JP2020082189A - Connection cutting device and connection cutting method - Google Patents

Abstract

To provide a connection cutting device which can cut off a product connected at a connection from a work-piece reliably and with good efficiency, and can prevent formation of burr on a product side cut part.SOLUTION: A punching unit includes: a lower die 22 which is positioned on an underside of a work-piece and of which an upper part is polygonal; and a punching head 21 which is positioned above the lower die 22, rotates around a central axis same as a central axis 22c of the lower die 22, comprises an upper blade 21b, and is vertically movable. The punch head 21 is rotatable so that an inner side of the upper blade 21b is positioned on each side 22a of an outer peripheral part of the lower die 22. By lowering the upper blade 21b in the state that the central axis 22c is positioned on a product side of the work-piece and the side 22a of the lower die 22 and the inner side of the upper blade 21b are positioned at a tip of a connection of the work-piece, the connection can be cut.SELECTED DRAWING: Figure 4

Description

The present invention relates to a connecting portion cutting device and a connecting portion cutting method for separating a product connected to a work by a connecting portion such as a micro joint.

When cutting out one or more products having a predetermined shape from a plate material such as metal, punching is performed by a turret punch press or the like. At the time of punching, in order to improve the work efficiency of punching, by processing the product and the frame part in a state where they are connected by a connecting part such as a micro joint, and cutting the connecting part in a later step, The method of separating products is often adopted.
Several methods have been proposed as a method of separating a product from a work composed of a frame portion and a product connected by a connecting portion.

Patent Document 1 discloses a plurality of gripping portions that are provided to grip an end surface of a plate material and that can move up and down in a height direction orthogonal to the plate material, a vibration generating unit that vibrates the gripping portion, and a height position of the gripping portion. There is disclosed a connecting portion separating device provided with a height control means for controlling each gripping portion.

Further, in Patent Document 2, a cushion member for mounting a work and supporting the entire surface of the work, and a movable member provided on the work are provided, and a load is applied by a pressing head to shear a connection part of an arbitrary part to work the part. There is disclosed a separation device for connecting part processed parts, which comprises a pressing device for separating the parts and a positioning means for positioning the parts to be separated in the vicinity of the connection part based on the connection part processing information.

[Problems to be Solved by the Invention]
In the connecting portion separating device disclosed in Patent Document 1, the outer peripheral portion of the work is gripped, and the gripped state is vertically vibrated to separate the connecting portion and the product. In the case of this separating device, when the plate thickness of the work is large, it may be difficult to separate the products due to the position and shape of the connecting portion. In addition, there is a problem in that noise is generated due to violent vibration, separated products fall apart and fall apart, and burrs are likely to occur in the connection part separation part on the product side. It was

In the device for separating processed parts of the connection part disclosed in Patent Document 2, the work is placed on the cushion member, and the connection part is sheared by pressing the connection part with the pressing head. .. Since the connection part is pressed while the work is placed on the cushion member, there is a problem that after cutting, the tip of the connection part bends downward and burrs easily occur at the cutting part on the product side. It was

If the burr generated during cutting remains in the product after being separated from the work, it is necessary to remove the burr from the viewpoints of damage to other products due to the burr, handling problems, product quality, etc. .. Therefore, it has been an important subject to prevent the occurrence of burrs on the product side when disconnecting the connection portion.

JP, 2009-39747, A JP-A-8-206995

Means for Solving the Problems and Their Effects

The present invention has been made in view of the above problems, and a product connected by a connecting portion such as a micro joint can be reliably and efficiently separated from a workpiece, and a burr is formed on a cutting portion on the product side. It is an object of the present invention to provide a connecting portion cutting device and a connecting portion cutting method that do not cause the occurrence.

In order to achieve the above-mentioned object, the connection part disconnecting device (1) according to the present invention comprises:
It is a device that separates the product connected at the connection part from the work,
A punching unit for cutting the connecting portion,
The punching unit is located on the lower surface of the work and has a polygonal lower die and an upper portion thereof located above the lower die and rotates about the same central axis as the central axis of the lower die, It is configured to include a vertically movable punching head with an upper blade,
The inner side of the upper blade, the punching head is configured to be rotatable so as to be located on each side of the outer peripheral portion of the lower mold,
The central axis is located on the product side of the work, the sides of the lower die and the inner side of the upper blade are located at the tip of the connecting portion of the work, and the upper blade is lowered. The connection portion is configured to be disconnected.

According to the above-mentioned connecting portion cutting device (1), when the connecting portion of the work is cut, the side of the polygon of the lower mold is the tip portion of the connecting portion, in other words, the boundary portion between the tip portion of the connecting portion and the product. The connection is disconnected in the positioned state. At the time of cutting, since the product side is firmly supported by the lower mold, it is possible to prevent the occurrence of burrs on the product side. Further, since the connecting portion is cut in a sheared state by the lower die and the upper blade, the connecting portion is surely cut. Therefore, in addition to obtaining a product with excellent quality without burrs, the product can be reliably and efficiently separated from the work. In addition, it is possible to prevent damage to other products due to burrs and troubles in handling.

Further, the connecting portion cutting device (2) according to the present invention is the same as the connecting portion cutting device (1),
Each side of the polygonal lower die is concave, and the upper blade is shaped to match the concave shape of each side of the lower die.
According to the connecting portion cutting device (2), the side of the lower die of the polygon is concave, and the upper blade has a shape matching the concave shape of the side of the lower die. It is possible to prevent the vicinity of the tip of the connecting portion from remaining as a protrusion on the product side after cutting. Therefore, it is possible to reliably prevent the occurrence of protrusions that may hinder the handling of the product.

Further, the connection section cutting device (3) according to the present invention is
It is a device that separates the product connected at the connection part from the work,
A punching unit for cutting the connecting portion,
The punching unit is located on the lower surface of the work and has a circular upper part, and is located above the lower mold and rotates about the same central axis as the central axis of the lower mold. It is configured to include a vertically movable punching head equipped with a blade,
The inner side of the upper blade, the punching head is configured to be rotatable so as to be located in the upper outer peripheral portion of the lower mold,
The upper blade descends in a state where the central axis is located on the product side of the work, and the inner periphery of the upper outer peripheral portion of the lower die and the upper blade is located at the tip of the connecting portion of the work. Thus, the connection portion is configured to be disconnected.

According to the connection part cutting device (3), when the connection part of the work is cut, the circular outer periphery of the lower mold is located at the tip part of the connection part, in other words, at the boundary part between the tip part of the connection part and the product. The connection is disconnected in the positioned state. At the time of cutting, since the product side is firmly supported by the lower mold, it is possible to prevent the occurrence of burrs on the product side. Further, since the connecting portion is cut in a sheared state by the lower die and the upper blade, the connecting portion is surely cut. Therefore, in addition to obtaining a product with excellent quality without burrs, the product can be reliably and efficiently separated from the work. In addition, it is possible to prevent damage to other products due to burrs and troubles in handling.

Further, the connection cutting device (4) according to the present invention is
It is a device that separates the product connected at the connection part from the work,
A punching unit for cutting the connecting portion,
The punching unit is located on the lower surface of the work, and has a lower die having a circular upper inner peripheral portion, and is located above the lower die and rotates about the same central axis as the central axis of the lower die. Along with, it is configured to include a vertically movable punching head with an upper blade,
The outer side of the upper blade, the punching head is configured to be rotatable so as to be located in the upper circular inner peripheral portion of the lower mold,
The upper blade is in a state where the central axis is located outside the product of the work, and the outer periphery of the upper circular inner periphery of the lower die and the upper blade is located at the tip of the connecting portion of the work. It is characterized in that the connection portion is disconnected by lowering.

