This application is based on Japanese Patent Application No. 2017-73669 filed on Apr. 3, 2017, the disclosure of which is incorporated herein by reference.
The present disclosure relates to a rolling bending method. The present disclosure further relates to a rolling bending apparatus.
A rolling bending process is known as a manufacturing method for a pressed component in an annular shape. In the rolling bending process, a steel strip is rolled with an inclined roller, and the steel strip is bent in the board width direction. Patent Literature 1 teaches a method for manufacturing a stator of a rotary device by performing a rolling bending work.
(Patent Literature 1)
Japanese published unexamined application No. 2006-217692
It is noted that, the characteristics of the material of the steel strip such as yield stress may vary. Because of the variation in such as yield stress, the steel strip, which has been processed with the rolling bending work, may vary in its curvature.
It is an object of the present disclosure to produce a rolling bending method. It is another object of the present disclosure to produce a rolling bending apparatus.
According to an aspect of the present disclosure, a rolling bending method is for rolling a steel strip between a driving roller and a compression roller while bending the steel strip in a width direction of the steel strip. The method comprises feeding, in a feeding process, the steel strip between the driving roller and the compression roller. The method further comprises compressing, in a rolling process, the steel strip by using the driving roller and the compression roller to generate a stress greater than a yield stress in the steel strip to elongate one periphery portion of the steel strip more than an other periphery portion of the steel strip in a sending direction. The one periphery portion is on one side in the width direction of the steel strip. The other periphery portion is on an other side in the width direction. The method further comprises sending out, in a sending-out process, the steel strip from a work space between the driving roller and the compression roller. The compression roller includes a first contact portion and a second contact portion. The first contact portion is to compress the steel strip. The second contact portion extends from an end of the first contact portion in an axial direction of the compression roller. The end of the first contact portion has an outer diameter less than an outer diameter of the second contact portion.
According to another aspect of the present disclosure, a rolling bending apparatus is configured to roll a steel strip while bending the steel strip in a width direction of the steel strip. The rolling bending apparatus comprises a driving roller configured to receive a torque from an actuator to feed the steel strip. The rolling bending apparatus further comprises a compression roller including a first contact portion and a second contact portion. The first contact portion is configured to compress the steel strip. The second contact portion extends from an end of the first contact portion in an axial direction of the compression roller. The end of the first contact portion has an outer diameter less than an outer diameter of the second contact portion. The rolling bending apparatus further comprises a compression part configured to move the compression roller toward the driving roller to cause the first contact portion and the second contact portion to generate a stress greater than a yield stress in the steel strip.
The above and other objects, features and advantages of the present invention will become more apparent from the following detailed description made with reference to the accompanying drawings. In the drawings:
As follows, embodiments of a rolling bending process and a rolling bending apparatus according to the present disclosure will be described with reference to drawings. In the following multiple embodiments, the same reference numeral will be denoted to the same element, and description of the same element will be omitted.
The rolling bending apparatus will be described with reference to
As shown in
The compression part 16 is configured with, for example, an air cylinder and/or a hydraulic system. The compression part 16 is configured to move the compression roller 12 in the vertical direction thereby to change the length between the driving roller 11 and the compression roller 12 in the vertical direction. In this way, the compression part 16 is configured to change a compression force exerted on the steel strip 20. The feeder guide 19 is configured to position the steel strip 20 with respect to the board width direction (width direction) and to send out the steel strip 20 smoothly with reduced rattle. In the following description, the board width direction is a direction perpendicular to the sending direction. The board width direction is within a board surface. The uncoiler 50 is wound with the steel strip 20. The uncoiler 50 is configured to send out the steel strip 20 continuously at a constant speed. The wind-up part 51 is configured to rotate while moving downward in synchronization with a speed of the steel strip 20 being sent out. In this way, the wind-up part 51 is configured to wind the manufactured steel strip 20 in a spiral form.
Rolling work is performed on the steel strip 20 by using the driving roller 11 and the compression roller 12. The column portion 121 is directed to the projected portion 13 in a first direction. The steel strip 20 is not exerted with the compression force from the compression roller 12 on the side beyond the non-connecting surface 132 of the projected portion 13 in the first direction. Therefore, the rolling work is terminated and is not performed at the portion of the steel strip 20 on the side beyond the non-connecting surface 132. One periphery portion 28 of the steel strip 20 with respect to the board width direction is further elongated along the sending direction than the other periphery portion 29 of the steel strip 20. The elongated periphery portion 28 is on the radially outer side in a bending work. The position, at which the projected portion 13 is in contact with the steel strip 20 with respect to the board width direction, is determined for each actual product. The steel strip 20 being processed with the bending work can be laminated in a spiral form.
