JP6746145B1 - Cylindrical laminated body manufacturing equipment - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a tubular laminated body manufacturing apparatus capable of ensuring shape accuracy. A winding machine (9) winds a base material (2) in an annular shape and conveys it to a press machine (10). The press machine 10 press-molds the notch 6 and the joint 7 on the annular base material 2. The base material 2 on which the notch portion 6 and the joint portion 7 are formed is wound into an annular shape to be formed into a tubular shape having a plurality of layers. The joining machine 11 integrally fixes a group of a plurality of laminated layers 3 through a joining portion 7 by caulking. [Selection diagram] Figure 2

Description

The present invention relates to a tubular laminate manufacturing apparatus for producing a tubular laminate.

2. Description of the Related Art Conventionally, a tubular laminate manufacturing apparatus for producing a tubular laminate in which a base material is wound in plural layers in an annular shape is well known (see Patent Document 1, etc.). On the inner peripheral surface of this cylindrical laminated body, a processed shape portion formed of, for example, a notch or the like is formed. This type of tubular laminated body manufacturing apparatus manufactures a tubular laminated body composed of a plurality of layers by, for example, forming a notch in a base material and winding it around in a circumferential manner.

JP-A-6-303747

However, in the case of the above-mentioned construction method, since the base material is processed into an annular shape after the base material is processed into a notch or the like, the curvature is changed between the cutout portion and the other portions, and the circularity of the tubular laminate or There was a problem that the diameter accuracy could not be secured.

An object of the present invention is to provide a tubular laminate manufacturing apparatus capable of ensuring shape accuracy.

A tubular laminated body manufacturing apparatus that solves the above problems is a press machine that forms a processed shape portion by press working on a base material that is wound into an annular shape, and a cylinder of a plurality of layers that is wound into the base material. A joining machine for fixing a group of layers formed in a shape via the joining section formed in each layer while aligning the positions of the working sections of each layer.

According to the present invention, it is possible to ensure the shape accuracy of the tubular laminate.

The perspective view of the cylindrical laminated body of one embodiment. The block diagram of a cylindrical laminated body manufacturing apparatus. Schematic of a press machine. Schematic of a joining processing machine. It is an operation|movement figure of a press machine, (a) is a figure at the time of non-operation, (b) is a figure at the time of operation. It is an operation|movement figure of a joining processing machine, (a) is a figure at the time of non-operation, (b) is a figure at the time of operation. FIG. 6 is an operation diagram showing a state in which the seat portion of the joining machine is moved.

Hereinafter, an embodiment of the tubular laminate manufacturing apparatus will be described with reference to FIGS.
As shown in FIG. 1, the tubular laminated body 1 has a tubular shape in which a plurality of annular layers 3 are stacked in the stacking direction (Z-axis direction in FIG. 1) by winding a plurality of base materials 2 in an annular shape. I am doing it. The base material 2 is made of, for example, a strip-shaped steel plate. On the inner peripheral surface of the cylindrical laminated body 1, the processed shape portion 4 extending in the height direction of the cylindrical laminated body 1 (Z-axis direction in FIG. 1) is formed in the circumferential direction of the inner peripheral surface 5 of the cylindrical laminated body 1. In, a plurality of (four in this example) are formed at equal intervals. The processed shape portion 4 is a cutout portion 6 formed by cutting out a part of the base material 2. The upper and lower layers of each layer 3 are fixed to each other via a joint portion 7 formed in each layer 3.

As shown in FIG. 2, a tubular laminate manufacturing apparatus 8 for producing the tubular laminate 1 includes a winding machine 9 that winds the base material 2 and sends the base material 2 in an annular shape, and presses the base material 2 after the winding process. And a joining machine 11 for fixing the layered base materials 2 laminated after the press working. The winding machine 9, the press machine 10, and the joining machine 11 are unitized as an integrated device.

The winding machine 9 includes a plurality of transport rollers 12 and a movable roller 13 that is movable according to the diameter of the base material 2 that is processed into an annular shape. The position of the movable roller 13 is switched in the radial direction of the base material 2 (direction of arrow A in FIG. 2) to set the diameter of the base material 2 formed in an annular shape.

As shown in FIG. 3, the die unit 14 of the press machine 10 includes a fixed die 15 and a movable die 16 movable with respect to the fixed die 15. The movable die 16 includes a cutting portion 17 that cuts a part of the base material 2 and a punching portion 18 that pushes out the base material 2 with a predetermined pressure. A pair of embossing parts 18 are provided so as to be arranged on both sides of the cutting part 17. The fixed die 15 is formed with an escape portion 19 through which the cutting portion 17 and the embossing portion 18 can pass. The escape portion 19 is, for example, a through hole. The press machine 10 press-forms the machined shape portion 4 on the edge portion of the base material 2 by the cutting portion 17, and presses the plurality of joint portions 7 on the base material 2 by the pair of embossing portions 18. The cutout 6 has a shape obtained by cutting out a part of the edge of the base material 2.