According to the connection part cutting device (4), when the connection part of the work is cut, the inner peripheral part of the lower die is located at the tip part of the connection part, in other words, at the boundary part between the tip part of the connection part and the product. The connection is disconnected in this state. At the time of cutting, since the product side is firmly supported by the lower mold, it is possible to prevent the occurrence of burrs on the product side. Further, since the connecting portion is cut in a sheared state by the lower die and the upper blade, the connecting portion is surely cut. Therefore, in addition to obtaining a product with excellent quality without burrs, the product can be reliably and efficiently separated from the work. In addition, it is possible to prevent damage to other products due to burrs and troubles in handling.
Furthermore, since the inner periphery of the lower die is circular, there is a large degree of freedom in the alignment of the inner periphery of the lower die with the tip of the connecting portion, and it is easy to set the angle with respect to the central axis including the alignment of the upper blade. There are advantages. Further, when the connecting portion is cut off, the concave portion, which is the inner peripheral portion of the lower mold, is positioned at the tip portion of the connecting portion. Therefore, by arranging the inner peripheral portion of the lower mold slightly on the product side from the tip of the connecting portion, there is an advantage that it is possible to prevent a protrusion, which is the remaining portion of the connecting portion, on the product side after cutting. In addition, since the inner periphery of the lower die is circular and the outer periphery can be circular, any shape can be selected, so that the lower die can be easily manufactured.

Moreover, the connection part cutting device (5) which concerns on this invention is any one of the said connection part cutting devices (1)-(4).
The work is placed, a work feeding part into which the placed work is fed, the punching unit, and a product take-out part that takes out the product from the work including the product with the connection part cut in order Is provided,
The work feeding unit includes a work support sheet on an upper surface thereof, and further includes a traveling direction alignment robot that grips one end side in the width direction of the work, and a width direction alignment robot,
The movement of the work from the work feeding portion to the product unloading portion, and the alignment of the workpiece with the connecting portion for cutting in the traveling direction are controlled by the traveling direction alignment robot,
The movement and alignment of the punching unit to the connecting portion for cutting in the width direction of the work is configured to be controlled by the width direction alignment robot.

According to the connecting/disconnecting device (5), the work feeding unit, the punching unit, and the product take-out unit for taking out the product separated from the work are sequentially provided, and the work is moved and aligned in the traveling direction, and the punching head is provided. The widthwise movement and alignment of the are controlled by the robot. Therefore, the disconnection of the connection part can be automated, and even if there are many connection parts in the work, the movement and alignment to the connection part that disconnects quickly and accurately is executed, and the work can be reliably and efficiently performed. The product can be separated.

Further, the connecting portion cutting device (6) according to the present invention is the same as the connecting portion cutting device (5),
It is characterized in that the work supporting sheet in the work feeding section is constituted by a brush table.
According to the connecting/disconnecting device (6), since the work moves on the brush table, the work can be moved smoothly and the work is not easily scratched.

Further, the connecting portion cutting device (7) according to the present invention is the above connecting portion cutting device (5) or (6),
A pickup robot is provided, the work is placed on the work feeding part by the pick-up robot, and the product separated from the work is taken out from the product take-out part by the pick-up robot. Is characterized by.
According to the connection section cutting device (7), the pickup robot performs the transfer of the work from the supply section to the work feeding section, and the transfer of the work from the product takeout section after cutting the connection section to the outside. So it can be executed quickly without human intervention. Therefore, the work efficiency can be significantly improved.

Moreover, the connection part cutting device (8) which concerns on this invention is any one of the said connection part cutting devices (5)-(7),
A work supply table on which the work is placed is arranged in the vicinity of the side of the work feeding section,
A work transfer device that holds the work on the work supply table, transfers the work to the work feeding unit, and places the work on the work feeding unit.
A product pick-up robot that is arranged near the side of the product take-out unit and takes out the product separated from the work from the product take-out unit,
It is characterized by having.

According to the connection part cutting device (8), the work on the work supply table is supplied to the work feeding part by the work transfer device, and the product separated from the work is picked up by the product pickup robot by the product picking part. Taken from. That is, the work is supplied and the product is taken out by different means, the work can be supplied and the product can be taken out in parallel, and the cutting work can be speeded up.
The product pick-up robot can be a small-sized robot with a limited function and a small turning ability. Even if one work contains products of different shapes and sizes, the picked-up product can be shaped and sized. Can be sorted separately. Therefore, it is particularly suitable when the product is a small amount and many kinds.
Further, since the supply of the work to the work feeding unit is performed by the work transfer device, it is possible to select a more suitable condition for holding and transferring the work according to the size and shape of the work. .. Therefore, the work can be transferred more reliably and quickly.

Further, the connecting portion cutting device (9) according to the present invention is the same as the connecting portion cutting device (8),
The work transfer device is
A guide frame provided across the work supply table and the work feeding section,
A work holding and moving unit that can move along the guide frame;
A work holding lifting unit fixed to the work holding moving unit,
A work holding unit that is supported by the work holding lifting unit and that can move up and down while holding the work;
It is characterized in that it is configured to include.

According to the connection part cutting device (9), the work transfer device includes the guide frame, the work holding/moving part, the work holding/lifting part, and the work frame, which are provided so as to straddle the work supply table and the work feeding part. And a work holding part. Therefore, it is possible to more reliably and quickly supply the work to the work feeding section. Further, since the single-axis robot can be used for holding movement and holding lifting of the work, in that case, the work can be supplied to the work feeding part more smoothly.

Moreover, the connection part cutting device (10) according to the present invention is any one of the connection part cutting devices (1) to (9),
The lower die and/or the upper blade are configured to be easily replaceable.
According to the connection part cutting device (10), if the lower die or the upper blade of the punching unit is worn out and cutting of the connection part of the work is likely to be hindered, these can be immediately used as consumables. The performance of the punching unit of the connection section cutting device can be easily maintained.

The punching unit (1) according to the present invention is
A lower mold with a polygonal upper part,
The inside of the upper blade is configured to include a punching head formed so as to match each side of the outer peripheral portion of the polygonal lower die. The punching unit (2) according to the present invention is
A lower mold with a circular top,
The inside of the upper blade is configured to include a punching head formed so as to abut the upper outer peripheral portion of the circular lower die.
Further, the punching unit (3) according to the present invention,
A lower mold whose inner circumference is circular,
It is characterized in that the outer side of the upper blade includes a punching head formed so as to match the upper circular inner peripheral portion of the lower die.

According to the punching units (1) to (3), each is composed of one set of lower die and punching head, and by applying these punching units to the connecting portion cutting device, the product is cut from the work. At this time, it is possible to obtain a product of good quality with no burrs on the product side. Further, it can be applied to various devices that can move the punching head up and down, and can be applied to disconnection of various work connecting parts.

A method of using the connection cutting device according to the present invention is the method of using the connection cutting device (8) or (9),
A product pallet is arranged in the vicinity of the side of the product take-out portion, and the products having a plurality of shapes separated from the work are stacked on the product pallet according to the shape, and a plurality of shapes used in a later step are collectively used. It is characterized in that the products are collectively conveyed at once by the product pallet.
According to the method of using the connection portion cutting device, a plurality of products having a plurality of shapes which are collectively used in the subsequent steps can be collectively conveyed at once by the product pallet. Therefore, one set of parts required for the subsequent assembling process can be collectively moved, and the subsequent process work can be efficiently performed.

