lines 192 of the first inner sheets 182 shown in
Similar to the above-mentioned angle θ1, the angle θ4 is defined as the equation: θ4=θ1=(360°×n2)/(n1×2). By setting the angle θ4 in this way, it is possible to reduce the cogging torque which is generated dependent on the number of poles of the motor 10. For example, in the case of the present embodiment, the angle θ4 is 22.5°.
Next, referring to
The first core sheet 204 includes an outer sheet 210 having a hole 208 at its center; and a first inner sheet 212 fit into the hole 208 so as to be arranged radially inside of the outer sheet 210. Further, the second core sheet 206 includes an outer sheet 210 the same as the first core sheet 204; and a second inner sheet 214 fit into the hole 208 so as to be arranged radially inside of the outer sheet 210. Each of the outer sheets 210 included in each of the first core sheet 204 and the second core sheet 206 is a thin sheet having a regular octagonal (i.e., regular “8”-gonal) outside edge, and includes a regular octadecagonal (i.e., regular “18”-gonal) hole 208 at its center. The outer sheet 210 is made from a magnetic steel sheet rolled in a predetermined direction.
Next, referring to
The first inner sheet 212 is made from a magnetic steel sheet rolled in the direction indicated by the arrow 220 in
The second inner sheet 214 has a shape the same as the first inner sheet 212. Specifically, the second inner sheet 214 has the same regular octadecagonal outside edge as the first inner sheet 212, and includes a total of 36 teeth 224 at its inside edge. Between these teeth 224, a total of 36 slots 226 are defined.
In the present embodiment, since the number of slots is “36,” the slots 226 of the second inner sheet 214 are aligned at equal intervals in the circumferential direction at angles of 10° about the axis O1. More specifically, as shown in
Similarly, the angle θ6 between the imaginary line 232 and the imaginary line 234 is also 10°. The imaginary line 234 radially extends from the axis O1 so as to pass through the center of the slot 226d adjacent to the slot 226c in one circumferential direction (counterclockwise direction as seen from front side of
Here, the second inner sheet 214 is made from a magnetic steel sheet rolled in a direction of the imaginary line 234, that is, the direction shown by the arrow 228 in
As explained above, in the present embodiment, each of the hole 208 of the outer sheet 210, the first inner sheet 212, and the second inner sheet 214 has a regular octadecagonal shape (i.e., regular “18”-gonal shape). This number of “18” is determined by a method explained below.
Here, assume that the hole 208, the first inner sheet 212, and the second inner sheet 214 are regular n5-gonal shapes (n5 is a natural number). In this case, this natural number n5 is selected to be one of divisors of the number of slots of the motor whereby the angle θ7 expressed by 07=360°/n5 becomes a value the closest to the angle θ8 expressed by θ8=360°/(n1×2). Here, n1 shows the number of poles of the motor, as in the above-mentioned embodiment.
More specifically, since the number of slots is “36” in the present embodiment, the divisors thereof include 1, 2, 3, 4, 6, 9, 12, 18, and 36. Here, if making n5=12, θ7=30°. Further, if n5=18, θ7=20°. Further, if n5=36, θ7=10°. On the other hand, the number of poles of the motor of the present embodiment is “8,” so θ8=22.5°.
Therefore, as the number closest to this angle θ8=22.5°, n5best=18 is selected, thereby each of the hole 208, the first inner sheet 212, and the second inner sheet 214 according to the present embodiment are formed into a regular octadecagon shape. The above-mentioned angle θ5 is set as θ5=360°/n5best=20° using the thus selected n5best=18. Note that, the effect of this configuration will be explained later.
As explained above, each of the first core sheets 204 is configured by fitting a first inner sheet 212 into a hole 208 of an outer sheet 210. Further, each of the second core sheets 206 is configured by fitting a second inner sheet 214 into a hole 208 of an outer sheet 210. The stator core 200 shown in
At this time, the first core sheets 204 and the second core sheets 206 are stacked so that the imaginary lines 222 of the first inner sheets 212 shown in
Next, referring to
The apparatus 250 is provided with a first punch die 252; a first power generation apparatus 254 for driving the first punch die 252; a second punch die 256; a second power generation apparatus 258 for driving the second punch die 256; a rotation drive part 260 for rotating the second punch die 256 about the axis O2 of the second punch die 256; and a controller 262 for controlling the first power generation apparatus 254, the second power generation apparatus 258, and the rotation drive part 260.
The first punch die 252 and the second punch die 256 are for press working the hoop 266 conveyed along the direction shown by the arrow 264 in
The first punch die 252 is for forming the inside edge of the first core sheet 24, which includes the teeth 55 and slots 59 shown in
The punch 268 has an outer circumferential surface 272 corresponding to the inside edge shapes of the first core sheet 24 and the second core sheet. Further, the die 270 has an inner circumferential surface 274 corresponding to the outer circumferential surface 272 of the punch 268. The first power generation apparatus 254 is configured by e.g. a hydraulic cylinder, and drives the punch 268 toward the die 270 in response to a command from the controller 262.
