JP3553573B2 - Manufacturing method of cylindrical stator - Google Patents

Description

[0001]
[Industrial applications]
The present invention relates to a method for manufacturing a cylindrical stator. The present invention relates to a method for manufacturing a stator (referred to as a stator core) used for, for example, an electromagnetic valve.
[0002]
[Prior art]
Conventionally, JP-A-4-365305 discloses a solenoid valve stator (solenoid stator) used for a fuel injection valve used in a diesel engine. This solenoid stator comprises a number of magnetic plates having a uniform thickness and a curved shape, and each magnetic plate is spirally arranged with respect to the central axis of the stator.
[0003]
The solenoid stator disclosed in Japanese Utility Model Laid-Open Publication No. 63-203981 has a cylindrical stator formed by arranging a large number of wedge-shaped magnetic plates radially with respect to the center of the stator. The wedge-shaped processing of the magnetic plate material is performed by a cutting method, a press, a drawing method, a sintering method, or the like.
[0004]
[Problems to be solved by the invention]
However, the stator manufacturing technology disclosed in the above publication has the following problems. In other words, when the magnetic plate material is formed into a wedge shape, if the drawing method is used, there is a problem of the processing limit and dimensional accuracy in the current technology, and if the sintering method is used, a large suction force by the solenoid valve is required. Since the maximum magnetic flux density is low, the attraction force is greatly reduced as compared with the cutting method. In addition, when the cutting method is used, the cost becomes very high when the number of magnetic plate materials is large.
[0005]
Accordingly, an object of the present invention is to provide a method for manufacturing a cylindrical stator that is easy to manufacture.
[0006]
[Means for Solving the Problems]
The method of manufacturing a cylindrical stator according to each invention described below includes a plate piece arrangement step of spirally arranging a plurality of magnetic plates having soft magnetism and having the same thickness, and an outer end of each magnetic plate by a pressing unit. Press in the direction of diameter reductionTo reduce the diameter of the magnetic plateAnd a step of reducing the diameter.
[0007]
In a preferred embodiment, the aboveIn the method for manufacturing a cylindrical stator, each of the magnetic plates is previously continuously curved in one direction in the longitudinal direction before being pressed by the pressing portion, and is curved so that its curvature is increased inside. It is characterized by having.
In a preferred embodiment, the aboveA method of manufacturing a cylindrical stator includes rotating a plurality of magnetic plates in a spiral shape and rotating the rotary table, and pressing the magnetic plates into a cylindrical shape by using a pressing unit that presses the magnetic plates in a diameter reducing direction. And it is characterized by being arranged in a spiral.
[0008]
In a preferred embodiment, the aboveIn the method for manufacturing a cylindrical stator, the magnetic plates are arranged in a cylindrical and spiral shape by using a rotation drive unit that rotates the rotary table in the spiral direction.
Claim1 describedManufacturing method of cylindrical statorIs moreA plate forming step of forming a magnetic plate row by arranging magnetic plate groups having the same thickness in the thickness direction in a row in the thickness direction, and forming a magnetic plate row; The magnetic plate row is sequentially pushed into the inside of the guide tube in a state where the convex surface of the inner end of the magnetic plate is pressed against the inner peripheral surface of the cylindrical guide tube, thereby forming the inner end of each magnetic plate. And a main winding step of sliding the portions along the inner peripheral surface of the guide cylinder and arranging them in a spiral shape.
[0009]
A second aspect of the present invention relates to the method of manufacturing a cylindrical stator according to the first aspect.,PreviousUrging the pin in the direction of the thickness of the magnetic plate row in a state where the concave surface of the inner end of the magnetic plate forming the column direction base end of the magnetic plate row is pressed against the outer peripheral surface of the pin; A temporary winding step of arranging the outer ends of the magnetic plates on the base end side in the column direction of the magnetic plate row in a substantially radial direction with the pin as a center, and completing the temporary winding step with the completion of the row forming step It is characterized in that it is terminated before the main winding step is completed.
[0010]
Claim3The manufacturing method of the cylindrical stator ofFurtherA magnetic plate formed by arranging equal-thickness magnetic plate groups having notch recesses in which a central portion in the longitudinal direction adjacent to the curved inner end portion is cut from the long side by a predetermined depth in the width direction and arranged in a line in the thickness direction. A table having a mounting surface on which the plate row is slidably mounted, a guide provided upright on the mounting surface and having a guide surface for aligning each outer end of the magnetic plate in a line, An insertion which is arranged above the mounting surface in a posture extending vertically from the mounting surface and a part of the cylindrical surface is formed by notching in a axial direction from a predetermined position of an opening end on the mounting surface side. A guide cylinder having a mouth,
A guide tube elevating mechanism for moving the guide tube up and down along the axis, and urging the inner end of each magnetic plate toward the guide tube to move the inner end of each magnetic plate to the magnetic plate By sequentially pushing the inner ends of the respective magnetic plates along the inner peripheral surface of the guide cylinder by sequentially pushing the inside of the guide cylinder through the insertion opening from the leading end of the row, the magnetic material is arranged in a spiral shape. It is characterized in that the magnetic plates are arranged in a cylindrical shape and a spiral shape using a plate row pushing mechanism.
[0011]
Claim4Is the claim3The method for manufacturing a cylindrical stator according to any one of the preceding claims, wherein the magnetic plate row pushing mechanism comprises: a pin disposed so as to be able to move up and down with respect to the mounting surface and to be movable along the mounting surface; In the state where the pin is pressed against the concave surface of the inner end portion of the magnetic plate forming an end, the pin is urged toward the substantially thickness direction of the magnetic plate row in the row direction base end side of the magnetic plate row. A pin pushing mechanism for arranging the outer end of each of the magnetic plates in a substantially radial direction with the pin as a center, and the outer end of each of the magnetic plates on the base end side of the magnetic plate row in the row direction is connected to the pin. A pin lifting mechanism that raises the pins in the axial direction after being arranged in a substantially radial direction as a center, and a concave surface that comes into contact with the outer end of the magnetic plate row arranged in a substantially radial direction. A stopper movably disposed on the mounting surface along the mounting surface, The stoppers are urged in the direction of the guide cylinder, and the inner ends of the magnetic plates are sequentially pushed from the front end side of the row of magnetic plates into the inside of the guide cylinder through the insertion openings in order, thereby making the respective magnetic plates The magnetic plate is cylindrically and spirally arranged by using a stopper pushing mechanism for sliding the inner end along the inner peripheral surface of the guide cylinder to arrange the spirally.
[0012]
Claim5 describedManufacturing method of cylindrical statorIs moreAfter the diameter reducing step, a spiral body formed by arranging at least the same thickness of magnetic plate group having a curved inner end in a spiral shape is introduced into a cylinder having a conical inner peripheral surface, and then the axis of the spiral body is adjusted. The method includes a step of reducing the diameter of the spiral body by pushing the spiral body in a direction of a small diameter in the axial direction while making the spiral body coincide with the axis of the inner peripheral surface of the cone.
[0013]
Claim6Is the claim5In the method of manufacturing a cylindrical stator, the diameter reducing step includes disposing a receiving ring coaxially with the cylinder in proximity to the small diameter opening of the cylinder, and reducing the diameter of the spiral body and extruding the spiral body from the small diameter opening. It is characterized by including a step of fitting into the receiving wheel.
Claim7Is the claim5The method of manufacturing a cylindrical stator according to the above, wherein the diameter reducing step includes: a cylinder having a conical inner peripheral surface; a rod for urging an end surface of a spiral body in the cylinder to push the spiral body in a small diameter direction; And a linear actuator that moves back and forth along the axis of the cylinder.
[0014]
Claim8Is the claim7In the method for manufacturing a cylindrical stator according to the above, the diameter reducing step includes a receiving rod inserted into the cylinder, and the end faces of the rods hold the both end faces of the spiral body while the spiral is formed by the push rod. Pushing a body into the cylinder.
Claim9Is the claim8In the method for manufacturing a cylindrical stator according to the above, the diameter reducing step includes an axial direction relative to an outer peripheral surface of the spiral body near an inlet-side end face of the cylinder while aligning an axial center of the spiral body with an axial center of the cylinder. Providing guide means having a guide surface that is displaceably and non-radially displaceable, and pushing the spiral body into the cylinder causes the guide surface of the guide means to abut on the outer peripheral surface of the spiral body. It is characterized by being done.
[0015]
Claim 10 describedManufacturing method of cylindrical statorIs moreA plate forming step of forming a magnetic plate row by arranging magnetic plate groups of equal thickness whose inner ends are curved in a line in the thickness direction; and forming the magnetic plate row in a spiral shape. Arranging a guide member having a plurality of guide surfaces capable of substantially abutting on a plurality of surfaces of the magnetic plate row having an ideal shape, and forming a large number of the magnetic plates with a substantially thickness. Stacked in the direction to form an unshaped magnetic plate row, a plurality of surfaces of the unshaped magnetic plate row are brought into contact with the guide surfaces to align each magnetic plate, and the unshaped magnetic plate is arranged. The method is characterized by including a step of shaping the end face shape of the row.
[0016]
Claim 11Claim 10In the method for manufacturing a cylindrical stator according to the above, the row forming step prepares a frame body forming the guide member having a shaping hole substantially matching an ideal shape of the magnetic plate row, and a large number of the magnetic plates are substantially Laminating in the thickness direction to form the unshaped magnetic plate row, pushing the unshaped magnetic plate row into the shaping holes to align the respective magnetic plates, and forming the end face shape of the unshaped magnetic plate row Is characterized by including a step of shaping
[0017]
Claim 12Claim 10In the method for manufacturing a cylindrical stator according to the above, the row forming step prepares a plate-like guide member having a thickness substantially equal to the opening width of the groove of the magnetic plate row, and cuts in which the same portions are cut into the same shape. By laminating a large number of the magnetic plates having concave portions in a substantially thickness direction to form an unshaped magnetic plate row having the grooves, and fitting the guide member into the grooves of the unshaped magnetic plate rows. A step of aligning the magnetic plates and shaping the end face shape of the unshaped magnetic plate row.
[0018]
Claim 13Claim 10In the method for manufacturing a cylindrical stator according to the above, the row forming step prepares a predetermined number of the magnetic plates having cut notches in which the same portions are cut into the same shape, and has a thickness substantially equal to the opening width of the cut notches. A step of preparing a plate-shaped guide member having the magnetic plate and sequentially stacking the magnetic plates while fitting the cut-out recesses of the magnetic plate into the guide member to form the magnetic plate row.
[0019]
Claim 14 describedManufacturing method of cylindrical statorIs moreIn the thickness direction, the plate piece disposing step includes the step of forming a group of magnetic plates having an equal thickness in which a central portion in the longitudinal direction adjacent to the curved inner end portion has a cutout recess cut from the long side by a predetermined depth in the width direction. A row forming step of forming a magnetic plate row by arranging in a row, and a step of spirally arranging the magnetic plate row,
The step of spirally arranging the magnetic plate rows presses the magnetic plate rows against the guide surface by urging the magnetic plate rows in the stacking direction toward a partially cylindrical guide surface, And a step of rotating along to develop a spiral shape.
[0020]
Claim 15Claim 14In the method for manufacturing a cylindrical stator according to (1), the step of spirally arranging the magnetic plate rows includes a step of standing along an axis of a partial cylindrical wall having a partial cylindrical guide surface and an axis of the partial cylindrical guide surface. A guide portion with a pin having a guide pin provided therein, and a partial cylindrical wall having a guide surface having a partial cylindrical shape, the distance between the guide portion with the pin and the guide portion with the pin being expandable and contractible. And a pin-less guide portion which is relatively displaced by pressing the inner end portion of the magnetic plate at one end side in the row direction of the magnetic plate row against the guide surface of the pin-less guide portion. The inner end of the magnetic plate at the other end in the direction is pressed against the outer peripheral surface of the guide pin, and the two guide portions are brought closer to each other to bring the inner end of the magnetic plate into one end in the row direction of the magnetic plate row. Slid along the guide surface of the pinless guide in order from Jo in are arranged, it is characterized by comprising the step of arranging the inner end portion of the magnetic plate in the column direction other end side of the magnetic plate column spirally inside the guide surface about said pin.