It is a perspective view which shows an example of the workpiece|work which has the connection part which this invention makes object, (a) is the example in which the product of the same shape is formed in one workpiece, (b) is different in one workpiece. FIG. 3C is a partial enlarged view showing an example of a connection part, in which a shaped product is formed. It is a perspective view showing an example of the whole composition of the connecting part cutting device concerning an embodiment. It is a perspective view which shows an example of a structure of the principal part of the connection part cutting device which concerns on embodiment. FIG. 4 is a perspective view showing a punching unit in which the lower die is a polygonal shape in the connection portion cutting device according to the embodiment, (a) shows a punching head including an upper blade and an upper blade support portion, and (b) shows a lower die. There is. It is a perspective view which shows another punching unit whose lower die is polygonal in the connection part cutting device which concerns on embodiment, (a) is a punching head containing an upper blade and an upper blade support part, (b) is a lower die. Shows. It is a figure which shows the cutting|disconnection of the connection part of the workpiece|work by a punching head and a lower mold|die, (a) and (b) is a side view, (c) is a top view which shows the cutting position of a connection part. It is a top view which shows the relationship between the position of each connection part of a workpiece|work at the time of a connection part cutting, and the position of a lower mold, (a) is a lower mold, (b) is each connection part and the position of the side of a lower mold. Shows the relationship. FIG. 3 is a perspective view showing a punching unit having a circular lower die in the connection section cutting device according to the embodiment. It is a perspective view which shows another punching unit in the connection part cutting device which concerns on embodiment. It is a figure which shows the cutting|disconnection of the connection part of the workpiece|work by the punching head and lower die shown in FIG. 9, (a) is a top view which shows the relationship between the position of the connection part of a workpiece|work and the position of a lower mold|die at the time of disconnection of a connection part. , (B) are side views. It is a perspective view which shows an example of the whole structure of the connection part cutting device which concerns on another embodiment. It is the perspective view which looked at the work conveyance device from the work supply section side among the connection part cutting devices concerning another embodiment. It is a perspective view which shows the example of a work holding part of a pick-up robot and a product pick-up robot, (a) is a figure where a holding part is a flat type, (b) is a figure which shows an elongate type. FIG. 3 is a block diagram showing a system configuration of a control unit that controls disconnection of the connection unit by the connection unit disconnecting device according to the embodiment. It is a flow chart which shows the process of separating a product from a work by the connecting part cutting device concerning an embodiment.

Hereinafter, a connecting portion cutting device according to an embodiment of the present invention will be specifically described with reference to the drawings.
FIG. 1 is a perspective view showing an example of a work having a connecting portion to which the present invention is applied, (a) and (b) are views showing the whole work, and (a) is the same for one work. FIG. 3 is a partially enlarged view showing an example in which shaped products are formed, (b) is an example in which products of different shapes are formed on one work, and (c) is an example of a connection portion.

As shown in FIGS. 1A and 1B, the work 10 includes a plurality of products 11 in one work 10 when the size of the product 11 is small. Further, the products 11 included in one work may have the same shape as shown in FIG. 1A, or may have different shapes as shown in FIG. 1B.
As shown in FIG. 1C, each product 11 is connected to the outer peripheral portion 13 which is the outer frame of the work 10 by at least two connecting portions 12.
There is a cutout portion 14 between the product 11 and the outer peripheral portion 13 of the product 11, and the connection portion 12 is located in the cutout portion 14 and connects the product 11 and the outer peripheral portion 13. For example, when the product 11 is a quadrangle, there are usually two connection parts 12 at a diagonal position, or two at each corner, or four at each corner. It is appropriately selected according to the shape and size. The connecting portion 12 also includes a joint portion called a micro joint.

As shown in FIG. 1C, in the shape of the connecting portion 12, the width of the tip portion 12a on the product 11 side is the narrowest, and the width of the tip portion 12a is significantly narrower than the width of the outer peripheral portion side 12b. .. The width of the tip portion 12a of the connecting portion 12 is narrow, so that the product 11 can be held. That is, the product 11 can be easily separated from the work 10 at the position of the tip portion 12a of the connecting portion 12.
The work 10 targeted by the present invention is usually made of a metal plate such as iron, stainless steel, or aluminum.
The size of the work 10 varies, and when the work 10 is large, the length and width are about 1.2 m×2.4 m, and when the work 10 is small, one side is about several tens of mm. The mass may be about 20 kg.

FIG. 2 is a perspective view showing an example of the overall configuration of the connection section disconnecting device according to the embodiment. Further, FIG. 3 is a perspective view showing a configuration of a main part of the connection section cutting device according to the embodiment. In FIG. 3, the pickup robot 70 and its work holding unit 71 shown in FIG. 2 are omitted. The connection unit cutting device 1 includes a punching unit 20, a width direction alignment robot 30, a traveling direction alignment robot 40, a work feeding unit 50, a product unloading unit 60, supply of the work 10 to the work feeding unit 50, and removal of the product 11. It is configured to include a pickup robot 70 that functions as. 2 and 3 show the work 10 of the type shown in FIG. 1(a).
Further, the punching head 21 of the punching unit 20 is attached to the punching head guide 23 of the width direction alignment robot 30. The width-direction alignment robot 30 moves and aligns the punching unit 20 in the width direction.

The work 10 located in the work supply unit 51 is placed on the work feeding unit 50 by the pick-up robot 70, and after all the connecting portions 12 of the work 10 are cut by the punching unit 20, the product take-out unit 60 makes the work 11 Are picked up by the pick-up robot 70, and then the remaining portion 15 of the work 10 is discharged to the remaining work portion accommodating portion 61.
In FIG. 2, the holding unit 71 of the pickup robot 70 picks up the work 10 so that the relationship between the holding unit 71 attached to the arm tip of the pickup robot 70 and the work 10 and the product 11 is clear. The respective positions that have been moved, the positions where the products 11 have been picked up and transferred are shown as they are. In reality, the holding unit 71 moves together with the arm of the pickup robot 70. As the pickup robot 70, a general-purpose horizontal articulated robot used in many fields, as well as a 5-axis or 6-axis robot such as a vertical articulated robot or a parallel link robot can be used.

As shown in FIGS. 2 and 3, the main part of the connection/disconnection device 1 is centered on the width-direction positioning robot 30 including the punching unit 20, the work feeding part 50 is located upstream of the robot 30 and the product is taken out downstream. It is configured to include a portion 60 and a work remaining portion storage portion 61.
The work feeding unit 50 includes a fixed support base 52 and a work support sheet 53 disposed on the upper surface of the support base 52. The work 10 slides on the work support sheet 53 and includes the punching unit 20 in the width direction. It is sent to the alignment robot 30. The work supporting sheet 53 is preferably composed of, for example, a brush table. The use of the brush table has the advantages that the work 10 can be moved smoothly and that the work 10 is not easily scratched.

The movement of the workpiece 10 in the traveling direction (Y-axis direction) is controlled by the traveling direction alignment robot 40. As shown in FIG. 3, the traveling direction alignment robot 40 is provided on one end side in the width direction (X axis direction) from the work feeding unit 50 to the product unloading unit 60, and is a single-axis robot (uniaxial robot). It is equipped with a robot whose movement can be controlled. Further, the advancing direction alignment robot 40 side of the work 10 is gripped by the chuck 41 of the robot, and the work 10 is moved from the work feeding unit 50 to the product unloading unit 60 while being gripped by the robot. Meanwhile, the robot controls the cutting position of the connecting portion 12 of the work 10 in the Y-axis direction.

In the work feeding section 50, the work 10 is slid on the work supporting sheet 53 to be moved. On the other hand, the product take-out section 60 is configured by a conveyor 62 such as a belt conveyor. In the product take-out section 60, the work 10 is moved in the Y-axis direction by the robot, and the work 10 is also moved in the Y-axis direction by the conveyor 62. To move to. If there is a difference in speed and distance between the movement of the robot in the Y-axis direction and the movement of the conveyor 62, there is a possibility that the uncut connection portion 12 may be hindered from being aligned in the Y-axis direction. Therefore, it is preferable to control the movement of the conveyor 62 in synchronization with the movement of the work 10 by the robot.
After the product 11 is taken out from the product take-out section 60, the remaining portion 15 of the work 10 is discharged to the remaining work piece accommodation section 61 by the conveyor 62.