The second punch die 256 is arranged at a downstream side of the first punch die 252, and punches out the first core sheet 24 and the second core sheet 26, each of which has a decagonal outside edge shown in
Next, referring to
Specifically, the outer circumferential surface 280 includes a flat surface 282, flat surface 284, flat surface 286, flat surface 288, flat surface 290, flat surface 292, flat surface 294, flat surface 296, flat surface 298, and flat surface 300. These flat surfaces 282, 284, 286, 288, 290, 292, 294, 296, 298, and 300 are respectively arranged so as to correspond to the sides 28, 30, 32, 34, 36, 38, 40, 42, 44, and 46 of the first core sheet 24. The arrows 264 in
More specifically, the punch 276 is arranged with respect to the conveying direction 264 so that the direction of the imaginary line 306 and the conveying direction 264 match when arranged at the first position. This imaginary line 306 corresponds to the above-mentioned imaginary line 29, and extends from the axis O2 in the radial direction so as to pass through the centers of the flat surfaces 282 and 292.
As shown in
The above-mentioned rotation drive part 260 rotates the punch 276 from the first position shown in
Therefore, when the punch 276 is arranged at the second position, the maximum dimension of the punch 276 in the direction 302 is determined by the dimension 308 between the flat surfaces 286 and 296. Here, the dimension 304 and the dimension 308 are set to be the same. The die 278 which receives the punch 276 has an inner circumferential surface 309 corresponding to the outer circumferential surface 280 of the punch 276. The rotation drive part 260 rotates the die 278 in synchronization with the punch 276 so as to become the same angle and direction as the punch 276.
Next, referring to
Next, the controller 262 sends a command to the power generation apparatus 258 so as to drive the punch 276 of the second punch die 256 toward the die 278. Thereby, as shown in the section (b) of
Next, the controller 262 sends a command to the rotation drive part 260 so as to rotate the punch 276 from the first position shown in
Next, the controller 262 sends a command to the power generation apparatus 258 so as to drive the punch 276 of the second punch die 256 toward the die 278. Thereby, as shown in section (b) of
As explained above, the maximum dimensions 52 and 80 of the first core sheet 24 and the second core sheet 26 in directions perpendicular to the conveying direction 264 (that is, the rolling directions 48 and 74) become the same. Due to this, it is possible to punch out the first core sheet 24 and the second core sheet 26 from the hoop 266 with the constant width 314, so it is possible to efficiently use the hoop 266 to fabricate the first core sheet 24 and the second core sheet 26. Due to this, it is possible to reduce the amount of waste of the hoop 266, so it is possible to produce the stator core 20 capable of reducing the cogging torque by a high efficiency while reducing the manufacturing costs.
Further, the sides 34 and 44 of the first core sheet 24 located at the both ends in the direction perpendicular to the conveying direction 264 extend in parallel to the conveying direction 264. In addition, the sides 58 and 68 of the second core sheet 26 located at the both ends in the direction perpendicular to the conveying direction 264 also extend in parallel to the conveying direction 264.
According to this configuration, it is possible to increase areas occupied by the first core sheet 24 and the second core sheet 26 in the width 314 of the hoop 266. Due to this, it is possible to more efficiently use the hoop 266, so it is possible to further reduce the amount of waste of the hoop 266.
Next, referring to
The apparatus 320 includes a first punch die 322; a first power generation apparatus 324 which drives the first punch die 322; a second punch die 326; a second power generation apparatus 328 which drives the second punch die 326; a third punch die 330; a third power generation apparatus 332 which drives the third punch die 330; a rotation drive part 335 which rotates the first punch die 322; and a controller 333 which controls a first power generation apparatus 324, a second power generation apparatus 328, a third power generation apparatus 332, and the rotation drive part 335.
The first punch die 322, the second punch die 326, and the third punch die 330 are for press-working the hoop 266 conveyed in the conveying direction 264. The hoop 266 is conveyed along the rolling direction. The first punch die 322 is for forming the inside edges of the first inner sheet 182 and the second inner sheet 184, wherein the inside edge includes teeth 186, 194 and slots 188, 196 as shown in
The punch 334 has an outer circumferential surface 338 which corresponds to the inside edge shapes of the first inner sheet 182 and the second inner sheet 184. Further, the die 336 has an inner circumferential surface 340 which corresponds to the outer circumferential surface 338 of the punch 334. The first power generation apparatus 324 is configured by e.g. a hydraulic cylinder, and drives the punch 334 toward the die 336 in response to a command from the controller 333.