[0021]
Claim16Claim 14In the method of manufacturing a cylindrical stator, the step of spirally arranging the magnetic plate rows includes preparing a pair of semi-cylindrical guide portions having a partially cylindrical guide surface and facing each other, The magnetic plate at one end in the row direction of the plate row is pressed against the guide surface of one of the guide portions, and the magnetic plate at the other end in the row direction of the magnetic plate row is pressed against the other guide portion, and the two guides are pressed. A step of bringing the magnetic plates closer to each other and sliding each of the magnetic plates along the two guide surfaces to form a spiral arrangement.
[0022]
Claim17Claim 14In the method for manufacturing a cylindrical stator, the step of spirally arranging the magnetic plate rows prepares a rotatable guide portion having a cylindrical guide surface, and the column-direction tips of the magnetic plate rows are aligned. The outer end of the magnetic plate to be formed is pressed against the guide surface of the guide portion, and the magnetic plate row is pushed into the guide portion while rotating the guide portion, whereby each magnetic member of the magnetic plate row along the guide surface is pressed. The method is characterized in that the method includes a step of arranging the plates in a spiral shape in order from the front end side.
[0023]
Claim18Manufacturing method of cylindrical statorIs moreA row forming step of arranging the magnetic plate rows by arranging magnetic plate groups of equal thickness having curved inner ends in a row in the thickness direction, and forming the magnetic plate rows in a spiral shape. Arranging the magnetic plate row in a spiral shape, wherein the inlet has a shape substantially matching the shape of the end face perpendicular to the axial direction after the formation of the spiral body of the magnetic plate row, and the outlet has Prepare a guide cylinder having a guide surface that is formed in a circular shape and has a continuously changing opening shape from the inlet to the outlet, and inserts the magnetic plate row from the inlet to the outlet so that each of the magnets of the magnetic plate row It is characterized in that the method includes a step of gradually arranging the plates in a spiral shape.
[0024]
Claim19Manufacturing method of cylindrical statorIs moreThe plate piece disposing step prepares a guide cylinder in which a number of positioning grooves capable of inserting the outer end of the magnetic plate in the width direction are formed substantially radially on an inner peripheral surface, and the magnetic plates are individually formed. The method further comprises a step of moving the guide plate in the axial direction, inserting the outer ends of the magnetic plates into the positioning grooves one by one, and arranging the respective magnetic plates in a spiral shape.
[0025]
[Action and effect of the invention]
In the method of manufacturing a cylindrical stator according to each of the above inventions, the respective magnetic plates are first arranged in a spiral shape, and then the outer ends of the respective magnetic plates are pressed by the pressing portion in the diameter reducing direction.PreferablyAt least the inner end of each magnetic plate is rotated relative to the pressing portion in a spiral direction.Etc. to reduce the diameter. In this case, the outer end of each magnetic plate, that is, a portion in contact with the pressing portion may be stationary relative to the pressing portion, or may rotate relative to the pressing portion. In this way, the spiral-shaped cylindrical stator can be manufactured simply and with good finish, and the productivity is excellent. That is, when the spirally arranged magnetic plates are pressed in the diameter reducing direction, a compressive force in the longitudinal direction of each magnetic plate is generated from the pressing force. If the inner end of each magnetic plate cannot be displaced, there is a possibility that the magnetic plate may be distorted in an undesired direction by this compressive component. According to the present invention, since at least the inner end of each magnetic plate is rotatable relative to the pressing portion in the spiral direction, the inner end of each magnetic plate escapes in the spiral direction against such a compressive component. This prevents the magnetic plate from being distorted in an undesired direction. Note that the inner end of each magnetic plate described above escapes in the spiral direction, so that the inner end of each magnetic plate can be reduced in diameter. The inner edges of the boards can be easily arranged circumferentially.
[0026]
In a preferred embodiment,Each of the magnetic plates is previously curved continuously in one direction in the longitudinal direction, and is curved so that the curvature gradually decreases on the inner end side. With this configuration, the inner end of each magnetic plate can be easily wound inward in the spiral direction.
In a preferred embodiment,Each magnetic plate is placed on a rotatable rotary table. With this configuration, as compared with the case of the fixed table, the rotating table is rotated by the component force when each magnetic plate is pressed in the diameter reducing direction by the pressing portion, so that each magnetic plate moves inward in the spiral direction. Entanglement can be facilitated, and the above-mentioned undesired distortion of each magnetic plate can be prevented.
[0027]
By rotating the rotary table in a preferred embodiment, the inward winding of each magnetic plate in the spiral direction can be promoted, and the outer ends of each magnetic plate can be sequentially pressed, which is more convenient. That is, it is necessary to uniformly press all the outer ends of each magnetic plate in the diameter reducing direction. However, it is not easy to design a pressing portion that simultaneously presses all the outer ends of each magnetic plate in the diameter reducing direction. If the outer end of each magnetic plate is relatively rotated with respect to an appropriate number of pressing portions, it is not necessary to simultaneously press all the outer ends of each magnetic plate in the diameter reducing direction, and the pressing portion sequentially presses each magnetic plate. Since the pressing may be performed, the design of the pressing portion is facilitated.
[0028]
Claim1According to the method for manufacturing a cylindrical stator according to the present invention, a magnetic plate row is prepared by arranging magnetic plate groups having the same thickness at the inner end in a line in the thickness direction. While pressing the convex surface of the inner end of the claim magnetic plate forming the front end against the inner surface of the cylindrical guide cylinder, the magnetic plate row is sequentially pushed into the inside of the guide cylinder, so that the inner end of each magnetic plate is brought into the guide cylinder. Are slid along the inner surface of the spiral and arranged in a spiral.
[0029]
This makes it possible to automatically spirally arrange the magnetic plate rows simply by pushing in a row in advance, and the spiral arrangement can be realized extremely easily and efficiently. Become.
Claim2According to the method for manufacturing a cylindrical stator according to1In carrying out the manufacturing described in the above, while pressing the concave surface of the inner end of the magnetic plate forming the column direction base end of the magnetic plate row against the outer peripheral surface of the pin, the pin is urged toward the thickness direction of the magnetic plate row. I do. With this configuration, the outer ends of the magnetic plates on the base end side in the row direction of the magnetic plate row can be arranged in a substantially radial direction with the pin as a center.1In the method described in (1), the final part of the spiral arrangement step can be easily performed, and the productivity can be further improved.
[0030]
Claim3According to the method for manufacturing a cylindrical stator according to the above, a magnetic plate row in which a notch concave portion cut in a width direction by a predetermined depth is formed at a central portion of a long side of each magnetic plate is substantially formed on a mounting surface of a table. It is slidably mounted in the thickness direction. The outer ends of the magnetic plates forming the magnetic plate row are aligned in a row along the guide surface on the mounting surface. The guide cylinder provided with the guide surface has an insertion opening formed by cutting a part of the cylindrical surface from a predetermined position of the opening end on the placement surface side in the axial direction. The mechanism that pushes in the magnetic plate row urges the curved inner end of the magnetic plate in the direction of the guide cylinder, and only the inner end of each magnetic plate row from the tip of the magnetic plate row through this insertion port in order. It is sequentially pushed into the inside of the guide cylinder. Thus, the inner end of each magnetic plate is slid along the inner peripheral surface of the guide cylinder, and each magnetic plate is arranged in a spiral. Therefore, by adopting such a configuration, it is possible to provide an apparatus having excellent productivity which can easily realize the method for manufacturing a cylindrical stator according to the fifth aspect.
[0031]
Claim4According to the method for manufacturing a cylindrical stator according to the claim,3The described configuration can be further improved. That is, the mechanism for pushing the magnetic plate row is a pin that can be raised and lowered with respect to the mounting surface, a pin lifting mechanism that raises and lowers the pin, A pin pushing mechanism for pressing the magnetic plate, a stopper for urging the radial outer end of the magnetic plate on the base side in the row direction along the mounting surface, and a stopper for urging the stopper in the direction of the guide cylinder. By providing a stopper pushing mechanism that sequentially pushes the inner end of the magnetic plate from the front end of the magnetic plate row into the inside of the guide cylinder through the insertion port, when the pin is pushed by the pin pushing mechanism, the magnetic plate row The effect of arranging the outer ends of the plurality of proximal magnetic plates in a substantially radial direction with the pin as the center is enhanced.
[0032]
Also, when the stopper is urged by the stopper pushing mechanism, only the inner end of each magnetic plate is sequentially pushed into the inside of the guide tube through the insertion opening of the guide tube in order from the front end side in the column direction of the magnetic plate row. The inner end of each magnetic plate slides along the inner peripheral surface of the guide cylinder to further enhance the function of being arranged in a spiral.
Therefore, the claims4In particular, the configuration described in2And claims3Can easily be realized, and can be provided as a method for manufacturing a cylindrical stator having excellent productivity.
[0033]
Claim5According to the method of manufacturing a cylindrical stator according to, MagneticBy pressing a spiral body in which spiral plates are spirally arranged into a cylinder having a conical inner peripheral surface in the axial direction with a small diameter, an effect of reducing the diameter of the spiral body occurs. Therefore, it is easy to press the entire outer peripheral surface of the spiral body in the centripetal direction.
[0034]
Claim6According to the method for manufacturing a cylindrical stator according to5Further, in the manufacturing method described above, a receiving ring is arranged coaxially with the cylinder in close proximity to the small-diameter opening of the cylinder, and an action can be added in which a spiral body that is reduced in diameter and extruded from the small-diameter opening is directly fitted into the receiving ring. The spiral body can be easily fitted into the receiving wheel without complicating the configuration and operation of the diameter device, thereby realizing a method of manufacturing a cylindrical stator having an effect with excellent productivity.
[0035]
Claim7According to the method for manufacturing a cylindrical stator according to5The described manufacturing method can be easily realized. Specifically, by energizing the end surface of the spiral body in the cylinder having the inner peripheral surface of the cone, the rod for pushing the spiral body in the small diameter direction is advanced and retracted by the linear actuator along the axis of the cylinder. Thus, a method for manufacturing a cylindrical stator that can be easily reduced in diameter and has excellent productivity is realized.
[0036]
Claim8According to the method for manufacturing a cylindrical stator according to the above,7In the method of manufacturing a cylindrical stator described above, when the spiral body is inserted into a tapered cylinder, the spiral body is clamped at both end faces of the push rod and the receiving rod while the both end faces are held.
In this way, the diameter can be reduced without changing the shape and posture of the spiral body.
[0037]
Claim9According to the method for manufacturing a cylindrical stator according to8In the method for manufacturing a cylindrical stator described above, when the spiral body is inserted into the cylinder, the outer peripheral surface of the spiral body immediately before the insertion is guided by the guide surface of the guide means. By doing so, it is possible to suppress a change in the shape and posture of the spiral body due to the reaction force generated in the spiral body at the start of insertion into the cylinder.
[0038]
Claim 10According to the method of manufacturing a cylindrical stator according to, MagneticThe plurality of surfaces of the magnetic plate row are brought into contact with a plurality of guide surfaces having a positional relationship equal to the positional relationship of the ideally shaped magnetic plate row to align the respective magnetic plates, so that the end faces of the magnetic plate row are accurately aligned. And it can be easily aligned.
Claim 11According to the method for manufacturing a cylindrical stator according to claim 1,0Further, in the method for manufacturing a cylindrical stator described above, the magnetic plate row roughly preliminarily laminated is pressed into a shaping hole having a plurality of surfaces substantially matching the ideal shape of the magnetic plate row to be shaped. Thereby, the end faces of the magnetic plate row can be aligned accurately and easily.