The product take-out section 60 has been described with reference to FIG. 3 as an example in which the product take-out section 60 is configured by a conveyor 62 such as a belt conveyor. For example, a sheet such as a brush table may be provided on a fixed support table like the work feeding section 50. In that case, after taking out the product 11, in order to pay out the remaining portion 15 of the work 10, a fulcrum including a rotary shaft is provided at one end side in the width direction of the support base or at the end part in the traveling direction, and the opposite side of the fulcrum is provided. Is rotated upward so that the remaining portion 15 of the work 10 is dropped to the outside of the product take-out portion 60. In this case, the support base may be moved in the traveling direction such that the entire work 10 is moved to the product take-out portion 60 after the connection portion 12 is cut.

The movement of the work 10 in the width direction (X-axis direction) is executed by the width-direction alignment robot 30. The width-direction alignment robot 30 is located between the work feeding unit 50 and the product unloading unit 60, and is a robot (not shown) such as a single-axis robot that is a means for aligning and moving the lower die 22 of the punching unit 20. And a punching head guide 23 for moving and aligning the punching head 21. For the movement and alignment of the punching head 21 in the X-axis direction, it is preferable to use a single-axis robot as in the case of the lower die 22. When a single-axis robot is used to move and align the lower die 22 and the punching head 21, the movement and alignment of both can be performed synchronously with almost no error.

4 and 5 are perspective views showing an example of a punching unit in which the lower die has a polygonal shape. FIGS. 4A and 5A are punching heads, FIGS. 4B and 5B, respectively. Indicates the lower mold. In the case of FIG. 4, the upper side 22a of the lower die 22 is linear, and in the case of FIG. 5, the upper side 22a of the lower die 22 is concave. The upper blade 21b of the punching head 21 has a shape conforming to the shape of the side 22a of the lower die 22, and when the side 22a of the lower die 22 shown in FIG. When the inside (side of the lower die 22) 21ba is flat and the side 22a of the lower die 22 shown in FIG. 5 is concave, the inside (side of the lower die 22) 21bb of the upper blade 21b is the lower die. The cross section has a convex shape in accordance with the concave shape of the side 22a of 22. The upper blade 21b is fixed to the upper blade supporting portion 21a of the punching head 21 with bolts or the like. The upper blade 21b and the lower die 22 are consumable items, and are both replaceably attached.

In the example shown in FIGS. 4 and 5, the lower die 22 has an octagonal surface facing the punching head 21, and the punching head 21 has an upper blade 21b attached to an upper blade supporting portion 21a. The center axis of the lower die 22 and the center axes of the punching head 21 and the upper blade support portion 21a are at the same position, that is, on the extension line of the lower die 22 center axis 22c, the center axes of the punching head 21 and the upper blade support portion 21a. There is a relationship that is located. Further, the upper blade 21b is attached to the upper blade supporting portion 21a of the punching head 21 so that the inner sides (cutting sides) 21ba and 21bb of the upper blade 21b are located at positions corresponding to the sides 22a of the lower die 22. There is.
Since the center axes of the punching head 21 and the lower die 22 are at the same position, each side 22a of the lower die 22 is rotated by rotating the punching head 21 at a predetermined angle, for example, 45° when the lower die 22 is an octagon. The upper blade 21b can be moved.

6A and 6B are views showing cutting of a connecting portion of a work by a punching head and a lower die, FIGS. 6A and 6B are side views, and FIG. 6C is a plan view showing a cutting position of the connecting portion. As shown in FIG. 1, the connecting portion 12 is cut at its tip 12a. At the time of cutting, the lower die 22 is arranged such that the central axis 22c side is located on the product 11 side and one side 22a of the lower die 22 is located on the tip portion 12a of the connecting portion 12. Further, the punching head 21 is rotated so that the inner side 21ba of the upper blade 21b is positioned on the side 22a of the cutting portion of the lower die 22.
In this state, the punching head 21 is lowered to disconnect the connecting portion 12. Since the connecting portion 12 is cut in such a state, the connecting portion 12 is cut and deformed downward as shown in FIG. 6B. On the other hand, since the product 11 side is supported by the lower mold 22, it is possible to prevent the occurrence of burrs on the product 11 side due to the disconnection of the connecting portion 12, and to obtain a product 11 without burrs or the like at the cutting portion. You can

When the side 22a of the lower die 22 is a straight line, misalignment occurs when the connecting portion 12 is cut, and the cutting position is closer to the base side of the connecting portion 12 than the tip portion 12a of the connecting portion 12. Then, the vicinity of the tip portion 12a of the connecting portion 12 may remain on the product 11 side and become a protrusion. On the other hand, as described with reference to FIG. 5, the side 22a of the lower mold 22 is concave and the upper blade 21b having a shape corresponding to the side 22a is combined, so that after the connection portion 12 is cut, the product 11 side. Moreover, it is possible to prevent the vicinity of the tip portion 12a of the connection portion 12 from remaining as a protrusion.

As described above, when it is necessary to ensure that the vicinity of the tip 12a of the connecting portion 12 is a protrusion on the product 11 side so that it does not remain, the side 22a of the lower mold 22 is concave and a shape corresponding to it is formed. It is preferable to use the upper blade 21b.
As for the concave shape of the side 22a of the lower mold 22, the concave portion may be square or curved.
When the side 22a of the lower mold 22 is concave, it is cut at a position closer to the product 11 than the tip 12a of the connecting portion 12, but the concave dent may be small enough to be ignored. Then, even in such a case, the connection portion 12 is cut at the tip portion 12a.

The polygon on the upper side of the lower mold 22 may be only the region where the upper blade 21b descends. The lower part may be circular or polygonal.
The upper blade 21b does not need to have a sharp cutting edge, but since it is used for cutting the connecting portion 12, it is preferably made of tool steel or the like having abrasion resistance and mechanical strength. In addition, since the side 22a of the lower die 22 is used for cutting the connecting portion 12, it is made of tool steel or the like having abrasion resistance and mechanical strength, like the upper blade 21b. Is preferred. As described above, since the upper blade 21 and the lower die 22 are consumable items, they are replaceable and easily attached.

An electric punch using a servomotor or the like is suitable for punching for lowering the punching head 21 and cutting the connecting portion 12. A crank type, a hydraulic type or the like can be used, but an electric punch is most preferable from the viewpoint of punching performance, control, device configuration and the like.

FIG. 7 is a plan view showing the relationship between the position of each connection part of the work and the position of the lower mold when the connection part is disconnected. In the example shown in FIG. 7, the lower mold 22 is an octagon having sides A to H. Further, the work 10 is provided with ten connection portions a to n. The relationship between the connecting parts IN and the sides A to H of the lower mold 22 used for cutting is as shown in FIG. 6, and the connecting parts IN and the sides are as shown in FIG. Specific combinations with A to H are as follows.
I-H, R-A, H-B, N-B, H-D, H-D, To-E, J-F, Li-F, N-H.
The center axis 22c of the lower die 22 can be located on the side of the product 11 by combining the respective connecting portions IN and the sides A to H of the lower die 22 as described above. Therefore, in any of the connecting portions 12, the connecting portion 12 can be disconnected without causing burrs or the like on the product 11 side.

4 to 7 show examples of the lower mold 22 having an octagon, the shape of the lower mold 22 may be a polygon other than the octagon. However, in the case of a triangle, the connection part 12 may be cut between the corner (apex) of the lower die 22 and the upper blade 21b, so even if the position is small, the product 11 side Burrs easily occur. Therefore, it is preferably a polygon having a quadrangle or more, or a pentagon or more.
The polygonal portion of the lower die 22 is an upper portion of the lower die 22, that is, an area including a position where the upper blade 21b descends when the connecting portion 12 of the work 10 is cut, and all of the outer peripheral side of the lower die 22. The parts need not be polygonal.

