JP7010980B2 - Cutting / bending method - Google Patents

Description

The present invention relates to a cutting / bending method for cutting / bending a lead when the lead component is mounted on a substrate.

When the lead component is mounted on the substrate, the lead is inserted into the through hole formed in the substrate and the lead is cut and bent as described in the following patent document.

Japanese Unexamined Patent Publication No. 4-320400

According to the technique described in the above patent document, it is possible to appropriately mount the lead component on the substrate to some extent. However, by appropriately cutting the lead, or by appropriately cutting and bending the lead, it becomes possible to more appropriately mount the lead component on the substrate. The present invention has been made in view of such circumstances, and an object of the present invention is to appropriately mount lead components on a substrate.

In order to solve the above problems, the cutting / bending method described in the present invention includes a pair of main bodies, a holding portion that holds the pair of main bodies so as to be able to approach and separate in the horizontal direction, and the holding portion. After cutting a pair of leads of the first lead component by using one unit provided with a rotation mechanism for rotating the pair of leads, the main body is aligned with the pair of leads along the main body. After rotating the portion by the rotation mechanism to perform N-bending that bends the pair of leads in a direction to separate them, and cutting a pair of leads of a lead component different from the first lead component , the above-mentioned Reverse N bending is performed by rotating the main body portion in the direction opposite to the rotation by the rotation mechanism while aligning the pair of leads along the main body portion of the pair, thereby bending the pair of leads in a direction to separate them. It is characterized by doing.

In the cutting / bending method described in the present invention, N-bending that bends a pair of leads in a direction to separate them can be performed, and lead components can be appropriately mounted on a substrate.

It is a perspective view which shows the component mounting machine. It is a perspective view which shows the component mounting apparatus. It is a perspective view which shows the cut and clinch apparatus. It is a perspective view which shows the cut and clinch unit. It is sectional drawing which shows the slide body. It is an enlarged view which shows the slide body. It is a block diagram which shows the control device. It is sectional drawing which shows the cut-and-clinch unit just before the lead of a lead part is cut. It is sectional drawing which shows the cut-and-clinch unit after the lead of a lead part is cut. It is a schematic diagram which shows the lead bent in the inwardly bent state. It is sectional drawing which shows the cut-and-clinch unit after the lead of a lead part is cut. It is a schematic diagram which shows the lead bent in the outward bending state. It is sectional drawing which shows the cut-and-clinch unit after the lead of a lead part is curved. It is sectional drawing which shows the cut-and-clinch unit after the lead of a lead part is cut. It is a top view which shows the slide body from the viewpoint from above. It is a schematic diagram which shows the lead bent in the N bending state. It is sectional drawing which shows the cut-and-clinch unit after the lead of a lead part is curved. It is sectional drawing which shows the cut-and-clinch unit after the lead of a lead part is cut. It is a schematic diagram which shows the lead bent in the N bending state.

Hereinafter, examples of the present invention will be described in detail as embodiments for carrying out the present invention with reference to the drawings.

<Configuration of component mounting machine>
FIG. 1 shows a component mounting machine 10. The component mounting machine 10 is a device for executing component mounting work on the circuit base material 12. The component mounting machine 10 includes an apparatus main body 20, a base material transfer holding device 22, a component mounting device 24, a mark camera 26, a parts camera 28, a component supply device 30, a loose component supply device 32, and a cut and clinch device (see FIG. 3). 34, a control device (see FIG. 7) 36 is provided. Examples of the circuit board 12 include a circuit board, a base material having a three-dimensional structure, and the like, and examples of the circuit board include a printed wiring board and a printed circuit board.

The apparatus main body 20 is composed of a frame portion 40 and a beam portion 42 mounted on the frame portion 40. The base material transfer holding device 22 is arranged in the center of the frame portion 40 in the front-rear direction, and has a transfer device 50 and a clamp device 52. The transport device 50 is a device for transporting the circuit base material 12, and the clamp device 52 is a device for holding the circuit base material 12. As a result, the base material transfer holding device 22 conveys the circuit base material 12 and holds the circuit base material 12 fixedly at a predetermined position. In the following description, the transport direction of the circuit base material 12 is referred to as the X direction, the horizontal direction perpendicular to the direction is referred to as the Y direction, and the vertical direction is referred to as the Z direction. That is, the width direction of the component mounting machine 10 is the X direction, and the front-rear direction is the Y direction.