[0039]
Claim 12According to the method for manufacturing a cylindrical stator according to claim 1,0In the method of manufacturing a cylindrical stator described above, an equal-shaped notch (for example, a coil accommodating groove) is formed in each magnetic plate at an equal position, and the opening width of the groove (magnetic plate) formed by the notch in the magnetic plate row is formed. (A direction perpendicular to the thickness direction of the plate), a plate-shaped guide member having a thickness substantially equal to that of the guide member is prepared, and a groove portion of an unshaped magnetic plate row is fitted into the guide member to be shaped. Thereby, the end faces of the magnetic plate row can be aligned accurately and easily. Of course, in this state, the magnetic plate row can be urged in the thickness reducing direction.
[0040]
Claim 13According to the method for manufacturing a cylindrical stator according to claim 1,0In the method of manufacturing a cylindrical stator described above, an equal-shaped notch (for example, a coil accommodating groove) is formed in each magnetic plate at the same position, and the opening width of this notch (the perpendicular to the thickness direction of the magnetic plate) is formed. Direction), the magnetic plates are stacked while the cut-out recesses of each magnetic plate are sequentially fitted to a plate-like guide member having a thickness substantially equal to the thickness of the magnetic plate. Thereby, the end faces of the magnetic plate row can be aligned accurately and easily. Of course, in this state, the magnetic plate row can be urged in the thickness reducing direction.
[0041]
Claim 14According to the method for manufacturing a cylindrical stator according to the above, the magnetic plate row is urged in the laminating direction toward the partial cylindrical guide surface to press the magnetic plate row against the guide surface, and is rotated along the guide surface. As a result, the spiral body can be formed by a simple process.
Claim 15According to the method of manufacturing a cylindrical stator according to the present invention, a pinned guide portion having a partially cylindrical guide surface and a guide pin, and a pinless guide portion having a partially cylindrical guide surface, both ends of the magnetic plate row By compressing, the inner end of the magnetic plate (the portion which becomes the inner diameter side when the spiral body is formed from the cut concave portion) is slid along the guide surface of the pinless guide cylinder in order from the front end side of the magnetic plate row. The magnetic plates are arranged in a spiral shape, and the inner ends of the magnetic plate rows are arranged in a substantially radial direction with the pin as a center. Finally, each magnetic plate is arranged in a ring shape (in a spiral shape).
With this configuration, a complicated spiral body forming operation can be realized by a simple process.
[0042]
Claim16According to the method for manufacturing a cylindrical stator according to claim 1,5The pin is omitted in the spiral body forming step of (1). The outer ends of the magnetic plate rows compressed in the laminating direction (the outer portion after the spiral body is formed) slide along the guide surfaces of the two guide portions.5A spiral body is formed in the same manner as described above.
With this configuration, a complicated spiral body forming operation can be realized by a simple process.
[0043]
Claim17According to the method for manufacturing a cylindrical stator according to claim 1,4In the method of manufacturing a cylindrical stator according to the above, further, a guide portion having a cylindrical guide surface and being rotatable is prepared, and the guide portion is rotated by itself while pressing the outer end of the magnetic plate row against the guide surface. The respective magnetic plates are spirally arranged along the line.
With this configuration, a complicated spiral body forming operation can be realized by a simple process.
[0044]
Claim18According to the method of manufacturing a cylindrical stator according to, MagneticThe magnetic plates are stacked in advance to form a magnetic plate row (row forming step), and the magnetic plate rows are spirally arranged to form a spiral body (spiral body forming step), and the spiral body is reduced in diameter (diameter reduction). Process).
In particular, in the spiral body forming step, the inlet opening has a shape that matches the shape of the end face perpendicular to the width direction of the stacked magnetic plate rows, the outlet opening is circular, and the opening shape is continuously formed from the inlet to the outlet. Prepare a guide tube with a changing guide surface. Then, the magnetic plate row is pushed in the width direction to gradually arrange the magnetic plates of the magnetic plate row in a spiral shape.
[0045]
With this configuration, a complicated spiral body forming operation can be realized by a simple process.
Claim19According to the method of manufacturing a cylindrical stator according to, MagneticPrepare a guide cylinder with a number of positioning grooves that can be inserted into the outer end of the conductive plate in the width direction in a substantially radial shape on the inner peripheral surface, and move each magnetic plate individually in the axial direction of the guide cylinder. The magnetic plates are spirally arranged by inserting the outer ends of the plates one by one into the positioning grooves.
With this configuration, a complicated spiral body forming operation can be realized by a simple process.
[0046]
With this configuration, a complicated spiral body forming operation can be realized by a simple process.
[0047]
【Example】
(Example 1)
Hereinafter, the first embodiment of the present invention will be described in detail.
FIG. 1 is a cross-sectional view illustrating a main part of a solenoid valve employing a spirally wound cylindrical stator manufactured according to the present invention. The magnetic circuit of the solenoid valve includes a cylindrical stator (yoke) 100 having a highly permeable plate and a highly permeable movable disk 10 opposed to a lower end surface of the solenoid valve via a gap g.
[0048]
A cylindrical spring housing chamber S1 and a ring-shaped coil chamber S2 are formed at the radially central portion of the cylindrical stator 100 with its lower end face recessed. The upper part of the plunger 11 made of a non-magnetic rod is fed into the spring storage chamber S1. The plunger 11 is press-fitted into a central hole of the movable disk 10, and a lower portion of the plunger 11 is slidably held in a shaft hole of the housing 12. A valve (not shown) is fixed to a lower end (not shown) of the plunger 11, and a valve hole (not shown) is opened and closed by the vertical movement of the valve. Reference numeral 13 denotes a coil spring, which urges the movable disk 10 and the plunger 12 downward. Reference numeral 14 denotes a communication hole for allowing liquid to flow in and out of the spring housing chamber S1 and the outside in response to a change in the volume of the spring housing chamber S1 caused by sliding of the plunger 13. The exciting coil 15 is accommodated in the coil chamber S2.
[0049]
When the excitation coil 15 is energized, the lower end surface of the cylindrical stator 100 attracts the movable disk 10, whereby the plunger 11 compresses the coil spring 13 and is displaced upward. The magnetic flux passes through the exciting coil 15SurroundIt is formed and the important point is that the magnetic flux is formed radially and axially. When a pulse is applied to such a solenoid valve at a predetermined duty ratio, for example, the eddy current increases. Therefore, in order to reduce the eddy current without hindering the passage of the magnetic flux, it is necessary to stack the electromagnetic steel sheets in the circumferential direction of the cylindrical stator 100.
[0050]
It is important to form a magnetic circuit with low eddy current loss by laminating magnetic steel sheets in the circumferential direction as described above, even in other types of solenoid valves, electromagnets, stators or rotors and transformers of special rotating electric machines, and the like. The manufacturing method and the manufacturing apparatus of the present embodiment described below can be applied to them.
Next, the cylindrical stator 100 will be described with reference to FIG.
[0051]
The cylindrical stator 100 has a cylindrical shape, and has the cylindrical spring housing chamber S1 and the ring-shaped coil chamber S2 as described above. The cylindrical stator 100 is formed by spirally stacking a number of electromagnetic steel sheets 200 (see FIG. 3). Each electromagnetic steel sheet (hereinafter, also referred to as a magnetic plate) 200 has a spring housing chamber S1 and a ring-shaped coil chamber S2. Is formed in advance to form a notch.
[0052]
Hereinafter, a basic portion of a method of manufacturing the spirally wound cylindrical stator 100 will be described with reference to FIGS.
First, each magnetic plate 200 having the cut recesses formed therein is bent into a “substantially parabolic shape” shown in FIGS. 3 and 4 by press working. Here, the “substantially parabolic shape” is a shape that is continuously curved in one direction and has a curvature gradually reduced on the outer end face, and includes a spiral shape.
[0053]
However, the curvature may be provided mainly at the inner end of each magnetic plate 200, and the outer end may be left flat. Such bending is performed in order to arrange the inner end of each magnetic plate 200 on a circle as small as possible before performing a diameter reducing step described later. Next, each magnetic plate 200 is spirally arranged as shown in FIG. 2 (plate piece arrangement step). At this time, the inner ends of the magnetic plates 200 are arranged in a spiral shape so as to be positioned at the same position in the radial direction, that is, on the same circumference.
[0054]
Next, the outer end of each magnetic plate 200 is pressed in the diameter reducing direction by a pressing portion described later, and each magnetic plate 200 is rotated clockwise (spiral direction) in FIG. Process). Thus, each magnetic plate 200 is spirally wound (see FIG. 2). The term “diameter-reducing direction” used herein refers to a centripetal direction, which includes, for example, a case where the pressing direction deviates from the centripetal direction by about +/− 15 degrees.
[0055]
Next, by welding the outer peripheral portion of the cylindrical stator 100 with a laser or the like, the separation of each magnetic plate 200 is prevented, and the fabrication is completed.
A particularly important part of the above process is that each magnetic plate 200 is relatively rotated in a spiral direction with respect to a pressing portion described below that presses the outer end of each magnetic plate 200 in the diameter reducing direction. This meaning will be described in more detail with reference to FIG.
[0056]
When one magnetic plate 200a is taken as an example, the centripetal pressing force f applied to the outer end P of the magnetic plate 200a is equal to the longitudinal component of the outer end of the magnetic plate 200a (that is, the magnetic plate 200a is In the direction of compression) fa and a bending component perpendicular thereto (that is, a force for spirally bending the magnetic plate 200a) fb. fb is a force required to reduce the diameter of the magnetic plate 200a in a spiral shape, but fa causes the magnetic plate 200a to be distorted into an undesired shape. For example, if the inner end of the magnetic plate 200a is fixed, the inner end of the magnetic plate 200a is not regulated by the adjacent magnetic plate 200 and distorted into the above-mentioned undesired shape. However, since the center portion m and the outer end portion m 'of the magnetic plate 200a are separated from the adjacent magnetic plate 200, the compression may cause distortion to either side perpendicular to the longitudinal direction.
[0057]
According to the present embodiment, since each magnetic plate 200 is relatively rotated in the spiral direction, it is possible to prevent the plate piece from being distorted in an undesired direction due to such an excessive compressive component.
Next, the point of reducing the diameter of the circle drawn by the inner end of each magnetic plate 200 will be described.
Before pressing each magnetic plate 200 in the diameter reducing direction, the diameter d of the circle drawn by the inner end of each of the spirally arranged magnetic plates 200 is usually larger than the diameter d 'after completion of fabrication. This is because it is difficult to make the gap between the inner ends of the adjacent magnetic plates 200 zero. In the initial stage of starting pressing in the radially reduced direction in such a state, the component force in the compression direction pushes each magnetic plate 200 in its longitudinal direction, and as a result, the inner end of each magnetic plate 200 rotates in a spiral shape. The diameter of the circle drawn by the inner end of each magnetic plate 200 is reduced from d to d ′. However, what is necessary to realize the action of pushing the inner end of each magnetic plate 200 inward in the spiral direction is that slippage occurs between the pressing portion and the outer end of each magnetic plate 200 and The purpose is to keep the outer end of 200 from escaping in the opposite direction.
[0058]
A simple way to achieve this is to forcibly rotate the turntable. In this case, since the outer end of each magnetic plate 200 rotates relative to the pressing portion, the pressing portion may press the outer end of each plate piece sequentially to the diameter reducing step, and the design of the pressing portion is easy. It becomes. That is, all the magnetic plates 200 can be sequentially pressed in the diameter reducing direction by a small number of pressing portions. However, in this case, when the frictional resistance between each magnetic plate 200 and the rotary table is smaller than the frictional resistance between the pressing portion and each magnetic plate 200, only the rotary table rotates with respect to each magnetic plate 200. Therefore, it is desirable to provide a means such as pressing each magnetic plate 200 against a rotary table.
[0059]
Hereinafter, an example of a manufacturing apparatus for realizing the manufacturing method of the above embodiment will be described with reference to FIGS.