The second punch die 326 is arranged at the downstream side of the first punch die 322, and punches out the first inner sheet 182 and the second inner sheet 184, each of which has a circular outside edge shown in
The third punch die 330 is arranged at the downstream side of the second punch die 326, and punches out the outer sheet 180 having a regular octagonal outside edge as shown in
Next, referring to
At the initial stage, the punch 334 is arranged at the first position shown in
The rotation drive part 335 rotates the punch 334 about the axis O3 in the circumferential direction from the first position shown in
Next, referring to
Next, the controller 333 sends a command to the power generation apparatus 328 so as to drive the punch 342 of the second punch die 326 toward the die 344. Thereby, as shown in section (b) of
Next, the controller 333 sends a command to the power generation apparatus 332 so as to drive the punch 350 of the third punch die 330 toward the die 352. Thereby, as shown in section (c) of
Next, the controller 333 sends a command to the rotation drive part 335 so as to rotate the punch 334 of the first punch die 322 from the first position shown in
Next, the controller 333 sends a command to the power generation apparatus 328 so as to drive the punch 342 of the second punch die 326 toward the die 344. Thereby, as shown in section (b) of
Then, the rotated second inner sheet 184 is again fit into the hole 178 formed at the hoop by punching out the second inner sheet 184. The rolling direction 198 of the thus fit second inner sheet 184 becomes a direction rotated from the conveying direction 264 (i.e., direction of imaginary line 199) about the axis O1 by the angle θ4, as shown in section (c) of
Next, the controller 333 sends a command to the power generation apparatus 332 so as to drive the punch 350 of the third punch die 330 toward the die 352. Thereby, as shown in section (c) of
Thus, according to the present embodiment, the core sheets 174 and 176, which constitute the stator core 170, are divided into regular octagonal outer sheets 180 and circular inner sheets 182 and 184, and stacked after rotating only the circular second inner sheets 184. Therefore, the outer sheets 180 are common members among the core sheets 174 and 176, so it is possible to punch out the outer sheets 180 from the hoop 266 of a constant width 314.
That is, when punching out the core sheets 174 and 176, it is possible to make the maximum dimensions of the core sheets 174 and 176 in the direction perpendicular to the conveying direction 264 constant. Due to this, it is possible to efficiently use the hoop 266 to fabricate the first core sheet 174 and the second core sheet 176. Therefore, it is possible to reduce the amount of waste of the hoop 266, so it is possible to produce a stator core 170 capable of reducing the cogging torque at a high efficiency while reducing the manufacturing costs.
Next, referring to
At step S1, a hoop 266 is conveyed in a conveying direction 264. For example, the hoop 266 is conveyed in the conveying direction 264 by a belt conveyor or other conveyance apparatus. At this time, the rolling direction of the hoop 266 and the conveying direction 264 match with each other.
At step S2, a first core sheet 24 is punched out from the hoop 266. For example, when fabricating the stator core 20 using the apparatus 250 shown in
At step S3, the second punch die 256 is rotated. Specifically, the controller 262 of the apparatus 250 sends a command to the rotation drive part 260 so as to rotate the punch 268 from the first position to the second position about the axis O2.
At step S4, a second core sheet 26 is punched out from the hoop 266. Specifically, the controller 262 of the apparatus 250 drives the first punch die 252 so as to form the inside edge 312 (section (a) of
Next, referring to
At step S11, a hoop 266 is conveyed so that the conveying direction 264 and the rolling direction match with each other. At step S12, a plurality of core sheets 92 are punched out from the hoop 266. Specifically, each core sheet 92 is punched out by a punch die having a circumferential surface corresponding to the outside edge shape of the first core sheet 92 shown in
At this time, the punch die is rotated so that the imaginary line of the punch die, which corresponds to the imaginary line 118 shown in
At step S13, a part of the plurality of core sheets 92 punched out at step S12 is rotated 180° about the imaginary line 118. That is, the part of the core sheets 92 are flipped over at step S12. At step S14, the part of the core sheets 92 flipped over at step S13 is stacked at the core sheets 92 which are not flipped over.
Here, as explained above, the core sheet 92 shown in
According to the present embodiment, both the first core sheet 92 and the second core sheet 94 can be punched out from the hoop 266 with a constant width 314 by a punch die rotated relative to the conveying direction 264 by the angle θ2 (=11.25°). Accordingly, the maximum dimensions (i.e., dimensions 122 and 154) of the core sheets 92 and 94 in directions perpendicular to the conveying direction 264 can be made constant.
Therefore, it is possible to efficiently use the hoop 266, thereby reduce the amount of waste of the hoop 266. For this reason, it is possible to produce a stator core 90 capable of reducing the cogging torque with a high efficiency while reducing the manufacturing costs.