Although an example in which the upper side of the lower mold has a polygonal shape has been described with reference to FIGS. 4 to 7, the upper part of the lower mold is not limited to the polygonal shape.
FIG. 8 is a perspective view showing a punching unit having a circular lower die in the connection section cutting device according to the embodiment. The punching unit 20 shown in FIG. 8 includes an upper outer peripheral portion 22ab including a circular lower die 22 and an upper blade 21b fixed to an upper blade supporting portion 21a. The inner side 21ba of the upper blade 21b whose upper outer peripheral portion 22ab corresponds to the circular lower die 22 may have a flat plate shape or a concave shape larger than the radius of curvature of the circular lower die 22.
When the upper outer peripheral portion 22ab of the lower die 22 is circular, the positioning of the lower die 22 and the upper blade 21b with respect to the tip portion 12a of the connecting portion 12 is the same as that described with reference to FIGS. 4 to 7, The only difference is that when the outer peripheral portion is polygonal, it is the side 22a, and when the outer peripheral portion is circular, it is the arc-shaped upper outer peripheral portion 22ab.

FIG. 9 is a perspective view showing another punching unit in the connection section cutting device according to the embodiment. FIG. 10 is a diagram showing the cutting of the work connecting portion by the punching head and the lower die shown in FIG. 9, and FIG. 10A shows the position of the work connecting portion and the lower die position when the connecting portion is cut. Is a plan view showing the relationship of FIG. The lower die and the work portion shown in FIG. 10B show a cross section taken along the line A-A′ shown in FIG.

In the case of the punching unit 20 described with reference to FIGS. 4 to 8, the outer side 22a of the lower die 22 and the upper outer peripheral portion 22ab of the lower die 22 are located at the tip portion 12a of the connecting portion 12 and the connecting portion 12a. The tip portion 12a of 12 is cut. On the other hand, in the case of the punching unit 25, as shown in FIG. 9 and FIG. Therefore, as shown in FIGS. 9 and 10(b), in the punching head 26 corresponding to the lower die 27, the upper blade 26b is attached to the outer lower portion of the upper blade support portion 26a and the outer side of the upper blade 26b. 26ba is the position corresponding to the upper circular inner peripheral portion 27a of the lower mold 27.
As described above, in the case of the punching unit 20, the connection portion 12 is cut using the side 22a on the outer peripheral side of the lower die 22 or the upper outer peripheral portion 22ab, while in the case of the punching unit 25, The difference is that the connecting portion 12 is cut using the upper circular inner peripheral portion 27a of the lower die 27.
Therefore, in the punching head 26, the outer side 26ba of the upper blade 26b corresponds to the upper circular inner peripheral portion 27a of the lower die 27 as described above.

Regarding the upper blade 26b of the punching head 26, the outer side 26ba of the upper blade 26b has a convex cross-section, and the convex mold has a radius of curvature corresponding to the lower die 27, in accordance with the shape of the upper circular inner peripheral portion 27a of the lower die 27. It is preferable that it is smaller than the radius of curvature of the upper circular inner peripheral portion 27a. The upper blade 26b is fixed to the upper blade support portion 26a of the punching head 26 with a bolt or the like. The upper blade 26b and the lower die 27 are consumable items and are both replaceably attached.

As shown in FIG. 10A, when the connecting portion 12 is cut by the punching unit 25, the upper circular inner peripheral portion 27 a of the lower die 27 is positioned at the tip 12 a of the connecting portion 12. Therefore, as shown in FIGS. 10A and 10B, the central shaft 27c of the lower die 27 is located on the outer peripheral portion 13 side of the work 10. Further, the central axis 26c of the upper blade support portion 26a is also positioned on the extension line of the central axis 27c of the lower die 27 on the outer peripheral portion 13 side of the work 10.

Thus, the center axis 27c of the lower die 27 and the center axis 26c of the punching head 26 and the upper blade support portion 26a are at the same position, that is, on the extension line of the lower die 27 center axis 27c. The central axis 26c of 26a is located. Further, the upper blade 26b is attached to the upper blade supporting portion 26a of the punching head 26 so that the outer side (cutting side) 26ba of the upper blade 26b is located at a position corresponding to the upper circular inner peripheral portion 27a of the lower die 27. Has been. The position of the outer side 26ba of the upper blade 26b is a position that does not contact the upper circular inner peripheral portion 27a of the lower mold 27 when the connecting portion 12 is cut.

Since the punching head 26 and the lower die 27 have the same central axis, the punching head 26 is rotated to move the upper blade 26b to a predetermined position above the upper circular inner peripheral portion 27a of the lower die 27. You can
By lowering the punching head 26 in the state shown in FIG. 10B, the tip portion 12a of the connecting portion 12 can be cut.

In the case of the punching unit 25, when the connecting portion 12 is cut, a concave portion which is the upper circular inner peripheral portion 27a of the lower die 27 is positioned at the tip portion 12a of the connecting portion 12. Therefore, it is possible to position the upper circular inner peripheral portion 27a of the lower die 27 slightly on the product 11 side from the tip portion 12a of the connecting portion 12, and in that case, after cutting, the connecting portion 12 of the connecting portion 12 on the product 11 side is cut. There is an advantage that it is possible to prevent the formation of the remaining projections.
Further, in the case of the punching unit 25, since the portion used for cutting the lower die 27 is a circular inner peripheral portion, unlike the case where the lower die has a polygonal shape, the lower die 27 is aligned during cutting. , And the position of the upper blade 26b corresponding to the cutting position of the lower die 27 is easy.

9 and 10 show examples of the lower mold 27 having a cylindrical shape having a circular outer side, but the outer shape may be other shapes such as a square shape. Also, the upper blade support portion 26a may have a cross section other than a circular shape.
The upper blade supporting portion 21a of the punching unit 20 shown in FIGS. 4 and 5 does not necessarily have to have the same polygonal shape as the lower die 22. It suffices that the center axis 21c of the upper blade support portion 21a is at the same position as the center axis 22c of the lower die 22 and the inner side 21ba of the upper blade 21b corresponds to the side 22a of the lower die 22.

As described above, the punching units 20 and 25 are the parts that play the most important role in the connection section cutting device 1 according to the embodiment.
That is, for the punching unit 20 having a polygonal lower die 22 for cutting the connecting portion 12, the lower die 22 is located on the lower surface of the work 10, and the upper portion thereof is located above the lower die 22 having a polygonal shape. The polygonal lower die 22 is configured to include a punching head 21 that rotates around a central axis 21c that is the same as the central axis 22c of the polygonal lower die 22 and that is provided with an upper blade 21b and can move up and down. The punching head 21 is rotatable so as to be positioned on each side 22a of the outer peripheral portion of 22, and the central axes 21c and 22c are positioned on the product 11 side of the work 10, and the sides 22a of the lower die 22 and the upper blade 21b are positioned. With the inner side 21ba positioned at the tip 12a of the connecting portion 12 of the work 10, the connecting portion 12 is cut by lowering the upper blade 21b.
In the punching unit 20 for a connecting portion cutting device used in the connecting portion cutting device 1, each side of the lower die 22 having an upper polygonal shape, and the inside of the upper blade 21b is an outer peripheral portion of the lower die 22 having a polygonal shape. 22a, and a punching head 21 formed so as to match 22a.