The apparatus has a casing 2 in which a lower case 21 and an upper case 22 are connected by bolts 23, and a bevel gear 3 is rotatably accommodated inside the casing 2. The lower case 21 has a bottomed cylindrical shape, and the upper case 22 has a disk shape that covers the opening of the lower case 21. The drive shaft of the bevel gear 3 projects outward from the casing 2 in the horizontal direction, and is connected to a rotating handle or a motor (not shown).
[0060]
On the other hand, immediately above the bevel gear 3, a disk-shaped scroll gear plate 4 is rotatably fitted to the boss portion 24 of the upper case 21, and the lower surface of the scroll gear plate 4 is provided on the tooth surface of the bevel gear 3. A condensed tooth surface is formed, and spiral teeth 41 are formed on the upper surface of the scroll gear plate 4.
As shown in FIGS. 5 and 6, twelve linear guide grooves 25 are formed in the upper case 22 in the radial direction every 30 degrees. 22 has been reached.
[0061]
Twelve sliders 5 are mounted on the upper surface of the upper case 22. The slider 5 includes an upper plate portion 51 having a wide width in the circumferential direction of the upper case 22 and a lower plate portion 52 swelling downward from the lower surface of the upper plate portion 51. It is slidably fitted. A spiral tooth 53 condensing with the spiral tooth 41 of the scroll gear plate 4 protrudes from the lower plate portion 52, and the slider 5 moves in the radial direction while being guided by the linear guide groove 25 by the rotation of the scroll gear plate 4. .
[0062]
An L-shaped angle 6 as viewed from the side is mounted and fixed on the slider 5, and two pressing bars (pressing portions in the present invention) whose height is adjusted by spacers 7 on the angle 6. 8 is fixed horizontally. Incidentally, the height of each pressing bar 8 is set by adjusting the thickness of the spacer 7 so that the inner ends of the pressing bars 8 adjacent in the circumferential direction can overlap when viewed from the vertical direction at the end of the diameter reduction step. Have been.
[0063]
Further, the boss portion 24 of the upper case 22 has an upward concave portion 26, and the lower portion of the turntable 9 is supported in the concave portion 26 so as to be relatively rotatable. A cylindrical stator 100 is mounted on the turntable 9, and a cylindrical portion 91 is provided upright at the center of the upper surface of the turntable 9.
Hereinafter, the operation of this device will be described.
[0064]
First, the magnetic plates 200 are spirally arranged around the central cylindrical portion 91. At this time, the diameter d of the circle drawn by the inner end of each magnetic plate 200 is made as small as possible. Next, the rotary table 9 and each magnetic plate 200 are rotated at a predetermined rotation speed by a motor (not shown). Next, when the bevel gear 3 is rotated by a handle (not shown), the scroll gear 4 rotates, and the slider 5 and the pressing bar 8 advance in the centripetal direction. Thus, a total of 24 pressing bars press the outer end of each magnetic plate 200 in the diameter reducing direction, and each magnetic plate 200 is reduced in diameter. At this time, the frictional force between the rotary table 9 and each magnetic plate 200 is larger than the frictional force between each magnetic plate 200 and the pressing bar 8.
[0065]
In this manner, even if each magnetic plate 200 is pressed in the diameter reducing direction to reduce its diameter, each magnetic plate 200 is improper due to the compressive force in the longitudinal direction of the magnetic plate 200 of the pressing force in the diameter reducing direction. The diameter can be reduced smoothly without being distorted in a desired direction. Further, the pressing bar 8 can sequentially press at least all the magnetic plates 200.
In addition, the frictional force between each magnetic plate 200 and the rotary table 9 may be smaller than the frictional force between each magnetic plate 200 and the pressing bar 8. In this case, the outer end of each magnetic plate 200 is fixed to the pressing bar 8, and the inner end of each magnetic plate 200 is rotated by the rotation of the turntable 9 and turns in a spiral direction while being curved in a spiral shape. The central column portion 91 has a function as a stopper for preventing each magnetic plate 200 from being further reduced in diameter.
[0066]
(Modification 1)
In the above embodiment, the rotary table 9 is rotated in synchronization with the rotation of the pressing bar 8, but the rotary table 9 may be activated after the pressing bar 8 presses each magnetic plate 200 for a predetermined time. In this case, since the rotary table 9 is not rotating at first, each magnetic plate 200 is pushed inward in the spiral direction by the pressing force-component force of the pressing bar 8 in the centripetal direction. The inner end of the plate 200 has a minimum radius. Thereafter, the rotary table 9 is rotated at an appropriate rotation speed, and the magnetic plates 200 are pressed evenly.
[0067]
(Modification 2)
As shown in FIG. 7, the center column portion 91 may be changed to a truncated cone 92, and the truncated cone 92 may be lowered into the rotary table 9 with the pressing operation of the pressing bar 8. In this way, the outer peripheral surface of the truncated cone 92 can always contact the inner end of each magnetic plate 200 regardless of the diameter of the inner end of each magnetic plate 200, and the inner end of each magnetic plate 200 It can be guided to always be at the same diameter position.
[0068]
As described above, the cylindrical stator 100 according to the present invention includes a plate piece arranging step of spirally arranging the magnetically permeable magnetic plates 200 and an outer end P of each spirally arranged magnetic plate 200. And a step of reducing the diameter of a spiral body in which the diameter is reduced by biasing the spiral in the centripetal direction.
(Example 2)
Next, another embodiment of the plate piece arranging step of this embodiment will be described in detail.
[0069]
First, an example of the manufacturing apparatus used in the present embodiment will be described with reference to FIG.
The base 7000, which forms a table according to the present invention, has a horizontal mounting surface 70000, and a slider 1000 composed of a rectangular parallelepiped block and a stopper 4000 composed of a substantially rectangular parallelepiped block are slidable on the mounting surface 70000. An actuator (not shown) that is mounted thereon slides the slider 1000 in the Y direction and the stopper 4000 in the X direction. Note that a hydraulic cylinder fixed to the base 7000 is used for these actuators themselves, but the configuration and operation of the hydraulic cylinder are well known, so that further description is omitted.
[0070]
A guide groove 10000 is recessed in the X direction on the slider 1000. The guide groove 10000 guides the provisional winding arm 2000 and the main winding arm.5000 are slidably arranged in the X direction independently of each other by an actuator (not shown) (in this embodiment, a hydraulic cylinder mounted on the slider 1000).
A pin 3000 is held at the distal end of the temporary winding arm 2000 by an actuator (not shown) (in this embodiment, a hydraulic cylinder mounted on the temporary winding arm 2000) so as to be slidable in the Z direction above the mounting surface 70000. Similarly, a pin 60000 is provided at the tip of the main winding arm 5000 by an actuator (not shown) (in this embodiment, a hydraulic cylinder mounted on the main winding arm 5000) in the Z direction above the mounting surface 70000. It is slidably held. Each of the pins 3000 and 60000 has a cylindrical shape with a small diameter, and a ring (a guide cylinder in the present invention) 6000 is fixed to the lower end of the pin 60000 with its axis vertical. The ring 6000 has a cylindrical shape with a top plate having an open lower end surface, and an insertion hole 61000 cut in the axial direction is formed at a predetermined position of the lower end edge so as to face leftward in FIG. I have.
[0071]
A thick stopper plate 12000 having a stopper surface parallel to the guide surface 11000 of the slider 1000 is mounted on the mounting surface 70000 by an actuator not shown (a hydraulic cylinder fixed to the base 7000 in this embodiment). It is slidably held on the surface 70000 in the X and Y directions.
Next, an operation of forming a spiral body from the magnetic plate row 300 (see FIG. 9) will be described based on the process chart of FIG.
[0072]
Note that the magnetic plate row 300 is formed in advance by laminating the magnetic plates 200 shown in FIG. 10 linearly in a substantially thickness direction, and as shown in FIG. 9, a holding block mounted on a robot hand (not shown). 301 and 302. However, in each of the following embodiments, it is assumed that the magnetic plate 200 (see FIG. 10) having no cut-out recess forming the spring storage chamber S1 shown in FIG. 1 is used. FIG. 11 shows a cylindrical stator 100 formed by spirally arranging the magnetic plates 200 and reducing the diameter. 101 is a coil accommodation room. Note that the magnetic plate 200 of FIG. 10 has a cut concave portion 202 formed at a central portion in the longitudinal direction (length direction) and cut from one long side 201 in the width direction. Reference numeral 203 denotes an inner end which is on the inner diameter side when the spiral body is formed from the cut recess 202 of the magnetic plate 200, and 204 is an outer end which is on the outer diameter side when the spiral body is formed than the cut recess 202 of the magnetic plate 200. .
[0073]
Setting process a
The setting step 10 is a step of mounting the magnetic plate row 300 shown in FIG. 9 on the mounting surface 70000.
The magnetic plate row 300 is formed by laminating the magnetic plates 200 shown in FIG. 10 linearly in a substantially thickness direction, and is sandwiched between holding blocks 301 and 302 mounted on a robot hand (not shown) and is placed on the mounting surface 70000. After that, the holding blocks 301 and 302 are opened in the X direction and then detached from the mounting surface 70000. At this time, the slider 1000, the stopper 4000 and the stopper plate 12000 are retracted, and the robot hand can work freely. In FIG. 9, reference numeral 304 denotes a rectangular recess formed by a set of cut recesses 202 of the magnetic plate 200.
[0074]
Then, after the stopper plate 12000 advances rightward in FIG. 1, the slider 1000 advances toward the magnetic plate row 300, and the guide surface 11000 of the slider 1000 contacts the outer end 303 of the magnetic plate row 300, and the magnetic force is maintained. The plate row 300 is pushed in the Y direction. As a result, the inner end 305 of the magnetic plate row 300 abuts on the vertical surface of the stopper plate 12000, and then the slider 1000 stops moving, whereby the magnetic plate row 300 is positioned at a predetermined position on the mounting surface 70000. The inner and outer ends 303, 305 are aligned in a straight line or line, respectively. Thereafter, the stopper plate 12000 retreats to the left. Thereafter, the pin 3000 descends in preparation for the next temporary winding step.
[0075]
The slider 1000 and the stopper plate 12000 constitute a guide.
Temporary winding process b
Next, the pin 3000 advances to the right in the X direction, and the outer peripheral surface of the pin 3000 is moved to the base end of the magnetic plate row 300.Side of the magnetic plate 200The magnetic plate 200 a is pressed against the concave surface of the inner end portion 203, thereby forming the base end (in the laminating direction) of the plurality of magnetic plates 202 in the longitudinal direction center and the outer end 204 of the plurality of magnetic plates 202. Are rotated counterclockwise around the center and are partially arranged in a spiral. The pin 3000 is connected to the base end of the magnetic plate row 300.Side of the magnetic plate 200If the pin 3000 is rotated counterclockwise while being pressed against the concave surface of the inner end 203 of the magnetic plate 200a, the spiral arrangement is promoted.
[0076]
Start of main winding process c
Next, the pin 3000 is raised to move the slider 1000 backward, the ring 6000 is lowered, and then the stopper 4000 is advanced rightward in the figure. Here, the right side surface of the stopper 4000 is a concave surface that matches the partial spiral surface of the base end of the magnetic plate row 300 opened in the temporary winding step b. As a result, the advance of the stopper 4000 causes the stopper 4000 to move forward. The concave surface comes into contact with the partial spiral surface at the base end of the magnetic plate row 300. Even after this contact, the stopper 4000 continues to push the magnetic plate row 300 rightward, and as a result, the inner end 306 of the leading end of the magnetic plate row 300 is pushed into the inside of the ring 6000 from the insertion port 61000 of the ring 6000. Will be. The cylindrical wall 62000 on the slider 1000 side of the insertion opening 61000 of the ring 6000 is loosely fitted into the square concave portion 304 of the magnetic plate row 300, so that the flat outer end portion 307 of the magnetic plate row 300 is not hindered. It will be located outside the ring 6000.