Subsequently, a rolling bending process will be described. The rolling bending process is to produce a product, in which the steel strip 20 is laminated in an annular form, by using the rolling bending apparatus 10 according to the present embodiment.
A preparation process at step S1 will be described. The steel strip 20 is first prepared. The steel strip 20 is to be processed with a continuous work. In order to reduce fluctuation in curvature of the product produced with the continuous work, it is necessary to maintain the thickness, the width, a yield stress and/or the like of the steel strip regularly at constant values, respectively. However, it is difficult to maintain all the figures at the constant values in reality. The steel strip 20 as prepared actually has a certain fluctuation in the thickness, the width, the yield stress, and/or the like in dependence on a production lot.
A feeding process at step S2 will be described. The steel strip 20 is drawn from the uncoiler 50 by using a driving device (not shown). The steel strip 20 being drawn is rectified in the form and is aligned at a constant position with respect to the board width direction by using the feeder guide 19. The steel strip 20 is sent into the rolling bending apparatus 10.
A rolling process at step S3 will be described. A rolling bending work is continuously performed on the steel strip 20. Parameters, such as the rotational speed of the driving roller 11, the shape of the compression roller 12, the compression force exerted in the rolling work, the working position in the steel strip 20 with respect to the board width direction, are beforehand computed for each product. Specifically, a stress generated in the steel strip 20 by using the column portion 121 is set to be greater than the yield stress of the steel strip 20. Subsequent to the rolling bending work, a portion of the steel strip 20 having rolled with the column portion 121 is on an radially outer side, and a portion of the steel strip 20 having rolled with the projected portion 13 is on an radially inner side.
A sending-out process at step S4 will be described. The steel strip 20 having processed with the rolling bending work is sent out from the rolling bending apparatus 10 and is wound around the wind-up part 51 to be in a spiral form.
A cutting process at step S5 will be described. A working length of the steel strip 20 is acquired from a counter equipped to the feeder guide 19, by multiplying a sending speed by an elapsed time, and/or the like. Subsequent to performing the rolling bending work on the steel strip 20 by a predetermined length, the steel strip 20 having processed with the rolling bending work and wound around the wind-up part 51 is cut. The steel strip 20 is removed from the wind-up part 51. Through the above-described process, the steel strip 20 is annularly laminated to be a product.
As follows, the product of the steel strip 20 will be described. As the product, the steel strip 20 has been processed with the rolling bending work by using the rolling bending apparatus 10 according to the present embodiment.
Subsequently, a relationship between the rolling bending work and the curvature of the steel strip 20 will be described.
In
In
The steel strip 20, which is processed with the rolling bending work by using the general compression roller 21, differs in the start position of the following deformation with respect to the board width direction, as the yield stress varies. Ratios of the deformation amount is represented with area ratios in
Subsequently, the steel strip 20, which has been processed with the rolling bending work by using the rolling bending apparatus 10 according to the present embodiment, will be described.
In
A follow-up deformed portion 165 represents the steel strip 20 of the yield stress A (MPa), which has caused the follow-up deformation following the concentrated deformed portion 155. A follow-up deformed portion 166 represents the steel strip 20 of the yield stress B (MPa), which has caused the follow-up deformation following the concentrated deformed portion 156. A follow-up deformed portion 167 represents the steel strip 20 of the yield stress C (MPa), which has caused the follow-up deformation following the concentrated deformed portion 157. All the follow-up deformed portions 165, 166, and 167 have started the follow-up deformation at the same point 41. The rolling work on the steel strip 20 has been terminated at the same point with respect to the board width direction, regardless of the yield stress of the steel strip 20. Therefore, even though the yield stress varies, the follow-up deformed portion starts constantly at the point 41. The follow-up deformed portions 165, 166, and 167 reduce in the amount of deformation toward the radially inside and show deformation in a shape of trailing of skirt. Since, the follow-up deformation starts at the position, the surface shapes of the follow-up deformed portions 165, 166, and 167 are similar to each other.
The first follow-up deformed portion 203 is a portion, which has deformed following the concentrated deformed portion 155 processed with the projected portion 13. The first follow-up deformed portion 203 has a thickness less than the target thickness AT. The second follow-up deformed portion 204 is a portion, which has deformed following the concentrated deformed portion 155 processed with the projected portion 13. The second follow-up deformed portion 204 has a thickness greater than the target thickness AT. The non-deformed portion 205 is a portion which has not deformed.
A thin portion 230 is a combination of the concentrated deformed portion 155 and the first follow-up deformed portion 203. The thin portion 230 has a thickness entirely less than the target thickness AT. A thick portion 231 is a combination of the second follow-up deformed portion 204 and the non-deformed portion 205. The thick portion 231 has a thickness entirely greater than the target thickness AT.