Next, referring to
At step S21, the hoop 266 is conveyed along the rolling direction in the conveying direction 264. At step S22, the first inner sheets 182 and 212 are punched out from the hoop 266. For example, when producing the stator core 170 with the apparatus 320 shown in
On the other hand, when producing the stator core 200 shown in
At step S23, the first inner sheet 182, 212 is fit into the hole 178, 208 formed at the hoop 266 by punching out the first inner sheet 182, 212. For example, when producing the stator core 170 shown in
At step S24, the second inner sheet is punched out from the hoop 266. For example, when producing the stator core 170 shown in
Then, the controller 333 drives the second punch die 326 to punch out the second inner sheet 184 to enclose the inside edge 366 at its center (section (b) of
At step 525, the second inner sheet is rotated about the center axis of the second inner sheet. Specifically, when producing the stator core 170 shown in
At step S26, the second inner sheet, which was rotated at step S25, is fit into the hole 178, 208 formed in the hoop 266 at step S24. Specifically, when producing the stator core 170 shown in
On the other hand, when producing the stator core 200 shown in
At step S27, the first outer sheet 180, 210 is punched out. Specifically, when producing the stator core 170 shown in
At step S28, the second outer sheet 180, 210 is punched out. Specifically, when producing the stator core 170 shown in
At step S29, the outer sheets 180, which were fabricated at step S27 and into which the first inner sheets 182, 212 are fit, and the other outer sheets 180, which were fabricated at step S28 and into which the second inner sheets 184 and 214 are fit, are stacked each other. As a result, the stator core 170 or 200 shown in
When producing the stator core 200 shown in
Therefore, at step S25, in order to rotate the inner sheet by the angle θ5, the user can rotate the inner sheet by exactly the amount of the external angle of the regular octadecagon (i.e., equal to the angle between adjoining sides). Therefore, the user can easily understand the angle for rotation, thereby the operation becomes easy. Further, the angle θ5 is close to the angle θ7, so it is possible to reduce the cogging torque generated due to the number of poles of the motor.
Note that, when producing the stator core 200 shown in
The thus configured stator core 200 includes a second inner sheet 214, the rolling direction 228 of which differs by 20° relative to the first inner sheet 212; a second inner sheet 214, the rolling direction 228 of which differs by 40° relative to the first inner sheet 212; a second inner sheet 214, the rolling direction 228 of which differs by 60° relative to the first inner sheet 212; . . . and a second inner sheet 214, the rolling direction 228 of which differs by (θ5×n6)° relative to the first inner sheet 212.
By configuring the stator core 200 in this way, it is possible to more effectively reduce the cogging torque. Further, in order to fabricate such a stator core 200, at step S25, the user may rotate the inner sheets by the angle (θ5×n) when performing the n-th step S25. For example, the user may increase the angle for rotation of the inner sheet in accordance with the number of times of performing step S25 such as to 20° at first step S25, 40° at second step S25, . . . and (θ5×n)° at n-th step S25.
Note that, in the above-mentioned embodiments, the case of stacking a plurality of first core sheets at one side in the axial direction and stacking a plurality of second core sheets at the other side of the first core sheets in the axial direction will be explained. However, the invention is not limited to this. The first core sheets and the second core sheets may be alternately stacked one at a time or may be stacked any number at a time.
Further, in the above-mentioned embodiments, the case of forming the stator core by stacking first core sheets each comprised of an outer sheet and a first inner sheet and second core sheets each comprised of an outer sheet and a second inner sheet was explained. However, the invention is not limited to this. The stator core need only be provided with outer sheets and first and second inner sheets which are arranged at the insides of the outer sheets in the radial direction. The thicknesses of the outer sheets and the first and the second inner sheets may also differ. That is, it is also possible to form a core sheet comprised of one outer sheet and one inner sheet.
As explained above, according to the present invention, it is possible to punch out the first core sheet and the second core sheet from a hoop of a constant width, so it is possible to efficiently use a hoop to fabricate the first core sheet and the second core sheet. For this reason, it is possible to reduce the amount of waste of the hoop, so it is possible to produce a stator core which can reduce the cogging torque at a high efficiency while reducing the manufacturing costs.
Above, the present invention was explained through embodiments of the present invention, but the above embodiments do not limit the invention relating to the claims. Further, all combinations of features which were explained in the embodiment are not necessarily essential for the invention. Further, the above embodiments can be changed or improved in various ways as clear to a person skilled in the art. Such changed or improved embodiments are also included in the technical scope of the present invention as clear from the claim language.
Further, it should be noted that the operations, routines, steps, stages, and other processing in the apparatus, system, program, and method in the claims, specification, and drawings, unless particularly clearly indicated by “before”, “in advance of”, etc. or the output of prior processing being used for later processing, can be realized in any order. In the flow of operations in the claims, specification, and drawings, even if explained using “first”, “next”, “then” etc. for convenience, this does not mean the execution in this order is essential.
Number | Date | Country | Kind |
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2014-007259 | Jan 2014 | JP | national |