[0077]
During the winding process d
Further, the stopper 4000 pushes the magnetic plate row 300 to the right, so that the inner end 306 of the magnetic plate row 300 is subsequently pushed into the inside of the ring 6000 from the insertion port 61000 of the ring 6000. The inner end of the distal end of the plate row 300 abuts on the inner peripheral surface of the ring 6000 as shown in FIG. Further, the inner end 306 of the magnetic plate row 300 continuously pushed into the ring 6000 by the pushing force of the stopper 4000 is guided by the inner peripheral surface of the ring 6000 and slides along the inner peripheral surface. As a result, the outer end 307 of the magnetic plate row 300 is spirally arranged around the ring 6000 as shown in FIG.
[0078]
During the main winding process e
Further, the stopper 4000 pushes the magnetic plate array 300 to the right, and as a result, the magnetic plate array 300 is arranged in a complete spiral around the ring 6000 as shown in FIG. It is formed. Thereafter, the stopper 4000 retreats, and raises the ring 6000 to separate the ring 6000 from the spiral body 400.
[0079]
The spiral body 400 formed as described above is reduced in diameter by the above-described diameter reducing step, and is completed as a cylindrical stator 100 through fixing by welding or an adhesive.
By the above-described steps and the manufacturing apparatus, the cylindrical stator 100 having the spiral magnetic plate arrangement can be simply and reliably formed.
(Example 3)
Next, another embodiment of the diameter reducing step will be described in detail. First, a diameter reducing device used in a diameter reducing step, which is a main part of the present embodiment, will be described with reference to FIG.
[0080]
A guide base 250 is fixed on the table 150. The guide base 250 is a long block extending in a direction perpendicular to the plane of the paper of FIG. 13, and a guide groove 250 a long in a direction perpendicular to the plane of the paper is formed on an upper end surface of the guide base 250. A bore 250b is formed at the end of the guide groove 250a in a direction perpendicular to the plane of the drawing with the axis M as a center. The diameter of the bore 250b is set to be smaller than the width of the guide groove 250a (the left-right direction on the paper surface of FIG. 13), and the cylindrical outer ring 350 is slid over the guide groove 250a and immediately above the bore 250b from the near side of the paper surface. After the spiral body 4000 described later is fitted, the spiral body 4000 is retracted in the opposite direction.
[0081]
The base 450 is fixed on the table 150 so as to cover the guide groove 250a with the bottomed cylinder lying down. The base 450 is formed with a groove 350a into which the entire top of the guide base 250 is fitted. However, the top surface of the outer ring 350 placed in the guide groove 250a is designed not to protrude upward from the top surface of the base 450. On the top surface of the base 450, a cylinder 550 stands upright about the axis M.
[0082]
The cylinder 550 has a conical inner peripheral surface that becomes smaller in diameter with the axis M as a center, and a rod 650 is disposed inside the conical inner peripheral surface 550a so as to be able to advance and retreat in the axial direction. . Also, two columns 750 are provided upright on both sides of the base 450, and a bar 750a fixed above the cylinder by the columns 750 has a linear actuator 850 composed of, for example, a hydraulic cylinder for raising and lowering the rod 650. Has been fixed.
[0083]
Next, the structure of an attachment for fixing the spiral body 4000 will be described with reference to FIGS.
This attachment includes a stopper bolt 950, an inner ring 960, and a stopper 970, as shown in FIG. The stopper bolt 950 has a disk-shaped head, the inner ring 960 has a cylindrical shape with a bottom, and the stopper 970 has a wheel shape. Then, the shaft of the stopper bolt 950 passes through the inner ring 960 and the holes 960a and 4000a of the spiral body 4000 and is screwed into the screw hole 970a of the stopper 970. The cylindrical portion of the inner ring 960 is fitted into the groove 4010 for accommodating the coil of the spiral body 4000. As a result, when the stopper bolt 950 is tightened, the spiral body 4000 is axially pressed by the inner ring 960 and the stopper 970. Will be.
[0084]
Next, the diameter reducing operation of the spiral body 4000 will be described with reference to FIGS. First, as shown in FIG. 15, the outer ring 350 is set immediately below the cylinder 550, the rod 650 is pulled up from the cylinder 550, and the spiral body 4000 equipped with the attachment shown in FIG.
Next, the rod 650 is lowered, and the disk-shaped head of the stopper bolt 950 is pushed down by the tip of the rod 650. In this way, the spiral body 4000 descends, and the outer peripheral portion of the spiral body 4000 is reduced in diameter as the conical inner peripheral surface 550a becomes smaller in diameter (see FIG. 15). The reduced spiral body 4000 is the lower end of the cylinder 550. It is fitted into the inside of the outer ring 350 from the opening as it is (see FIG. 17).
[0085]
The spiral body 4000 is taken out of the diameter reducing device together with the outer ring 350, and is fixed by, for example, welding an end face. Then, the spiral body 4000 is removed from the outer ring 350 to obtain a completed cylindrical stator.
As described above, the diameter reducing apparatus and the diameter reducing step of the present embodiment are excellent in that they are extremely simple and have high reliability. In the above embodiment, the spiral body 4000 is sandwiched by the attachment and inserted into the cylinder. However, an attachment of another shape may be used, or the spiral body 4000 may be directly pushed in at the tip of the rod 650. An electromagnet may be built in, and the spiral body 4000 may be sucked and inserted easily into the inner peripheral surface 550a of the cone.
(Example 4)
The process of shaping the magnetic plate row 300 will be described with reference to FIGS. This step is a part of the above-described row forming step, and the end faces of the magnetic plate row 300 formed by overlapping so that the end faces of the respective magnetically permeable plates (see FIG. 9) 200 having soft magnetism are substantially aligned. It is a process.
[0086]
First, an example of the manufacturing apparatus used in the present embodiment will be described with reference to FIG. The base 3b forming a table has a horizontal mounting surface 31b, and a frame hole into which an alignment plate (frame) 2b described later is fitted is formed on the mounting surface 31b. It is driven up and down by a pair of hanging shafts 6b. The alignment plate 2b has a shaping hole 21b having a shape slightly larger than the ideal outer surface shape of the magnetic plate row 300.
[0087]
The magnetic plate row 300 is formed by arranging a large number of magnetic plates 200 so as to overlap each other in a substantially thickness direction, and is held by holding blocks 41b and 42b mounted on a robot hand (not shown). The holding portion 4b constituted by the holding blocks 41b and 42b is moved rightward (X direction) in FIG. 18 above the base 3b to a position where the magnetic plate row 300 can be fitted into the shaping hole 21b from above. Stopped. Thereafter, the holding portion 4b is lowered to the lowest position where the lower surface of the holding portion 4b does not hit the upper surface of the alignment plate 2b. Next, a command is issued to the robot hand to open the holding blocks 41b and 42b in the X direction. When the holding blocks 41b and 42b are opened, the magnetic plate row 300 cannot be held by the holding blocks 41b and 42b, and is inserted into the shaping hole 21b immediately below. At this time, as shown in FIG. 19, a slightly chamfered portion 22b is formed over the entire inner surface of the alignment plate 2b, which defines the shaping hole 21b of the alignment plate 2b, over the entire circumference. The rows 300 are smoothly fitted and aligned in the shaping holes 21b. Of course, the upper end surfaces of the magnetic plate rows 300 may be pressed downward by the holding blocks 41b and 42b fixed to the robot hand.
[0088]
Next, the shaft 6b fixed to the lower surface of the alignment plate 2b is lowered by an actuator (not shown) until the mounting surface 31b and the upper surface 22b of the alignment plate 2b are flush with each other (height). 300 can be removed or slid.
In order to separate the magnetic plate row 300 from the holding blocks 41b and 42b, only one of them may be opened. Further, the alignment plate 2b may be pulled out upward, or may be divided into two and opened horizontally. Furthermore, although the magnetic plate row 300 is sandwiched between the sandwiching blocks 41b and 42b to form the sandwiching portion 4b, it is also possible to insert the magnetic plates 200 one by one using a supply means such as a parts feeder.
(Example 5)
Another example of the process of shaping the magnetic plate row 300 will be described with reference to FIG. This step is a part of the above-described row forming step, and the end faces of the magnetic plate row 300 formed by overlapping so that the end faces of the respective magnetically permeable plates (see FIG. 9) 200 having soft magnetism are substantially aligned. It is a process.
[0089]
In the fourth embodiment, the alignment is performed on the basis of the outer shape of the magnetic plate row 300. In this embodiment, the holding section 4b (see FIG. 18) is moved to place the magnetic plate row 300 on the mounting surface 91b of the base 9b. And the alignment plate (guide member) 10b driven by a linear actuator (not shown) is pushed into the groove (square recess) 304 of the magnetic plate row 300 from above, thereby aligning the magnetic plates 200. The groove 304 of the magnetic plate row 300 is an aggregate of the cut recesses 202 of the magnetic plate 200, and the thickness of the alignment plate 10b is formed slightly smaller than the groove width of the groove 304.
[0090]
By this operation, the inner surfaces of the magnetic plates 200 facing the cut recesses 202 are aligned flat. Further, since each magnetic plate 200 is mounted on the mounting surface 91b of the base 9b, the upper and lower end surfaces thereof are also aligned. Next, by raising the alignment plate 10b, the magnetic plate row 300 can be aligned on the base 9b. Note that a chamfered portion 101b is formed at the tip of the alignment plate 10b to facilitate insertion. It should be noted that insertion can be facilitated even by using a tapered alignment plate.
[0091]
(Example 6)
Another magnetic plate row alignment method will be described with reference to FIG.
In this embodiment, the alignment plate (guide member) 10b described in the fifth embodiment is provided in advance.Of the magnetic plate row 300groove304The permanent magnet members 11b are fixed at regular intervals to a conveyor belt 12b provided below a base 14b made of a non-magnetic thin plate. Thus, the magnetic plate 200 is sequentially placed on one end of the base 14b.Next companionWhen the conveyor belt 12b is operated while feeding, the magnetic plate 200 is attracted by the permanent magnet member 11b and moves rightward on the base 14b. The first sheet is sent until it comes into contact with the stopper block 13b, and then, when the specified number of sheets have been supplied, the conveyor 12b is stopped. Thereafter, the conveyor belt 12b is lowered to a position where no magnetic force acts on the magnetic plate 200, and the alignment plate 10b is raised, whereby the magnetic plate row 300 is aligned on the base 14b.
[0092]
In FIG. 21, the grooves are aligned on the basis of the groove, but the alignment on the basis of the outer shape is naturally possible. On the base 14b, a linear actuator (not shown) is provided on the left side of the alignment plate 10b in FIG. 21, and the piston rod of the linear actuator is reciprocated in parallel to the surface of the base 14b. The magnetic plate 200 is dropped immediately in front of the piston rod every time the arm moves backward, so that the magnetic plate 200 can be sequentially inserted, and other magnetic plate insertion methods can be adopted.
[0093]
By employing the above means, each magnetic plate 200 of the magnetic plate row 300 can be easily aligned.
(Example 7)
Another embodiment of the spiral body forming step of spirally arranging the magnetic plate rows 300 will be described with reference to FIGS.
[0094]
First, an example of the manufacturing apparatus used in this embodiment will be described with reference to FIG. Cups 1c and 2c are installed on the upper part of the magnetic plate row 300.
As shown in FIGS. 22 to 25, the cup (guide portion with pin) 1c includes a semi-cylindrical wall (also referred to as a lip) 12c having a semi-cylindrical guide surface 11c obtained by dividing a cylindrical surface in the axial direction. It comprises an upper end wall 13c provided at the upper end of the cylindrical wall 12c, and a guide pin 14c hanging down from the upper end wall 13c along the axis of the guide surface 11c.
[0095]
As shown in FIGS. 22 to 25, the cup (guide cylinder with pin) 2c includes a partial cylindrical wall (also referred to as an edge) 22c having a partially cylindrical guide surface 21c obtained by dividing a cylindrical surface in the axial direction. And an upper end wall 23c provided at an upper end of the cylindrical wall 22c.