As shown in FIG. 4, the joining machine 11 includes a seat portion 20 on which a group of layers 3 stacked in a plurality of layers is placed, and a head for applying a mechanical shock to the joining portion 7 to fix each layer 3. And a section 21. The head portion 21 moves up and down with respect to the seat portion 20. The joining machine 11 is a caulking machine that integrally fixes the group of layers 3 by caulking. The head portion 21 is formed with a pair of rod-shaped tools 22 for applying a pressing force from above to the joint portion 7 positioned between the upper and lower layers in the crimping process. The joining machine 11 fixes a group of a plurality of laminated layers 3 via the joining portions 7 formed on each layer 3 while aligning the positions of the processed shape portions 4 of each layer 3.

Returning to FIG. 1, the tubular laminate manufacturing apparatus 8 includes a positioning mechanism 23 that aligns the layers 3 of the base material 2 in the radial direction of the tubular laminate 1 during the joining process by the joining machine 11. The positioning mechanism 23 includes a support portion 24 located on the inner diameter side of the base material 2 wound in an annular shape, and a pressing portion 25 movable with respect to the support portion 24. The support portion 24 is formed in an arc shape along the inner circumference of the base material 2 and is fixed so that its position does not move. The pressing portion 25 is formed in an arc shape along the outer circumference of the base material 2. The pressing portion 25 switches the position in the radial direction of the base material 2 (direction of arrow B in FIG. 1) to position the plurality of layers 3 together with the support portion 24 in the radial direction.

Next, the operation of the tubular laminate manufacturing apparatus 8 of the present embodiment will be described with reference to FIGS. 5 to 7.
As shown in FIG. 5A, the strip-shaped base material 2 is conveyed to the press processing machine 10 while being wound in an annular shape by the winding processing machine 9. As shown in FIG. 5B, when the base material 2 is conveyed by a predetermined amount, the conveyance of the base material 2 is temporarily stopped, and the movable die 16 of the press working machine 10 is operated downward to move the base material 2 Pressed. At the time of this press working, the notch 6 is formed in the base material 2 by the cutting part 17, and the pair of joining parts 7 is formed by the punching part 18. The press machine 10 periodically repeats the press work of the base material 2 so that the cutouts 6 are formed at equal intervals in the circumferential direction on the base material 2 that is conveyed while being wound in an annular shape.

As shown in the partial enlarged views of FIGS. 6A and 6B, the joint portion 7 is composed of a boss-shaped protrusion having a hole shape on one surface side of the base material 2. The joint portion 7 forming a boss-like protrusion has a shape having a convex portion 27 and a concave portion 28. The joint portions 7 are, for example, cylindrical protrusions, and are arranged in pairs on both sides of the cutout portion 6. The recess 28 of the joint 7 has a circular opening.

As shown in FIG. 6A, after the press-processed base material 2 is wound a plurality of times around to form a layer, the joining machine 11 performs a crimping process on the layered base material 2. It is preferable that the crimping is performed, for example, every time the base material 2 is laminated for one round. Further, at the time of caulking, the joint portions 7 of the lowermost layer 3 are fitted into the grooves 30 formed in plural on the upper surface of the seat portion 20, respectively. During the laminating process, the base material 2 is aligned in the radial direction by the positioning mechanism 23. In the case of this example, in a state where the inner peripheral surface of the base material 2 is supported by the support portion 24, the movable pressing portion 25 is pressed against the outer periphery of the base material 2 to align the layers 3 in the radial direction.

As shown in FIG. 6B, the joining machine 11 places the layered base material 2 on the seat portion 20 and operates the head portion 21 downward during caulking. At this time, the tool 22 of the head portion 21 is inserted into the concave portion 28 of the joining portion 7 located in the uppermost layer and pushed from above to fix the joining portions 7 arranged in the stacking direction. As a result, the convex portion of the joint portion 7 of the upper layer 3 is tightly fitted into the concave portion of the lower layer 3, and the group of layers 3 is integrally fixed.

As shown in FIG. 7, in the joining machine 11, the seat portion 20 moves downward as the number of layers 3 placed on the seat portion 20 increases. That is, as the layers 3 are sequentially stacked, the seat portion 20 of the joining machine 11 moves downward, so that the position of the seat portion 20 in the height direction is adjusted. Then, a series of winding steps, pressing steps, and caulking are performed to manufacture the tubular laminated body 1 in which the plurality of layers 3 are continuous in the laminating direction.