Regarding the punching unit 20 in which the lower die 22 that cuts the connecting portion 12 is circular, the lower die 22 is located on the lower surface of the work 10 and has an upper circular portion, and the lower die 22 is located above the lower die 22. It is configured to include a punching head 21 that rotates about a central axis 21c that is the same as the central axis 22c of 22 and that is provided with an upper blade 21b and is vertically movable. The inside of the upper blade 21b is the upper outer peripheral portion of the lower die 22. The punching head 21 is rotatable so as to be located at 22 ab, the central axes 21 c and 22 c are located on the product 11 side of the work 10, and the upper outer peripheral portion 22 ab of the lower die 22 and the inner side 21 ba of the upper blade 21 b are the work 10. The upper blade 21b is moved downward while being positioned at the tip 12a of the connecting portion 12, so that the connecting portion 12 is disconnected.
In the punching unit 20 for the connecting portion cutting device used in the connecting portion cutting device 1, the lower die 22 having a circular upper portion and the inner side of the upper blade 21b come into contact with the upper outer peripheral portion 22ab of the circular lower die 22. The punching head 21 formed in the above is included.

The punching unit 25 for cutting the connecting portion 12 is located on the lower surface of the workpiece 10 and has a circular lower die 27 at the upper inner periphery thereof, and is located above the lower die 27, and is located at the center of the lower die 27. It is configured to include a punching head 26 that rotates about the same central axis 26c as the shaft 27c and that is provided with an upper blade 26b, and is capable of moving up and down, and the outer side 26ba of the upper blade 26b is the upper circular inner circumference of the lower die 27. The punching head 26 is rotatably arranged so as to be located at the portion 27a, the central axes 26c and 27c are located outside the product 11 of the work 10, and the outside of the upper circular inner peripheral portion 27a of the lower die 27 and the upper blade 26b. The connecting portion 12 is cut by lowering the upper blade 26b in a state in which 26ba is located at the tip portion 12a of the connecting portion 12 of the work 10.
In the punching unit 25 for the connecting portion cutting device used in the connecting portion cutting device 1, a lower die 27 having a circular upper inner peripheral portion and an outer side 26ba of the upper blade 26b have an upper circular inner peripheral portion of the lower die 27. The punching head 26 is formed so as to conform to 27a.

As described above, in the connecting portion cutting device 1 according to the embodiment, the workpiece 10 is placed, the workpiece feeding portion 50 into which the placed workpiece 10 is fed, the punching units 20, 25, and the connecting portion 12 are provided. A product take-out section 60 for taking out the product 11 from the work 10 including the cut product 11 is sequentially provided, the work feeding section 50 is fixed, and a work supporting sheet 53 is provided on the upper surface. The advancing direction alignment robot 40 is provided with the advancing direction alignment robot 40 for moving the workpiece 10 from the work feeding part 50 to the product taking-out part 60 and for aligning the work 10 with the connecting part 12 to be cut in the advancing direction. The width-direction alignment robot 30 controls the movement and alignment of the punching units 20 and 25 to the connecting portion 12 to be cut in the width direction of the work 10, which is controlled by the width-direction alignment robot 30.

FIG. 11: is a perspective view which shows an example of the whole structure of the connection part cutting device which concerns on another embodiment. Further, FIG. 12 is a perspective view of the work transfer device in the connection cutting device according to another embodiment shown in FIG. 11, as viewed from the work supply unit side.
The connection cutting device 2 according to another embodiment differs from the connection cutting device 1 described with reference to FIGS. 2 to 3 in the following points. The connection section cutting device 1 includes a pick-up robot 70 that transfers the work 10 from the work supply section 51 to the work feeding section 50 and takes out the product 11 separated from the work 10 from the product taking-out section 60. That is, the pick-up robot 70 is configured to supply the work 10 to the work feeding section 50 and take out the product 11 separated from the product taking-out section 60.

On the other hand, in the case of the connection section cutting device 2, a work transfer device 55 for transferring the work 10 from the work supply unit 51 to the work feeding unit 50 is provided instead of the pickup robot 70, and from the work 10. The difference lies in that a product pick-up robot 75 that functions to take out the separated product 11 from the product take-out unit 60 is provided near the side of the product take-out unit 60. The punching units 20, 25, the width direction alignment robot 30, the advancing direction alignment robot 40, the work feeding unit 50, the product unloading unit 60, and the like are the same as those in the connection unit cutting device 1.
11 and 12, the work 10 of the type shown in FIG. 1B is shown.

As shown in FIG. 11, in the case of the connection cutting device 2, the work 10 on the work supply table 51 a arranged near the side of the work feeding unit 50 is transferred to the work feeding unit 50 by the work conveying device 55. The product 11 supplied and separated from the work 10 is taken out from the product take-out unit 60 by the product pickup robot 75. As in the case of the connection section disconnecting device 1, one pickup robot 70 does not transfer the work 10 to the work feeding section 50 and take out the product 11 from the product takeout section 60, but connect it. In the case of the partial cutting device 2, there is a big difference in that the supply of the work 10 and the removal of the product 11 are divided into different means.

As shown in FIGS. 11 and 12, the work transfer device 55 supports the work supply table 51 a, which is the work supply unit 51, and the guide frame 56 provided across the work feeding unit 50, and the work holding unit 72. In addition, the work holding lifting unit 57 includes a work holding lifting unit 57 that can move up and down and a work holding moving unit 58 that can move along the guide frame 56. The work holding lifting unit 57 is fixed to the work holding moving unit 58. Further, a lateral movement unit 59 is provided on the guide frame 56, and the work holding movement unit 58 can reciprocate between the work supply table 51a and the work feeding unit 50 by the lateral movement unit 59. Is becoming

As described above, in the connecting/disconnecting device 2, the work supply table 51a on which the work 10 is placed is arranged in the vicinity of the side of the work feeding unit 50, holds the work 10 on the work feeding table 51a, and feeds the work. A work transfer device 55 that transfers and places the work 50 on the unit 50, and a product pick-up robot 75 that is arranged near the side of the product take-out unit 60 and takes out the product 11 separated from the work 10 from the product take-out unit 60. ..

By the work transfer device 55, the work 10 held by the work holding unit 72 is moved by the movement of the lateral movement unit 59 supported by the guide rail 56 via the work holding lifting unit 57 and the work holding moving unit 58. , From the work supply table 51a to the work feeding section 50.
The work elevating/lowering unit 57 is preferably configured by a single-axis robot. Besides, a combination of an air cylinder, a servo motor and a ball screw can be used. Further, the lateral moving unit 59 is also preferably configured by a single-axis robot, but may be configured by using an air cylinder, a motor-driven chain, or a belt.

Although not shown, the work holding part 72 is provided with a suction pad on the lower side. The work supply table 51a holds the work 10 by the suction pad, and the work feeding part 50 allows the work 10 to be released. You can do it.
The work holding unit 72 and the work holding unit 76 used for the product pickup robot 75 will be described later with reference to FIG.

The product pick-up robot 75 that takes out the product 11 separated from the work 10 from the product take-out unit 60 is a general-purpose horizontal articulated robot as well as a vertical articulated robot similar to the pick-up robot 70 used in the connection section cutting device 1. , A parallel link robot, etc. can be used. However, the product pick-up robot 75 is used only for transferring the product 11 from the product take-out section 60 to the product pallet 63 shown in FIG. Therefore, it is not necessary to pick up the workpiece 10 having a large mass, unlike the pickup robot 70 of the connection section cutting device 1. Since the product 11 is separated from the work 10, the mass of the product 11 to be picked up is small. In addition, the movement range of the robot arm is narrow. Therefore, as the product pickup robot 75, a robot that is smaller and simpler than the picking robot 70 used in the connection section cutting device 1 can be adopted.

As described above, in the case of the connection section disconnecting device 2, the product pickup robot 75 is used only to take out the product 11 from the product takeout section 60. Further, the product pickup robot 75 can be operated in parallel with the transfer operation of the work 10 to the work feeding section 50 by the work transfer device 55. Therefore, it is convenient not only to take out the product 10 from the product take-out section 60 but also to transfer the product 11 in consideration of the subsequent steps. For example, as shown in FIG. 11, when there are one product 11a, two products 11a, two products 11b, and 11c having different shapes as one product 10, one product pallet 63 is provided. The products 11 can be stacked in an aligned state, such as one set of the products 11a, two sets of the products 11b, and two sets of the products 11c.