Next, the operation will be described.
First, the cups 1c and 2c are lowered so that the edges 12c and 22c of the cups 1c and 2c slightly enter the grooves (square recesses) 304 of the magnetic plate row 300, and the cup 1c is moved to the right (X direction) and the cup 2c is moved to the left (X direction). Move at the same time. Thereby, the short side 200b on the inner end side of the magnetic plate 200a closest to the cup 1c of the magnetic plate row 300 is pressed against the guide pin 14c, and the inner end of the magnetic plate 200c closest to the cup 2c of the magnetic plate row 300 is pressed. The part 203 is pressed against the guide surface 21c of the cup 2c (FIG. 23).
[0096]
Further, when the cups 1c, 2c are moved in a direction approaching each other, the edges 12c, 22c of the cups 1c, 2c are accommodated in the grooves 304 of the magnetic plate row 300, and each magnetic plate 200 is opened in a fan shape as viewed from above. (FIG. 24).
Further, when the cups 1c and 2c are moved in a direction approaching each other, the end of the inner end 306 of the magnetic plate row 300 facing the groove 304 moves circularly along the inner peripheral surface of the cups 1c and 2c. When the cups 1c and 2c are integrated, the respective magnetic plates 200 are spirally arranged to form a spiral body 400 (FIG. 25).
[0097]
14c and 24c are stoppers for preventing the magnetic plate 200 from overflowing from the cups 1c and 2c when being guided by the cups 1c and 2c, respectively.
In the present embodiment, the cups 1c and 2c are arranged in a spiral so as to fit the edges of the cups 1c and 2c in the cut recesses 202 of the magnetic plate 200. A spiral shape may be used by taking advantage of contraction.
[0098]
(Example 8)
Another embodiment of the spiral body forming step of spirally arranging the magnetic plate rows 300 will be described with reference to FIGS.
In this embodiment, a half-split cylindrical cup (guide portion) 5c in which the guide pin 14c is omitted is used instead of the cup 1c of the sixth embodiment, and a half-split cylindrical cup ( The outer end surface 303 of the magnetic plate row 300 is moved to the guide surface of the cup 5c by moving the cups 5c, 6c in a direction approaching each other (the x direction, which is the laminating direction of the magnetic plates 200) by using the guide portion 6c. Each magnetic plate 200 is opened in a fan shape by displacing along the guide surface 61c of the cup 51c and the cup 6c to form a spiral body 400 (see FIG. 27). That is, in this embodiment, the respective magnetic plates 200 are aligned by displacing the outer edge 203 of the magnetic plate 200 along the guide surface 51c of the cup 5c and the guide surface 61c of the cup 6c. In this way, the spiral body 400 can be easily formed.
(Example 9)
Another embodiment of the spiral body forming step of spirally arranging the magnetic plate rows 300 will be described with reference to FIGS.
[0099]
In this embodiment, instead of the cups 5c and 6c of the eighth embodiment (see FIG. 22), a mounting disk 9c on which the magnetic plate 200 is mounted, and a cylindrical guide cylindrical wall (guide 7c), and the mounting disk 9c is rotatable by a motor 8c. Further, a part of the guide cylindrical wall 7c is opened, and the tip of the square tube 10c that houses the magnetic plate row 300 is fitted into this opening. The square cylinder 10c houses a piston rod 101c driven by a linear actuator (not shown).
[0100]
Next, the operation will be described.
When the piston rod 101c pushes the magnetic plate array 300 in the rectangular cylinder 10c onto the mounting disk 9c, and the motor 8c rotates the mounting disk 9c in synchronization with the pushing, the outside of each magnetic plate 200 of the magnetic plate array 300 is rotated. The end side 203 is developed along the inner peripheral surface (guide surface) of the guide cylindrical wall 7c to form a spiral body 400. In this way, the spiral body 400 can be easily formed.
[0101]
(Example 10)
Another embodiment of the spiral body forming step of spirally arranging the magnetic plate rows 300 will be described with reference to FIGS. However, FIG. 31 (a) shows the opening of the cylinder (guide cylinder) 4d in the AA section of FIG.MouthThe shape is shown in FIG.c) Indicates the opening of the cylinder 4d in the BB section of FIG.MouthThe shape is shown in FIG.e) Indicates the opening of the cylinder 4d in the cross section taken along the line CC in FIG.MouthShow the shape. Also, in FIG.b) Indicates the opening of the cylinder 4d in the AA section in FIG.In the mouthFIG. 31 shows an arrangement shape of each of the accommodated magnetic plates 200, and FIG.d) Indicates the opening of the cylinder 4d in the BB section of FIG.In the mouthFIG. 31 (f) shows an arrangement shape of each of the accommodated magnetic plates 200, and FIG.In the mouthThe arrangement shape of each accommodated magnetic plate 200 is shown.
[0102]
In this embodiment, an upper end opening (entrance) 41d having a shape slightly wider than the shape of the outer end surface of the magnetic plate row 300 in a plane perpendicular to the width direction (axial direction in the spiral arrangement) and a circular shape. A cylinder 4d having a lower end opening 42d and a guide surface 43d having a continuously changing opening shape from the inlet 41d to the outlet 42d is prepared, and the magnetic plate array 300 is inserted from the inlet 41d to the outlet 42d to form a magnetic plate array. The 300 magnetic plates 200 are gradually arranged in a spiral shape.
[0103]
With this configuration, a complicated spiral body forming operation can be realized by a simple process.
(Example 11)
Another embodiment of the plate piece arranging step of arranging the magnetic plate rows 300 in a spiral will be described with reference to FIGS.
[0104]
In this embodiment, there is provided a rotating cylinder (also referred to as a winding holder) 2e in which a slit groove 21e into which the outer end portion 204 of the magnetic plate is inserted in the axial direction is recessed on the inner peripheral surface. The magnetic plate 200 is set sequentially.
First, an example of the manufacturing apparatus used in this embodiment will be described with reference to FIG. The base 3e has a horizontal mounting surface 31e, and a winding holder (guide tube) 2e for turning the magnetic plate 200 into a spiral body 400 is rotatably disposed on the mounting surface 31e. An indexing device 4e incorporating a stepping motor (not shown) is fixedly installed on the base 3e on the lower surface of the winding holder 2e, and the upper surface 41e of the indexing device 4e is flush with the mounting surface 31e. It is installed in. A magnet 42e is fixed on the upper surface 41e of the index device 4e, and a cutout 23e is formed at a predetermined position on the outer peripheral surface of the winding holder 2e.
[0105]
Next, the operation of the above device will be described.
First, the winding holder 2e is moved in the x direction until the magnet 42e comes into close contact with the notch 23e, and the winding holder 2e is attracted by the magnet 42e. Thereby, the axis of the winding holder 2e is made to coincide with the rotation center of the upper surface 41e of the index device 4e.
Next, the magnetic plate 200 is pinched by the pinching claws 51e at the tips of a pair of pinching portions 5e mounted on a robot hand (not shown).Department5e transfers the magnetic plate 200 to a position immediately above the slit groove 21e at a predetermined position. After that, the magnetic plate 200 is pinchednailThe lower surface of 51e is lowered to a position just below the upper surface of the winding holder 2e. At this time, as shown in FIG. 33, since the chamfered portion 22e is formed at the upper open end of the slit groove 21e of the winding holder 2e, the magnetic plate 200 can be smoothly inserted into the slit groove 21e. Is possible. Thereafter, the pair of holding claws 51e are opened by a robot hand (not shown), and the magnetic plate 200 is separated from the holding claws 51e and falls into the lower slit groove 21e. After the magnetic plate 200 is inserted into the slit groove 21e, the holding claws 51e go to pick up the next magnetic plate 200 to be inserted, during which the winding holder 2e inserts the next magnetic plate 200 by the index device 4e. Is indexed to a position to be performed (turned by a predetermined angle).
[0106]
This operation is repeated a required number of times, and after the number of magnetic plates 200 equal to the number of the slit grooves 21e is spirally arranged, the winding holder 2e is clamped by the pair of clamping arms 52e of the clamping section 5e.32It is transported in the middle and X directions, and is set immediately below the holding guide 6e. The holding guide 6e is fixed to a lower end of a shaft 62e that is driven vertically by a linear actuator (not shown), and has a tapered pin 61e projecting downward from the lower end of the holding guide 6e.
[0107]
Next, the holding guide 6e is lowered, the pin 61e is fitted into the center hole of the spiral body 400 in the winding holder 2e, and the lower end surface of the holding guide 6e is inserted into the slit 21e. The pressing guide 6e is lowered until it comes into contact with the upper side 201. The outer diameter of the holding holder 6e is smaller than the inner diameter of the winding holder 2e to prevent interference. Next, when the robot hand (not shown) is raised, the winding holder 2e held by the pair of holding arms 52e is raised. Next, when the holding guide 6e is raised, the mounting surface 31e of the base 3e is placed. The spiral body 400 is left above.
[0108]
Instead of using the pin 61e for guiding, a ring for guiding the inner peripheral surface or the outer peripheral surface of the spiral body 400 facing the cylindrical groove 101 (see FIG. 11) may be used for guiding. Further, instead of the holding portion 5e, a normal feeding means such as a parts feeder may be used to individually insert the sheet one by one into the slit groove 21e. Further, instead of the index device 4e, the magnetic plate 200 may be inserted while rotating sequentially. Further, the winding holder 2e is fixed to the upper surface 4 of the index device 4e by using the magnet 42e.1Although it is positioned at the rotation center of e, a chuck device such as an actuator or a positioning pin may be provided on the upper surface 42e. Further, a plurality of magnetic plates 200 may be inserted at the same time.
[0109]
By adopting the above-described means, that is, the magnetic plates 200 are sequentially inserted into the winding holder 2e having the slit grooves 21e, and are arranged in a spiral shape in the winding holder 2e to form the spiral body 400, and thereafter, the winding is performed. The step of detaching the holder 2e from the spiral body 400 can be easily realized.
(Example 12)
An improved embodiment of the spiral body diameter reducing step shown in FIGS. 13 to 17 will be described with reference to FIGS. First, the device will be described.
[0110]
A circular opening 40f is provided through a table-like base 4f having a horizontal mounting surface 41f, and the upper end of the cylinder 1f is fitted and fixed in the opening 40f. The inner peripheral surface 11f of the cylinder 1f has a conical shape whose diameter decreases downward as in the case of FIG. Below the base 4f, a support plate 5f is fixedly provided on the base 4f, and the support plate 5f has an opening 50f located immediately below the opening 40f. A linear actuator 6f formed of, for example, a hydraulic cylinder is fixed to the support plate 5f, and its piston rod (receiving rod) 61f is vertically inserted into the cylinder 1f through the opening 50f. The holder 3f is fixed to the tip of the piston rod 61f, and the upper end surface 31f of the holder 3f is flush with the mounting surface 41f at the highest position.
[0111]
On the other hand, a linear actuator (not shown) composed of, for example, a hydraulic cylinder is provided above the base 4f and directly above the opening 40f, and the axial center of a piston rod (push rod) 7f is a piston rod. (Receiving rod) coincides with the axis of 61f. At the tip of the piston rod 7f, an attachment 8f having a shape suitable for pressing downward the upper end face (the end face on which the groove 4010 is formed) of the spiral body 4000 (see FIG. 14) is fixed.
[0112]
The upper surface 51f of the support plate 5f is a flat surface, on which a cylindrical body 20f as a jig for holding the ring 2f is placed. An annular plate-shaped step 22f is provided inside the hole 21f of the cylindrical body 20f, and the upper end opening side of the hole 21f is formed larger in diameter than the lower side. Reference numeral 2f denotes a ring fitted into the spiral body 4000 having a reduced diameter, which is fitted into the hole 21f and placed on the step 22f. The cylindrical body 20f can be moved right and left by a linear actuator (not shown).