The component mounting device 24 is arranged in the beam portion 42, and has two work heads 60 and 62 and a work head moving device 64. As shown in FIG. 2, a suction nozzle 66 is provided on the lower end surfaces of the work heads 60 and 62, and the suction nozzle 66 sucks and holds the component. Further, the work head moving device 64 has an X-direction moving device 68, a Y-direction moving device 70, and a Z-direction moving device 72. Then, the two work heads 60 and 62 are integrally moved to an arbitrary position on the frame portion 40 by the X-direction moving device 68 and the Y-direction moving device 70. Further, the work heads 60 and 62 are detachably attached to the sliders 74 and 76, and the Z-direction moving device 72 individually moves the sliders 74 and 76 in the vertical direction. That is, the work heads 60 and 62 are individually moved in the vertical direction by the Z-direction moving device 72.

The mark camera 26 is attached to the slider 74 in a state of facing downward, and is moved in the X direction, the Y direction, and the Z direction together with the work head 60. As a result, the mark camera 26 captures an arbitrary position on the frame portion 40. As shown in FIG. 1, the parts camera 28 is arranged between the base material transfer holding device 22 on the frame portion 40 and the parts supply device 30 in a state of facing upward. As a result, the parts camera 28 takes an image of the parts gripped by the suction nozzles 66 of the work heads 60 and 62.

The component supply device 30 is arranged at one end of the frame portion 40 in the front-rear direction. The parts supply device 30 includes a tray-type parts supply device 78 and a feeder-type parts supply device (see FIG. 7) 80. The tray-type parts supply device 78 is a device that supplies parts in a state of being placed on the tray. The feeder type component supply device 80 is a device that supplies components by a tape feeder or a stick feeder (not shown).

The loose component supply device 32 is arranged at the other end of the frame portion 40 in the front-rear direction. The loose parts supply device 32 is a device that aligns a plurality of parts that are scattered apart and supplies the parts in the aligned state. That is, it is a device that aligns a plurality of parts in an arbitrary posture in a predetermined posture and supplies the parts in the predetermined posture.

Examples of the parts supplied by the parts supply device 30 and the loose parts supply device 32 include electronic circuit parts, solar cell components, power module components, and the like. Further, electronic circuit parts include parts having leads, parts having no leads, and the like.

The cut-and-clinch device 34 is arranged below the transfer device 50, and has a cut-and-clinch unit 100 and a unit moving device 102 as shown in FIG. As shown in FIG. 4, the cut-and-clinch unit 100 includes a unit main body 110, a pair of slide bodies 112, and a pitch changing mechanism 114. A slide rail 116 is arranged at the upper end of the unit main body 110 so as to extend in the X direction. A pair of slide bodies 112 are slidably supported by the slide rail 116. As a result, the pair of slide bodies 112 approach and separate in the X direction. Further, the pitch changing mechanism 114 has an electromagnetic motor 118, and the distance between the pair of slide bodies 112 can be controlled by operating the electromagnetic motor 118.

Further, as shown in FIG. 5, each of the pair of slide bodies 112 includes a fixed portion 120, a movable portion 122, and a slide device 124, and is slidably held by the slide rail 116 in the fixed portion 120. .. Two slide rails 126 are fixed to the back side of the fixed portion 120 so as to extend in the X direction, and the movable portion 122 is slidably held by the two slide rails 126. As a result, the movable portion 122 slides in the X direction with respect to the fixed portion 120. Further, the slide device 124 has an electromagnetic motor (see FIG. 7) 128, and the movable portion 122 slides in a controllable manner by the operation of the electromagnetic motor 128.

Further, the upper end portion of the fixing portion 120 has a tapered shape, and the first insertion hole 130 is formed so as to penetrate the upper end portion in the vertical direction. The first insertion hole 130 is open to the upper end surface of the fixing portion 120 at the upper end, and the opening edge to the upper end surface is a fixing blade (see FIG. 8) 131. Further, the first insertion hole 130 has an opening on the side surface of the fixing portion 120 at the lower end, and the waste box 132 is arranged below the opening to the side surface.