That is, when the connecting section 12 is cut using the connecting section cutting device 2, the product pallet 63 is placed near the side of the product take-out section 60 and the product 11 separated from the work 10 is predetermined. It is possible to adopt a method in which the products are stacked on the product pallet 63 according to each shape and a plurality of products 11 having a plurality of shapes to be used in the subsequent steps are collectively conveyed by the product pallet 63.
In the case where the products 11a to 11c are one set of parts required for assembly and processing in the subsequent process, by moving one product pallet 63 to the subsequent process, the next product can be quickly and efficiently You can do the work.

As described above, in the case of the connection cutting device 2, the supply of the work 10 to the work feeding unit 50 and the removal of the product 11 separated from the product removal unit 60 are performed by different means. There is an advantage that the work of the feeding unit 50 and the work of the product take-out unit 60 can be performed in parallel. Therefore, in the product take-out section 60, it is possible to sort the products 11 having a plurality of shapes into one product pallet 63. Therefore, it is extremely suitable as a connecting portion disconnecting device, particularly when a large number of small lots of finished products are obtained.

FIG. 13 is a perspective view showing an example of a work holding unit used for the pickup robot of the connection section disconnecting device and the product pickup robot. FIG. 13A is the work holding unit 71 shown in FIG. 2 and FIGS. The type corresponding to the work holding section 72 shown in the figure, and (b) is the type corresponding to the work holding section 76 shown in FIG.
The work holding part 71 at the arm tip of the pickup robot 70 and the work holding part 72 of the work transfer device 55 are of a flat plate type in which suction pads 71b are arranged vertically and horizontally, and an example thereof is shown in FIG. Is shown in. In the following description, the work holding parts 71 and 72 are collectively referred to as the work holding part 71. On the other hand, the work holding unit 76 provided at the tip of the arm of the product pickup robot 75 is an elongated type in which the suction pads 76b are arranged in a line, and an example thereof is shown in FIG. 13(b).

The work 10 and the product 11 are adsorbed and held by the work holding portions 71 and 76, and are transferred. The work holding portions 71 and 76 shown in FIG. 13 are of a type that uses a vacuum suction pad, and include boxes 71a and 76a and a plurality of suction pads 71b and 76b attached to the lower surfaces of the boxes 71a and 76a. .. In the case of the work holding unit 71, since the box 71a is divided into three, a connection pipe 71c for sucking and exhausting each box 71a is provided. In addition, a connection part (not shown) for vacuum suction and exhaust is provided on the upper surface or the side surface of the connection pipe 71c and the box 76a, and is connected to a vacuum pump, an ejector or the like via the hose. As a result, intake and exhaust of the inside of the boxes 71a and 76a can be performed.

It is preferable that the suction pads 71b and 76b are arranged in accordance with the position of the product 11 on the work 10. Therefore, it is preferable that the work holding portions 71 and 76 are used by appropriately selecting the work holding portions 71 and 76 in consideration of the shapes of the work 10 and the product 11, the position of the product 11 in the work 10. ..
The suction pads 71b and 76b have a cylindrical tail portion, and can be easily attached to and detached from the suction pad mounting holes of the boxes 71a and 76a. Therefore, it can be appropriately replaced depending on the size of the work 10, the number, size and shape of the products 11, damage to the suction pads 71b and 76b, and the like. Further, it is preferable that the work holding portions 71 and 76 are appropriately replaced and used according to the size and the number of the works 10 and the products 11 and a type that easily holds the works 10 and the products 11.

The suction pads 71b, 76b are preferably at least one-stage bellows type and made of nitrile rubber, silicone rubber, natural rubber or the like so that the product 11 can be held and released quickly and surely. As the suction pads 71b and 76b, commercially available general-purpose suction pads can be used.

FIG. 13B shows an example in which the work holding portion 76 is elongated and three suction pads 76b are provided in a row so that the products 11 can be individually picked up. For example, since the product 11 is small, the suction pad 76b may be located outside the product 11 among the three suction pads 76b. Even in such a case, in the case of vacuum suction, by providing a ball such as a steel ball in the suction pad 76b, the ball can block the suction port at the time of suction, so that the suction of air can be prevented. It is possible to prevent and stop the suction action by the suction pad 76b on the portion outside the product 11.

Although the case of the vacuum suction method has been described for the holding units 71 and 76 with reference to FIG. 13, a method other than the vacuum suction can be applied to the holding units 71 and 76. For example, when the work 10 is a magnetic material such as a steel plate, an electromagnet can be used. In that case, an electromagnet is attached instead of the suction pads 71b and 76b. When the work 10 and the product 11 are held, the work 10 and the product 11 are held and transported by using a method of attracting the work 10 by energizing the electromagnet and releasing the work by releasing the energization. ..

FIG. 14 is a block diagram showing a system configuration of a control unit that controls disconnection of the connection unit by the connection unit disconnection device according to the embodiment.
The control system 80 is used to disconnect the connecting portion 12 of the work 10 and includes an input portion 81, a control portion 82, and an output portion 83. NC data used for punching the work 10 is input to the input unit 81 and used. The NC data is data used when the work 10 is processed by punching using a turret punch press or the like, and the cutting position of the connecting portion 12 can be determined by using the data.

If there is no data regarding the position of the connecting portion 12, the disconnection position of the connecting portion 12 may be determined based on the captured image.
Using a program for determining the position of the connecting portion 12 of the work 10 based on the NC data, the cutting position coordinates (X, Y) of each connecting portion 12 of the work 10 and each connecting portion 12 based on the cutting position The cutting order and the like are required. In addition to NC data, punching data such as the number of workpieces 10 for cutting the connecting portion 12 and the cutting force are input to the input unit 81.

The data of the input unit 81 is sent to the X-axis movement control unit, the Y-axis movement control unit, and the punching unit control unit of the corresponding control unit 82. A control signal generated by the control unit 82 is output to the output unit 83, and based on the respective signals, movement and alignment of the work 10 by the X-axis direction alignment robot (width direction alignment robot 30), Y-axis direction. The movement and alignment of the work 10 by the alignment robot (the traveling direction alignment robot 40) and the cutting operation of the punching units 20 and 25 are controlled.

FIG. 15 is a flowchart showing an example of a step of separating a product from a work by the connection section cutting device according to the embodiment. FIG. 15 is an example for the connection section cutting device 1 described with reference to FIGS. 2 to 7 and the connection section cutting device 2 described with reference to FIGS. 11 and 12, and is shown in FIG. It is controlled by the control system 80. The following steps will be described for the punching unit 20.
In step 1, data such as NC data regarding the work 10 is acquired.
In step 2, the cutting position coordinates (Xn, Yn), which is the cutting position data, is acquired for each connecting portion 12 of the work 10 based on the acquired data.
In step 3, the central axis coordinates (Xn', Yn') of the lower die 22 and punching head 21 corresponding to the cutting position coordinates (Xn, Yn) of each connecting portion 12 are calculated and determined.
In step 4, the disconnection order of each connecting portion 12 is determined.
The above steps 1 to 4 are executed by the input unit 81 of the control system 80 shown in FIG.

In step 5, the work 10 is picked up by the work supply unit 51 by the pick-up robot 70 shown in FIG. 2 or the work transfer device 55 shown in FIGS. 11 and 12, and is transferred to the work feeding unit 50.
In step 6, the advancing direction alignment robot 40 shown in FIG. 3 moves the work 10 to Yn′ of the center axis coordinates of the lower die 22 and the punching head 21 corresponding to the cutting position of the connecting portion 12, and moves in the Y axis direction. Align the.
In step 7, the width-direction alignment robot 30 shown in FIG. 3 moves the work 10 to Xn′ of the central axis coordinates of the lower die 22 and punching head 21 corresponding to the cutting position of the connecting portion 12, and moves in the X-axis direction. Align the.
In step 8, the upper blade 21b of the punching head 21 is rotated to align the upper blade 21b with the cutting position (Xn, Yn).
In step 9, the punching head 21, that is, the upper blade 21b is lowered to cut the connecting portion 12.