[0113]
9f is a guide device (guide means) for pinching and guiding the spiral body 4000, which is fixed at a predetermined position on the mounting surface 41f of the base 4f and has an arm drive mechanism (not shown) therein. 35 includes a built-in base box portion 91f, a pair of arm portions 92f protruding leftward from the arm driving mechanism in FIG. 35, and a holding portion 93f fixed to the distal ends of both arm portions 92f so as to face each other. . The arm driving mechanism drives the holding portion 93f, and causes the holding portion 93f to hold the outer peripheral surface of the spiral body 4000 before diameter reduction.
[0114]
The operation of the diameter reducing device will be described.
First, the rod 61f and the holder 3f are retracted to the lowermost position. Next, the cylindrical body 20f holding the ring 2fToIt is set immediately below the cylinder 1f, and the rod 61f and the holder 3f are raised to the uppermost position through the ring 2f and the cylindrical body 20f. Next, the spiral body 4000 before the diameter reduction is transferred along the mounting surface 41f and mounted on the upper end surface 31f of the holder 3f.
[0115]
Next, the holding portion 93f is driven to cause the holding portion 93f to hold the outer peripheral surface of the spiral body 4000. Next, the attachment 8f is lowered to push the spiral body 4000 into the inner peripheral surface 11f of the cylinder 1f (see FIG. 36). At this time, the pressing force of the rod 7f exceeds the pressing force of the rod 61f, and the rod 61f and the holder 3f are lowered together with the spiral body 4000 by the urging of the rod 7f. As a result, as described above, the spiral body 4000 is reduced in diameter by the inner peripheral surface 11f of the cylinder 1f, and is pushed into the ring 2f from the outlet of the cylinder 1f (see FIG. 37). Finally, the cylindrical body 20f is pulled out to its original position, the reduced diameter spiral body 4000 is taken out together with the ring 2f, the outer peripheral surface of the spiral body 4000 is welded, and the spiral body 4000 is removed from the ring 2f.
[0116]
FIG. 39 is an enlarged view of the vicinity of the lower end of the rod 7f. A concave portion 71f is formed in the lower end surface 70f of the rod 7f, and a cylindrical wall-shaped projection 72f hangs around the concave portion 71f from the lower end surface 70f. The base portion 80f of the attachment 8f is press-fitted into the concave portion 71f, and a pin portion 82f hangs down from the center of the lower end surface of the base portion 80f along the axis of the piston rod 7f. The protrusion 72f is inserted into the ring-shaped groove 4010 of the spiral body 4000, and the pin 82f is inserted into the central groove 4000a of the spiral body 4000 to prevent displacement.
[0117]
With this configuration, the spiral body 4000 pushed into the cylinder 1f by the lower end surface of the base 80f does not deform as shown in FIG. 38, and can be reduced in diameter to a regular shape.
(Example 13)
Another embodiment of the step of reducing the diameter of the spiral body 4000 will be described with reference to FIGS.
[0118]
A rotating table 11g is fixed to an upper end of a rotating shaft 10g rotatably supported by a thrust bearing (not shown), and a shaft 12g stands upright from the center of the rotating table 11g. The shaft 12g is loosely fitted in the center hole of the spiral body 4000, and a thick holding disc 13g is loosely fitted on the upper portion of the shaft 12g. A screw (not shown) is formed at the upper end of the holding disc 13g, and a nut 14g is screwed therein. The amount of tightening by the nut 14g is set to such an extent that the spiral body 4000 can be relatively reduced in diameter relative to the turntable 11g and the holding disk 13g. The rotation shaft 10g is connected to a rotation resistance applying mechanism (not shown) that applies a predetermined rotation resistance (negative torque). As the rotation resistance applying mechanism, a friction plate is pressed with a predetermined force against a rotating disk (not shown) connected to the rotating shaft 10g, or an impeller (not shown) connected to the rotating shaft 10g is immersed in oil. A well-known mechanism for rotating or the like may be used.
[0119]
Rotary drums 2g and 3g are provided on both sides of the spiral body 4000, and the rotating shafts 21g and 31g are vertically set up together with the rotating shaft 10g. The rotating shafts 21g and 31g are connected to the rotating shaft of a motor with a built-in reduction gear mechanism (not shown), and rotate counterclockwise as shown in FIG. The motor with built-in reduction gear mechanism and the rotating drums 2g and 3g can be moved horizontally by a horizontal moving mechanism (not shown), and the rotating drums 2g and 3g are synchronized in directions approaching and moving away from each other. It is designed to move.
[0120]
Hereinafter, the operation of this device will be described.
As the rotating rotating drums 2g and 3g approach each other, the rotating drums 2g and 3g come into contact with the outer periphery of the spiral body 4000, that is, the sides forming the radial outer ends of the respective magnetic plates 200, whereby the spiral body 4000 rotates. Let me do. At this time, since the spiral body 4000 has the rotational resistance as described above, it is rotated by the rotation of the rotating drums 2g and 3g, but its rotation is delayed, and as a result, the outer circumference of the rotating drum 2g and 3g and the spiral body 4000 Friction occurs between the sides of the plate 200 that form the radially outer end, and the rotary drums 2g and 3g push the sides that form the radially outer end of each of the magnetic plates 200 in the diameter reducing direction, that is, in the substantially long side direction. As a result, the diameter of the spiral body 4000 is reduced. After diameter reduction is completed, the spiral body 4000 may be taken out by removing the nut 14g and the holding disc 13g.
[0121]
In this manner, the diameter of the spiral body 4000 can be easily reduced. Note that one or both of the rotating table 11g and the holding disk 13g may be fixed, and the above-described rotation resistance may be generated by friction between the rotating table 11g or the holding disk 13g and the spiral body 4000. Further, a large number of rotating drums may be provided.
[Brief description of the drawings]
FIG. 1 is a cross-sectional view illustrating a main part of a solenoid valve employing a spiral cylindrical stator manufactured in Example 1. FIG.
FIG. 2 is a perspective view of the cylindrical stator shown in FIG.
FIG. 3 is a perspective view showing a shape of one plate piece of the cylindrical stator shown in FIG. 2 before diameter reduction deformation.
FIG. 4 is a plan view showing a diameter reducing operation of each plate piece constituting the cylindrical stator shown in FIG. 2;
FIG. 5 is a schematic plan view of an apparatus for manufacturing a cylindrical stator according to the first embodiment.
6 is a half sectional view of the cylindrical stator manufacturing apparatus shown in FIG. 5;
FIG. 7 is an enlarged partial cross-sectional view of a part including a rotary table of the cylindrical stator manufacturing apparatus according to the first embodiment.
FIG. 8 is a schematic perspective view of a cylindrical stator plate piece arrangement device that performs a spiral arrangement according to a second embodiment.
FIG. 9 is a perspective view of a magnetic plate row before a spiral arrangement process to be mounted on the second embodiment.
FIG. 10 is a perspective view of one magnetic plate constituting the magnetic plate row of FIG. 9;
FIG. 11 is a perspective view of a cylindrical stator manufactured by the manufacturing method of FIG.
FIG. 12 is a process chart showing a spiral body forming operation by the apparatus of FIG. 8;
FIG. 13 is a cross-sectional view of a diameter reducing device that performs a diameter reducing operation according to a third embodiment.
FIG. 14 is an assembled sectional view of an attachment used in the diameter reducing device shown in FIG. 13;
FIG. 15 is a schematic partial sectional view illustrating a diameter reducing operation of the diameter reducing device shown in FIG. 13;
FIG. 16 is a schematic partial sectional view illustrating a diameter reducing operation of the diameter reducing device illustrated in FIG. 13;
17 is a schematic partial cross-sectional view illustrating a diameter reducing operation of the diameter reducing device shown in FIG.
FIG. 18 is a schematic perspective view showing a magnetic plate row aligning apparatus according to a fourth embodiment.
19 is an enlarged sectional view of a main part of FIG. 18;
FIG. 20 is a schematic perspective view showing a magnetic plate row aligning apparatus according to a fifth embodiment.
FIG. 21 is a schematic perspective view showing a magnetic plate row aligning apparatus according to a sixth embodiment.
FIG. 22 is a schematic perspective view showing a spiral body forming step of Example 7.
FIG. 23 is a schematic perspective view showing a spiral body forming step of Example 7.
FIG. 24 is a schematic perspective view showing a spiral body forming step of Example 7.
FIG. 25 is a schematic perspective view showing a spiral body forming step of Example 7.
FIG. 26 is a schematic perspective view showing a spiral body forming step of Example 8.
FIG. 27 is a schematic perspective view showing a spiral body forming step of Example 8.
FIG. 28 is a schematic perspective view showing a spiral body forming step of Example 9.
FIG. 29 is a schematic perspective view showing a spiral body forming step of Example 9.
FIG. 30 is a schematic perspective view showing a spiral body forming step of Example 10.
FIG. 31 is a view showing a radial opening shape of each part of the cylinder and a shape of a magnetic plate row in FIG. 30;
FIG. 32 is a schematic perspective view showing a spiral body forming apparatus according to an eleventh embodiment.
FIG. 33 is an enlarged schematic perspective view of a main part of FIG. 33.
FIG. 34 is a plan view of a main part of the diameter reducing device of FIG. 35;
FIG. 35 is a sectional view of a diameter reducing device that performs a diameter reducing operation according to a twelfth embodiment.
FIG. 36 is a schematic sectional view showing a diameter reducing step in Example 12.
FIG. 37 is a schematic sectional view showing a diameter reducing step of Example 12.
FIG. 38 is an enlarged sectional view of a main part of the diameter reducing device of FIG. 35;
39 is an enlarged sectional view of a main part of the diameter reducing device of FIG. 35.
FIG. 40 is a schematic plan view showing a diameter reducing step of Example 13.
FIG. 41 is a schematic front view of a diameter reducing device that performs a diameter reducing step according to a thirteenth embodiment.
[Explanation of symbols]
(In FIGS. 1 to 17)
100 is a cylindrical stator, 200 is a plate (magnetic plate), and 300 is a row of magnetic plates.
(FIGS. 18 to 21)
2b is an alignment plate (guide member), 10b is an alignment plate (guide member).
(FIGS. 22 to 29)
1c, 2c, 5c, and 6c are cups (guide portions), 11c and 21c are guide surfaces, and 7c is a guide cylindrical wall (guide portion).
(FIGS. 30 to 31)
4d is a cylinder (guide cylinder).
(In FIGS. 32 and 33)
2e is a winding holder (guide cylinder), 21e is a slit groove.
(FIGS. 34 to 39)
1f is a cylinder (guide cylinder), 7f is a piston rod (push rod), 61f is a piston rod (receiving rod), and 9f is a guide device (guide means).
(FIGS. 40 and 41)
2g and 3g are rotary drums.