According to the tubular laminated body manufacturing apparatus 8 of the above embodiment, the following effects can be obtained.
After the base material 2 was wound in an annular shape, the notch 6 was formed in the base material 2 by press working. Therefore, even when the notch 6 is formed in the base material 2, the curvature of the base material 2 does not significantly change between the notch 6 and other portions. Therefore, the shape accuracy can be ensured in the cylindrical laminated body 1 manufactured by winding the base material 2 around a plurality of times. Therefore, the circularity of the cylindrical laminated body 1 can be maintained even after pressing. Further, when the number of crimping points is n points per revolution and the crimping pitch is Pmm, the crimping pitch P is kept uniform by NC (Numerical Control) control, so that a circular shape having a circumferential length of n×P and a diameter of n×P/π is formed. The cylindrical laminated body 1 of can be obtained.

The base material 2 has a strip shape. The press machine 10 forms a plurality of notches 6 along the circumferential direction of the cylindrical layer 3 in each layer 3 of the base material 2. Therefore, it is possible to manufacture the tubular laminate 1 having a tubular shape in which the strips are laminated in an annular shape and having the plurality of notches 6 inside thereof with high shape accuracy.

The joining machine 11 fixes each layer 3 by the joining part 7 every time the base material 2 is laminated for one round. As described above, if the caulking process is performed every time the base material 2 is laminated for one round, the joint portion 7 can be more reliably fixed.

In the joining machine 11, the position of the seat 20 is adjusted according to the thickness of the base material 2. Therefore, even if the base material 2 is overlapped many times and becomes thick in the laminating direction, the bonding machine 11 can fix the layers 3 to each other.

Since the cylindrical laminate manufacturing apparatus 8 is provided with the positioning mechanism 23, when the layers 3 of the base material 2 are fixed by the joining machine 11, this fixing can be performed accurately.
The present embodiment can be modified and implemented as follows. The present embodiment and the following modified examples can be implemented in combination with each other within a technically consistent range.

The notch 6 is not limited to being provided on the inner peripheral surface 5 of the tubular laminate 1, but may be formed on the outer peripheral surface of the tubular laminate 1, for example.
-The notch portion 6 and the joint portion 7 may be manufactured by different pressing processes.

The processed shape portion 4 is not limited to the cutout portion 6 and may have another shape such as a hole or a hole.
The processed shape portion 4 is not formed on the edge portion of the base material 2 and may be provided at another position such as the center of the base material 2 in the width direction.

The crimping may be performed, for example, when the base material 2 is wound to some extent (for example, about 5 turns). In this case, since the crimping is performed after the base material 2 is wound to some extent, the crimping of each layer 3 can be efficiently performed.

The number of the joints 7 is not limited to being provided in plural, and may be one.
The joint portion 7 may be arranged at a position apart from the cutout portion 6.
The joining portion 7 is not limited to the boss-shaped protrusion and may have any shape as long as it can lock the upper and lower layers of the base material 2.

The base material 2 is not limited to a steel plate, and may be a resin material, for example.
The base material 2 is not limited to the band shape, and may have another shape such as a cylinder or a square pillar.
-The positioning mechanism 23 may be omitted from the device.

The tubular laminated body 1 is not limited to the cylindrical shape, and may have another tubular shape such as a square shape.
-The cylindrical laminated body 1 may be, for example, an iron core of an electrical component. Further, the tubular laminate 1 may be any of various devices and articles formed by laminating the base material 2.

Next, the technical idea that can be understood from the above-described embodiment and modification will be described.
(A) In the tubular laminated body manufacturing apparatus, the joining processing machine includes a seat portion on which the base material after press working is placed, and a head for applying a mechanical shock to the joining portion to fix the layers. And the position of the seat is adjusted according to the thickness of the base material.

(B) The tubular laminated body manufacturing apparatus includes a positioning mechanism that aligns each layer of the base material in the radial direction of the tubular laminated body when the base material is processed by the joining machine.

(C) a base material wound in an annular shape, a pressing step of forming a processed shape portion by a press working machine, and a group of the layers formed by winding the base material into a multi-layered tubular shape, A method for manufacturing a tubular laminate, comprising: a joining step of fixing the processed shape portions of each layer by a joining machine through the joining portions formed in each layer.

DESCRIPTION OF SYMBOLS 1... Cylindrical laminated body, 2... Base material, 3... Layer, 4... Processed shape part, 6... Notch part, 7... Joining part, 8... Cylindrical laminated body manufacturing apparatus, 10... Press processing machine, 11... Joining Processing machine, 14... Mold part.

Claims (3)

A press machine having a cutting section that forms a processed shape section by press working and a punching section that forms a joint section in the base material that is wound into an annular shape,
The base material is wound feed a group of layers formed in a cylindrical shape of the plurality of layers, while the position of the machining shape of the layers are combined, bonding process for fixing through the joint formed in the layers And a tubular laminated body manufacturing apparatus. The base material is a strip material,
The tubular laminate manufacturing apparatus according to claim 1, wherein the press working machine forms a plurality of the worked shape portions along the circumferential direction of the tubular shaped layer in each layer of the base material. The said joining machine performs fixing of each said layer by the said joining part, when the said base material is laminated|stacked for 1 round, or when the said base material is wound several turns or more. Device for manufacturing a cylindrical laminate.