Further, as shown in FIG. 6, the upper end portion of the movable portion 122 also has a tapered shape, and the bent portion 133 bent into an L shape is formed at the upper end portion thereof. The bent portion 133 extends above the upper end surface of the fixed portion 120, and the bent portion 133 and the upper end of the fixed portion 120 face each other with a slight clearance. Further, the first insertion hole 130 that opens on the upper end surface of the fixing portion 120 is covered by the bending portion 133, but the bending portion 133 has a second insertion hole 136 so as to face the first insertion hole 130. Is formed.

The tip of the bent portion 133 extends to the middle of the upper end surface of the fixed portion 120, and a part of the upper end surface of the fixed portion 120 is exposed. Then, a protrusion 134 extending upward from the bent portion 133 is formed on an exposed part of the upper end surface thereof. That is, the protrusion 134 is formed on the upper end surface of the fixing portion 120 so as to face the tip of the bending portion 133.

Further, the second insertion hole 136 of the bent portion 133 is a through hole that penetrates the bent portion 133 in the vertical direction, and the inner peripheral surface of the second insertion hole 136 is a tapered surface whose inner diameter becomes smaller toward the bottom. ing. On the other hand, the inner peripheral surface in the vicinity of the opening of the fixing portion 120 of the first insertion hole 130 to the upper end surface is not a tapered surface, and the inner diameter in the vicinity of the opening of the first insertion hole 130 is substantially uniform. Further, the opening edge of the second insertion hole 136 to the lower end surface of the bent portion 133 is a movable blade (see FIG. 8) 138.

A first guide groove 140 is formed on the upper end surface of the bent portion 133 so as to extend in the X direction, that is, in the sliding direction of the movable portion 122. The first guide groove 140 is formed so as to straddle the opening of the second insertion hole 136, and the first guide groove 140 and the second insertion hole 136 are connected to each other. Further, the first guide groove 140 is open on both side surfaces of the bent portion 133. The inner side surface of the first guide groove 140, that is, the one that opens to the side surface on the side where the pair of slide bodies 112 face each other is referred to as the first inner guide groove 140a, and the first guide groove 140.
Of these, the outer side surface, that is, the one that opens to the side surface on the side where the pair of slide bodies 112 do not face each other may be referred to as a first outer guide groove 140b. Further, a second guide groove 142 is formed on the upper surface of the bent portion 133 so as to extend toward the opposite side of the tip of the bent portion 133, that is, toward the base end of the bent portion 133. The second guide groove 142 is connected to the second insertion hole 136 at one end, and is open to the side surface of the bent portion 133 on the base end side at the other end.

Further, the pair of slide bodies 112 are arranged in a point object. That is, one of the pair of slide bodies 112 is arranged in a state where the other is rotated 180 degrees around the vertical line. Therefore, the pair of slide bodies 112 are illustrated as shown in FIG. 15 when viewed from above. Specifically, one second guide groove 142 and the other second guide groove 142 of the pair of slide bodies 112 extend in different directions from each other, and the protrusion 134 of each slide body 112 extends. A second guide groove 142 is formed on the opposite side of the second insertion hole 136.

Further, as shown in FIG. 3, the unit moving device 102 includes an X-direction moving device 150, a Y-direction moving device 152, a Z-direction moving device 154, and a rotation device 156. The X-direction moving device 150 includes a slide rail 160 and an X slider 162. The slide rail 160 is arranged so as to extend in the X direction, and the X slider 162 is slidably held by the slide rail 160. Then, the X slider 162 moves in the X direction by driving the electromagnetic motor (see FIG. 7) 164. The Y-direction moving device 152 includes a slide rail 166 and a Y slider 168. The slide rail 166 is arranged on the X slider 162 so as to extend in the Y direction, and the Y slider 168 is slidably held by the slide rail 166. Then, the Y slider 168 moves in the Y direction by driving the electromagnetic motor (see FIG. 7) 170. The Z-direction moving device 154 includes a slide rail 172 and a Z slider 174. The slide rail 172 is arranged on the Y slider 168 so as to extend in the Z direction, and the Z slider 174 is slidably held by the slide rail 172. Then, the Z slider 174 moves in the Z direction by driving the electromagnetic motor (see FIG. 7) 176.