Claims (19)

A plate piece arrangement step of spirally arranging a plurality of magnetic plates having the same thickness having soft magnetism, and pressing the outer ends of the respective magnetic plates in a diameter reducing direction by a pressing unit to reduce the diameters of the respective magnetic plates. In the method of manufacturing a cylindrical stator comprising a diameter reducing step,
The plate piece arranging step is a row forming step of forming a magnetic plate row by arranging magnetic plate groups having the same thickness in which the inner ends are curved in the thickness direction, and forming a row-direction tip of the magnetic plate row. The inner end portion of each magnetic plate is sequentially pushed into the inside of the guide tube while the convex surface of the inner end portion of the magnetic plate is pressed against the inner peripheral surface of the cylindrical guide tube. And a main winding step of slidably arranging in a spiral shape along the inner peripheral surface of the guide cylinder. Urges the front Symbol magnetic plate column the magnetic plate the pin concave of the inner end portion in a state pressed against the outer circumferential surface of the pin forming the column base end to approximately the thickness direction of the magnetic plate column A temporary winding step of arranging the outer ends of the magnetic plates on the base side in the column direction of the magnetic plate row in a substantially radial direction with the pin as a center. 2. The method for manufacturing a cylindrical stator according to claim 1, wherein the step is completed after completion and before completion of the main winding step. A magnetic plate formed by arranging equal-thickness magnetic plate groups having notch recesses in which a central portion in the longitudinal direction adjacent to the curved inner end portion is cut from the long side by a predetermined depth in the width direction and arranged in a line in the thickness direction. A table having a mounting surface on which the rows are slidably mounted,
A guide provided with a guide surface that is erected on the mounting surface and aligns each outer end of the magnetic plate in a line,
The axis is arranged above the mounting surface in a posture extending perpendicularly from the mounting surface, and a part of the cylindrical surface is notched in the axial direction from a predetermined position of the opening end on the mounting surface side. A guide cylinder having a formed insertion port,
A guide tube elevating mechanism that moves the guide tube up and down along the axis,
The inner ends of the respective magnetic plates are urged in the direction of the guide cylinder, and the inner ends of the respective magnetic plates are sequentially inserted from the front end of the row of magnetic plates into the guide cylinder through the insertion port. By using a magnetic plate row pushing mechanism in which the inner ends of the respective magnetic plates are slid along the inner peripheral surface of the guide cylinder by being pushed and arranged in a spiral shape,
A method for manufacturing a cylindrical stator, wherein the magnetic plates are arranged in a cylindrical and spiral shape. The magnetic plate row pushing mechanism,
A pin arranged to be movable up and down with respect to the mounting surface and movable along the mounting surface;
By pressing the pin toward the substantially thickness direction of the magnetic plate row in a state where the pin is pressed against the concave surface of the inner end of the magnetic plate forming the column direction base end of the magnetic plate row, A pin pushing mechanism for arranging the outer ends of the magnetic plates on the row direction base end side of the plate row in a substantially radial direction with the pin as a center,
After arranging the outer ends of the magnetic plates on the row direction base end side of the magnetic plate row in a substantially radial direction around the pins, a pin lifting mechanism that raises the pins in the axial direction,
A stopper that has a concave surface that is in contact with the outer end of the magnetic plate row arranged in a substantially radial direction and is movably disposed on the mounting surface along the mounting surface;
The stoppers are urged in the direction of the guide cylinder, and the inner ends of the magnetic plates are sequentially pushed from the front end side of the magnetic plate row into the guide cylinders through the insertion holes in order, thereby reducing the magnetic properties of the magnetic plates. Using a stopper pushing mechanism that slides the inner end of the plate along the inner peripheral surface of the guide cylinder and arranges it in a spiral shape,
4. The method for manufacturing a cylindrical stator according to claim 3, wherein the magnetic plates are arranged in a cylindrical and spiral shape. A plate piece arrangement step of spirally arranging a plurality of magnetic plates having the same thickness having soft magnetism, and pressing the outer ends of the respective magnetic plates in a diameter reducing direction by a pressing unit to reduce the diameters of the respective magnetic plates. In the method of manufacturing a cylindrical stator comprising a diameter reducing step,
In the diameter reducing step, at least an inner end portion of the spiral plate formed by arranging a group of magnetic plates having the same thickness in a spiral shape into a cylinder having a conical inner peripheral surface is placed in a cylinder having a conical inner peripheral surface. A method for manufacturing a cylindrical stator, comprising a step of reducing the diameter of the spiral body by pushing the spiral body in a direction of a small diameter in the axial direction while matching the axis of the conical inner peripheral surface. The diameter reducing step includes a step of disposing a receiving ring coaxially with the cylinder near the small diameter opening of the cylinder, and fitting the spiral body reduced in diameter and pushed out from the small diameter opening into the receiving ring. A method for manufacturing a cylindrical stator according to claim 5. The diameter reducing step includes a cylinder having a conical inner peripheral surface, a pushing rod for urging an end surface of the spiral body in the cylinder to push the spiral body in a small diameter direction, and moving the rod along an axis of the cylinder. 6. The method for manufacturing a cylindrical stator according to claim 5, wherein the method is performed using a linear actuator that moves forward and backward. The diameter reducing step includes a receiving rod inserted into the cylinder, and a step of pushing the spiral body into the cylinder by the push rod while sandwiching both end faces of the spiral body with the end faces of both rods. The method for manufacturing a cylindrical stator according to claim 7, further comprising: In the diameter reducing step, the outer peripheral surface of the spiral body is relatively displaceable in the axial direction and is not displaceable in the radial direction near the inlet-side end face of the cylinder while the axis of the spiral body is aligned with the axis of the cylinder. Preparing a guide means having a guide surface to be in contact with,
9. The method for manufacturing a cylindrical stator according to claim 8, wherein the pushing of the spiral body into the cylinder is performed while bringing the guide surface of the guide means into contact with the outer peripheral surface of the spiral body. A plate piece arrangement step of spirally arranging a plurality of magnetic plates having the same thickness having soft magnetism, and pressing the outer ends of the respective magnetic plates in a diameter reducing direction by a pressing unit to reduce the diameters of the respective magnetic plates. In the method of manufacturing a cylindrical stator comprising a diameter reducing step,
The plate piece arranging step includes a row forming step of forming a magnetic plate row by arranging magnetic plate groups of equal thickness whose inner ends are curved in a thickness direction, and spirally arranging the magnetic plate row. And a step of
In the row forming step, a guide member having a plurality of guide surfaces capable of substantially abutting on a plurality of faces of the magnetic plate row having an ideal shape is prepared, and a large number of the magnetic plates are stacked in a substantially thickness direction. A shaped magnetic plate row is formed, and a plurality of surfaces of the unshaped magnetic plate row are brought into contact with the guide surfaces to align the respective magnetic plates, thereby shaping the end face shape of the unshaped magnetic plate row. A method for manufacturing a cylindrical stator, comprising the steps of: In the row forming step, a frame body serving as the guide member having a shaping hole substantially matching the ideal shape of the magnetic plate row is prepared, and a large number of the magnetic plates are laminated in a substantially thickness direction to form the magnetic plate. A step of forming a shaped magnetic plate row, pushing the unshaped magnetic plate row into the shaping hole, aligning the magnetic plates, and shaping the end face shape of the unshaped magnetic plate row. 11. The method for manufacturing a cylindrical stator according to item 10. In the row forming step, a plate-shaped guide member having a thickness substantially equal to the opening width of the groove of the magnetic plate row is prepared, and a number of the magnetic plates having cut recesses in which the same portions are cut into the same shape are prepared. Forming an unshaped magnetic plate row having the groove portion by laminating in a substantially thickness direction, aligning the magnetic plates by fitting the guide member into the groove portion of the unshaped magnetic plate row, The method for manufacturing a cylindrical stator according to claim 10, further comprising a step of shaping an end face shape of the unshaped magnetic plate row. In the row forming step, a predetermined number of the magnetic plates having cut recesses in which the same portions are cut into the same shape are prepared, and a plate-like guide member having a thickness substantially equal to the opening width of the cut recess is prepared. 11. The method for manufacturing a cylindrical stator according to claim 10, further comprising a step of forming the magnetic plate row by sequentially stacking the magnetic plates while fitting the cut notch of the magnetic plate into the guide member. A plate piece arrangement step of spirally arranging a plurality of magnetic plates having the same thickness having soft magnetism, and pressing the outer ends of the respective magnetic plates in a diameter reducing direction by a pressing unit to reduce the diameters of the respective magnetic plates. In the method of manufacturing a cylindrical stator comprising a diameter reducing step,
In the plate piece disposing step, a group of equal-thickness magnetic plates having a notch concave portion in which a central portion in the longitudinal direction adjacent to the curved inner end portion is cut from the long side by a predetermined depth in the width direction is arranged in a line in the thickness direction. A row forming step of forming a magnetic plate row by arranging the magnetic plate row, and a step of spirally arranging the magnetic plate row,
The step of arranging the magnetic plate row in a spiral shape includes urging the magnetic plate row in a stacking direction toward a partially cylindrical guide surface to press the magnetic plate row against the guide surface, A method of manufacturing the cylindrical stator, the method comprising a step of rotating along a spiral to develop in a spiral shape. The step of spirally arranging the magnetic plate rows includes a pin having a partial cylindrical wall having a partial cylindrical guide surface and a guide pin erected along the axis of the partial cylindrical guide surface. A guide portion, a pinless guide portion having a partial cylindrical wall having a partially cylindrical guide surface and having a relative displacement with respect to the pinned guide portion so as to expand and contract the distance between the pinned guide portion; And pressing the inner end of the magnetic plate on one end side in the row direction of the magnetic plate row against the guide surface of the pinless guide portion, and pressing the magnetic plate on the other end side in the row direction of the magnetic plate row. The inner end portion is pressed against the outer peripheral surface of the guide pin, and the two guide portions are moved closer to each other to move the inner end portion of the magnetic plate in order from one end side of the magnetic plate row in the row direction of the pinless guide portion. It is slid along the guide surface and arranged in a spiral, and the row direction of the magnetic plate row Method for producing a cylindrical stator of claim 14 comprising the step of arranging the inner end portion of the magnetic plate of the end side in a spiral inside the guide surface about said pin. The step of spirally arranging the magnetic plate rows includes preparing a pair of semi-cylindrical guide parts having a partially cylindrical guide surface and facing each other, and providing the magnetic plate row at one end side in the row direction of the magnetic plate rows. A magnetic plate is pressed against the guide surface of one of the guide portions, the magnetic plate at the other end in the row direction of the magnetic plate row is pressed against the other guide portion, and the two guide portions are brought closer to each other so that the two guides are brought close to each other. 15. The method for manufacturing a cylindrical stator according to claim 14, further comprising a step of sliding each of said magnetic plates along a surface to arrange them in a spiral. The step of spirally arranging the magnetic plate row includes preparing a rotatable guide portion having a cylindrical guide surface, and setting the outer end of the magnetic plate, which forms the tip in the row direction of the magnetic plate row, to the outer end. Pressing the magnetic plate row into the guide portion while pressing the guide portion against the guide surface of the guide portion and rotating the guide portion, the respective magnetic plates of the magnetic plate row are spirally formed in order from the front end side along the guide surface. The method for manufacturing a cylindrical stator according to claim 14, further comprising a step of arranging the cylindrical stator. A plate piece arrangement step of spirally arranging a plurality of magnetic plates having the same thickness having soft magnetism, and pressing the outer ends of the respective magnetic plates in a diameter reducing direction by a pressing unit to reduce the diameters of the respective magnetic plates. In the method of manufacturing a cylindrical stator comprising a diameter reducing step,
The plate piece arranging step includes a row forming step of arranging magnetic plate groups having a curved inner end portion in equal thickness in a row in the thickness direction to form a magnetic plate row, and arranging the magnetic plate rows in a spiral shape. And a step of
In the step of spirally arranging the magnetic plate rows, the inlet has a shape substantially matching the shape of the end face perpendicular to the axial direction after the spiral body of the magnetic plate row is formed, and the outlet is formed in a circular shape from the inlet. Prepare a guide cylinder having a guide surface whose opening shape changes continuously to the outlet, and insert the magnetic plate row from the inlet to the outlet to gradually form each magnetic plate of the magnetic plate row into a spiral shape. A method for manufacturing a cylindrical stator, comprising a step of arranging. A plate piece arrangement step of spirally arranging a plurality of magnetic plates having the same thickness having soft magnetism, and pressing the outer ends of the respective magnetic plates in a diameter reducing direction by a pressing unit to reduce the diameters of the respective magnetic plates. In the method of manufacturing a cylindrical stator comprising a diameter reducing step,
The plate piece disposing step prepares a guide cylinder in which a number of positioning grooves into which the outer end of the magnetic plate can be inserted in the width direction are formed substantially radially on an inner peripheral surface, and the magnetic plates are individually guided. A method of manufacturing the cylindrical stator, comprising: moving the magnetic plates in the axial direction of the cylinder, inserting the outer ends of the magnetic plates into the positioning grooves one by one, and arranging the respective magnetic plates in a spiral shape. .

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