In step 10, it is determined whether or not all the connection parts 12 in the work 10 have been disconnected. If it is determined that the work has not been completed, the process returns to step 6 and the disconnection of the connecting portion 12 of the same work 10 is repeated. When it is determined that the disconnection of all the connection parts 12 in the work 10 is completed, the process proceeds to step 11.
In step 11, the entire work 10 is moved to the product take-out section 60 shown in FIGS. 2, 3, and 11.

In step 12, the product 11 is picked up from the product take-out section 60 by the pick-up robot 70 shown in FIG. 2 or the product pick-up robot 75 shown in FIG.
In step 13, the remaining portion 15 of the work 12 from which the product 11 has been removed from the work 10 is discharged as scrap.
In step 14, it is judged whether or not the disconnection of the connecting parts 12 of all the works 10 is completed. If it is judged that the disconnecting of the connecting parts 12 of all the works 10 is not completed, the process returns to step 5 to disconnect the connecting parts 12 of the next work 10. I do. When it is determined that the disconnection of the connecting portions 12 of all the works 10 is completed, the work is ended.

Although the embodiments of the present invention have been described in detail above, the above description is merely an example of the present invention. It goes without saying that various improvements and changes can be made without departing from the scope of the present invention and these are also included in the scope of the present invention.

1, 2 Connection part cutting device 10 Work piece 11, 11a, 11b, 11c Product 12 Connection part 12a Tip part 12b Outer peripheral side 13 Outer peripheral part 14 Cutout part 15 Remaining part 20, 25 Punching unit 21, 26 Punching head 21a, 26a Upper blade Support portions 21b, 26b Upper blades 21ba, 21bb Inner sides 21c, 22c, 26c, 27c of the upper blades Center shafts 22, 27 Lower mold 22a Sides 22ab Upper outer peripheral portion 23 Punching head guide 26ba Outer blades 27a Upper circular inner peripheral portion 30 Width direction alignment robot 40 Advance direction alignment robot 41 Chuck 50 Work feed part 51 Work supply part 51a Work supply table 52 Support table 53 Work support sheet 55 Work transfer device 56 Guide frame 57 Work holding/lifting part 58 Work holding/moving part 59 Lateral movement part 60 Product take-out part 61 Work rest part storage part 62 Conveyor 63 Product pallet 70 Pickup robots 71, 72, 76 Workpiece holding parts 71a, 76a Boxes 71b, 76b Suction pad 71c Connection pipe 75 Product pickup robot 80 Control system 81 Input unit 82 Control unit 83 Output unit

Claims (14)

It is a device that separates the product connected at the connection part from the work,
A punching unit for cutting the connecting portion,
The punching unit is located on the lower surface of the work and has a polygonal lower die and an upper portion thereof located above the lower die and rotates about the same central axis as the central axis of the lower die. , Including a vertically movable punching head having an upper blade,
The inner side of the upper blade, the punching head is configured to be rotatable so as to be located on each side of the outer peripheral portion of the lower mold,
The central axis is located on the product side of the work, the sides of the lower die and the inner side of the upper blade are located at the tip of the connecting portion of the work, and the upper blade is lowered. A connecting portion disconnecting device, wherein the connecting portion is configured to be disconnected. 2. The connection part cutting according to claim 1, wherein each side of the polygonal lower die is concave, and the upper blade has a shape that matches the concave shape of each side of the lower die. apparatus. It is a device that separates the product connected at the connection part from the work,
A punching unit for cutting the connecting portion,
The punching unit is located on the lower surface of the work and has a circular upper part, and is located above the lower mold and rotates about the same central axis as the central axis of the lower mold. It is configured to include a vertically movable punching head equipped with a blade,
The inner side of the upper blade, the punching head is configured to be rotatable so as to be located in the upper outer peripheral portion of the lower mold,
The upper blade descends in a state where the central axis is located on the product side of the work, and the inner periphery of the upper outer peripheral portion of the lower die and the upper blade is located at the tip of the connecting portion of the work. Accordingly, the connection section cutting device is configured to cut the connection section. It is a device that separates the product connected at the connection part from the work,
A punching unit for cutting the connecting portion,
The punching unit is located on the lower surface of the work, and has a lower die having a circular upper inner peripheral portion, and is located above the lower die and rotates about the same central axis as the central axis of the lower die. Along with, it is configured to include a vertically movable punching head with an upper blade,
The outer side of the upper blade, the punching head is configured to be rotatable so as to be located in the upper circular inner peripheral portion of the lower mold,
The upper blade is in a state where the central axis is located outside the product of the work, and the outer periphery of the upper circular inner periphery of the lower die and the upper blade is located at the tip of the connecting portion of the work. The connecting portion disconnecting device is characterized in that the connecting portion is disconnected by lowering. The work is placed, a work feeding part into which the placed work is fed, the punching unit, and a product take-out part that takes out the product from the work including the product with the connection part cut in order Is provided,
The work feeding unit includes a work support sheet on an upper surface thereof, and further includes a traveling direction alignment robot that grips one end side in the width direction of the work, and a width direction alignment robot,
The movement of the work from the work feeding portion to the product unloading portion, and the alignment of the workpiece with the connecting portion for cutting in the traveling direction are controlled by the traveling direction alignment robot,
The movement and the alignment of the punching unit to the connection portion for cutting in the width direction of the work are configured to be controlled by the width direction alignment robot. The connection cutting device according to any one of the above items. The connection portion cutting device according to claim 5, wherein the work supporting sheet in the work feeding portion is configured by a brush table. A pickup robot is provided, the work is placed on the work feeding part by the pick-up robot, and the product separated from the work is taken out from the product take-out part by the pick-up robot. The connection section disconnecting device according to claim 5 or 6, characterized in that. A work supply table on which the work is placed is arranged in the vicinity of the side of the work feeding section,
A work transfer device that holds the work on the work supply table, transfers the work to the work feeding unit, and places the work on the work feeding unit.
A product pick-up robot that is arranged near the side of the product take-out unit and takes out the product separated from the work from the product take-out unit,
The connection part cutting device according to claim 5, further comprising: The work transfer device is
A guide frame provided across the work supply table and the work feeding section,
A work holding and moving unit that can move along the guide frame;
A work holding lifting unit fixed to the work holding moving unit,
A work holding unit that is supported by the work holding lifting unit and that can move up and down while holding the work;
9. The connection portion cutting device according to claim 8, wherein the connection portion cutting device is configured to include. The connection cutting device according to any one of claims 1 to 9, wherein the lower die and/or the upper blade is configured to be easily replaceable. A lower mold with a polygonal upper part,
A punching unit for a connecting portion cutting device, wherein an inner side of the upper blade includes a punching head formed so as to match each side of an outer peripheral portion of the polygonal lower die. A lower mold with a circular top,
A punching unit for a connecting portion cutting device, wherein an inner side of the upper blade includes a punching head formed so as to abut on an upper outer peripheral portion of the circular lower die. A lower mold whose inner circumference is circular,
A punching unit for a connecting portion cutting device, wherein an outer side of the upper blade includes a punching head formed so as to match the upper circular inner peripheral portion of the lower die. A method of using the connection cutting device according to claim 8 or 9,
A product pallet is arranged in the vicinity of the side of the product take-out portion, and the products having a plurality of shapes separated from the work are stacked on the product pallet according to the shape, and a plurality of shapes used in a later step are collectively used. A method of using a connecting portion cutting device, characterized in that products are conveyed all at once by the product pallet.

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