In the cross section along the direction perpendicular to the sending direction, an area (first area) 206 is surrounded by the surface line of the thin portion 230 and a surface line, which is represented by the imaginary surface 27. In the cross section, an area (second area) 207 is surrounded by the surface line of the thick portion 231 and a surface line, which is represented by the imaginary surface 27. The area 206 is substantially the same as the area 207. That is, a portion thicker than the target thickness AT and a portion thinner than the target thickness AT are balanced with each other. In other words, the portion on the radially outer side, which has caused large deformation, and the portion on the radially inner side, which has caused small deformation, compensate with each other. Consequently, the steel strip 20 are deformed on the whole by a deformation amount about the target thickness AT on average.
As follows, an effect of the rolling bending work, which is processed on the steel strip 20 by using the rolling bending apparatus 10 of the present embodiment, will be described. (a) The projected portion 13 terminates the rolling work at the intermediate point with respect to the board width direction of the steel strip 20. The present feature sets the start position of the follow-up deformed portions 165, 166, and 167 at the constant point in the steel strip 20 with respect to the board width direction, regardless of the yield stress of the steel strip 20. Therefore, even though the yield stress of the steel strip 20 varies, the feature enables to constantly maintain the ratio of the amount of deformation of the portion, which is processed with the compression roller 12, to the follow-up deformation amount, regardless of the yield stress of the steel strip 20. Therefore, even in case where the yield stress of the steel strip 20 varies, the curvature of the steel strip 20 can be maintained at a constant curvature. (b) The steel strip 20, which has been processed with the rolling bending work, includes the inclination deformed portion 145 processed with the column portion 121. The imaginary surface 27 is the extension of the surface of the inclination deformed portion 145 toward the radially inner side. The steel strip 20, which has been processed, has the rear surface 26. The target thickness AT is the length between the imaginary surface 27 and the rear surface 26 in the thickness direction. The steel strip 20, which has been processed, includes the thick portion 231 and the thin portion 230. The thick portion 231 has the thickness greater than the target thickness AT. The thin portion 230 has the thickness less than the target thickness AT. Assuming a case where, for example, the steel strip 20 causes excessive deformation beyond a target, the steel strip 20 may have an uneven thickness. Consequently, the steel strip 20, which has been processed with the rolling bending work, may cause wrinkles. To the contrary, the feature enables to cause a portion, which has deformed by the large deformation amount, and a portion, which has deformed by the small deformation amount, to offset each other. Consequently, the feature enables the steel strip 20, which has been processed, to deform on the whole by a deformation amount about the target thickness AT on average. In this way, the feature enables the rolling bending work reducing or avoiding wrinkles. (c) In the cross-section perpendicular to the sending direction of the steel strip 20, which has been processed with the rolling bending work, the area 206 is surrounded by the surface line of the thin portion 230 and the surface line, which is represented by the imaginary surface 27. In the cross section, the area 207 is surrounded by the surface line of the thick portion 231 and the surface line, which is represented by the imaginary surface 27. The area 206 is substantially the same as the area 207. That is, in the steel strip 20, an amount of a portion, which has the thickness greater than the target thickness AT, and an amount of a portion, which has the thickness less than the target thickness AT, are equal to each other. Consequently, the amount of deformation meets the target thickness AT on average. The feature enables the rolling bending work stably with less wrinkles.
As follows, the second embodiment of the present disclosure will be described with reference to
The plan view in
As follows, the rolling bending process, which is to produce the stator of the rotary device by laminating the steel strip 60 in the annular form, will be described. A preparation process at step S1 will be described. The steel strip 60, which includes the teeth portion 62, is prepared. The teeth portion 62 is worked through, for example, a stamping process by using a punch. A feeding process at step S2 will be described. The steel strip 60 is aligned with the feeder guide 19 such that the first direction coincides with the direction, which is directed from the yoke portion 61 toward the teeth portion 62. The steel strip 60 is guided and fed into the rolling bending apparatus 10 such that the projected portion 13 rolls the yoke portion 61. Step S3 to step S5 are the same as those of the first embodiment.
As follows, an effect of the manufacturing of the stator of the rotary device through the rolling bending work by using the rolling bending apparatus 10 of the present embodiment will be described. (d) The process enables to reduce fluctuation in the curvature, which is produced through the bending work, even if a yield stress characteristic of the steel strip 60 varies. Therefore, the process enables to reduce variation in the diameter of the steel strip 20, which has been rolled up. Therefore, the process enables to reduce variation in the position of the teeth portion 62 of the steel strip 60. Therefore, the process facilitates insertion of the winding into the teeth portion 62. In addition, the process enables to protect an insulation of the winding from scratching. (e) The process enables to reduce a gap between the winding and the teeth portion 62. Therefore, the process enables to increase an occupancy rate of the winding, thereby to enhance an output power of the rotary device. (f) The process enables to reduce wrinkling in the steel strip 60. Therefore, the process facilitates lamination of the steel strip 60 tightly with reduced gap, thereby to increase the density of the iron core. Therefore, the process enables to enhance an output power of the rotary device. (g) The process enables to enhance accuracy of the circularity of the wound steel strip 20, thereby to reduce an air gap to reduce a loss of a magnetic circuit. This, the process enables to enhance an output power of the rotary device.
(a) A compression roller 80 shown in
A compression roller 90 shown in
A compression roller 100 shown in
(b) In the first and second embodiments, the driving roller 11 has the cylindrical surface. In replace with this configuration, the driving roller may be a roller having an inclined surface.
(c) In the first and second embodiments, the rotational axis center X1 of the driving roller 11 and the rotational axis center X of the compression roller 12 are in parallel with each other. In replace with this configuration, the rotational axis center of the driving roller 11 and the rotational axis center of the compression roller 12 may be inclined to each other.
The processing method according to a first aspect of the present disclosure is to perform the rolling bending work on the steel strips 20 and 60. The processing method includes the feeding process S2, the rolling process S3, and the sending-out process S4. The feeding process S2 includes feeding a steel strip between the driving roller 11 and the compression roller 12. The rolling process S3 includes causing the driving roller and the compression roller to generate a stress greater than the yield stress in the steel strip and elongating one periphery portion 28 of the steel strip more than the other periphery portion 29 of the steel strip in the sending direction. The one periphery portion 28 of the steel strip is on one side with respect to the board width direction. The other periphery portion 29 of the steel strip is on the other side with respect to the board width direction. The sending-out process S4 includes sending out the steel strip from the work space between the driving roller and the compression roller. The compression roller used in the rolling process includes the first contact portion 121 and the second contact portion 13. The first contact portion 121 rolls the steel strip. The second contact portion 13 extends from the end 124 of the first contact portion in the roller axial direction. The outer diameter D1 of the end of the first contact portion and the outer diameter D2 of the second contact portion have a relationship where the outer diameter D1 is less than the outer diameter D2.
The second contact portion of the compression roller exerts a large compression force on the steel strip and forms the concentrated deformed portion. The follow-up deformed portion deforms following the concentrated deformed portion. The start position of the follow-up deformed portion is constant with respect to the board width direction of the steel strip. Therefore, the ratio of the total deformation, which is the sum of the amount of deformation of the inclination deformed portion and the amount of deformation of the concentrated deformed portion, to the amount of deformation of the follow-up deformed portion becomes constant even if the yield stress of the steel strip varies. Thus, even if the yield stress of the steel strip varies, the curvature of the steel strip, which has been processed with the rolling bending work, becomes constant.
The rolling bending apparatus 10 according to a second aspect of the present disclosure bends the steel strips 20 and 60 in the board width direction. The rolling bending apparatus 10 includes the driving roller 11, the compression roller 12, and the compression part 16. The driving roller 11 receives torque from the actuator 15 and feeds the steel strip. The compression roller 12 includes the first contact portion 121 and the second contact portion 13. The first contact portion 121 compresses the steel strip. The second contact portion 13 extends from the end 124 of the first contact portion in the roller axial direction. The outer diameter D1 of the end of the first contact portion and the outer diameter D2 of the second contact portion have the relationship where the outer diameter D1 is less than the outer diameter D2. The compression part 16 is configured to move the compression roller toward the driving roller such that the first contact portion and the second contact portion generate a stress greater than the yield stress in the steel strip.
The rolling bending apparatus causes the first contact portion and the second contact portion to generate a stress greater than the yield stress of the steel strip by using the compression part. The second contact portion thereby forms the concentrated deformed portion in the steel strip. The start position of the follow-up deformed portion, which follows the concentrated deformed portion, becomes constant with respect to the board width direction of the steel strip. The total deformation is the sum of the amount of deformation of the inclined-deformed portion, which is processed with the first contact portion, and the amount of deformation of the concentrated deformed portion. The ratio of the total deformation to the amount of deformation of the follow-up deformed portion becomes constant even if the yield stress of the steel strip varies. Therefore, even if the yield stress of the steel strip varies, the curvature of the steel strip, which has been processed with the rolling and bending work, becomes constant.
It should be appreciated that while the processes of the embodiments of the present disclosure have been described herein as including a specific sequence of steps, further alternative embodiments including various other sequences of these steps and/or additional steps not disclosed herein are intended to be within the steps of the present disclosure.
While the present disclosure has been described with reference to preferred embodiments thereof, it is to be understood that the disclosure is not limited to the preferred embodiments and constructions. The present disclosure is intended to cover various modification and equivalent arrangements. In addition, while the various combinations and configurations, which are preferred, other combinations and configurations, including more, less or only a single element, are also within the spirit and scope of the present disclosure.
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