Further, the rotation device 156 generally has a disk-shaped rotary table 178. The rotary table 178 is rotatably supported by the Z slider 174 about its axis and is rotated by the drive of an electromagnetic motor (see FIG. 7) 180. The cut and clinch unit 100 is arranged on the rotary table 178. With such a structure, the cut-and-clinch unit 100 is moved to an arbitrary position by the X-direction moving device 150, the Y-direction moving device 152, and the Z-direction moving device 154, and is rotated to an arbitrary angle by the rotating device 156. do. The axis of the rotary table 178 and the midpoint of the straight line connecting the pair of slide bodies 112 coincide with each other. Therefore, when the cut and clinch unit 100 is rotated by the rotation device 156, the pair of slide bodies 112 rotates around the midpoint of the straight line connecting the pair of slide bodies 112. This makes it possible to position the second insertion hole 136 of the cut and clinch unit 100 at an arbitrary position below the circuit base material 12 held by the clamp device 52.

As shown in FIG. 7, the control device 36 includes a controller 190, a plurality of drive circuits 192, and an image processing device 196. The plurality of drive circuits 192 include the transfer device 50, the clamp device 52, the work heads 60 and 62, the work head moving device 64, the tray type parts supply device 78, the feeder type parts supply device 80, the loose parts supply device 32, and the electromagnetic motor. It is connected to 118, 128, 164, 170, 176, 180. The controller 190 includes a CPU, ROM, RAM, and the like, and is mainly a computer, and is connected to a plurality of drive circuits 192. As a result, the operation of the base material transfer holding device 22, the component mounting device 24, and the like is controlled by the controller 190. The controller 190 is also connected to the image processing device 196. The image processing device 196 processes the image data obtained by the mark camera 26 and the parts camera 28, and the controller 190 acquires various information from the image data.

<Operation of component mounting machine>
In the component mounting machine 10, components are mounted on the circuit substrate 12 held by the substrate transfer holding device 22 according to the above-described configuration. In the component mounting machine 10, various components can be mounted on the circuit substrate 12, but components having leads (hereinafter, may be abbreviated as "lead components") are attached to the circuit substrate 12. The case of mounting will be described below.

Specifically, the circuit base material 12 is conveyed to a working position, where it is fixedly held by the clamp device 52. Next, the mark camera 26 moves above the circuit base material 12 and takes an image of the circuit base material 12. As a result, information regarding the holding position of the circuit base material 12 and the like can be obtained. Further, the parts supply device 30 or the loose parts supply device 32 supplies lead parts at a predetermined supply position. Then, one of the work heads 60 and 62 moves above the supply position of the component and holds the component by the suction nozzle 66. As shown in FIG. 8, the lead component 200 is composed of a component fixing portion 202 and two leads 204 extending from the bottom surface of the component fixing portion 202. Then, the lead component 200 is suction-held at the component fixing portion 202 by the suction nozzle 66.

Subsequently, the work heads 60 and 62 holding the lead component 200 move above the parts camera 28, and the lead component 200 held by the suction nozzle 66 is imaged by the parts camera 28. As a result, information regarding the holding position of the component and the like can be obtained. Subsequently, the work heads 60 and 62 holding the lead component 200 move above the circuit base material 12, and correct an error in the holding position of the circuit base material 12, an error in the holding position of the component, and the like. Then, the two leads 204 of the lead component 200 that are sucked and held by the suction nozzle 66 are inserted into the two through holes 208 formed in the circuit base material 12. At this time, the cut and clinch unit 100 is moved below the circuit base material 12. In the cut and clinch unit 100, the coordinates of the second insertion hole 136 of the movable portion 122 in the XY direction and the coordinates of the through hole 208 of the circuit base material 12 in the XY direction match, and the movable portion 122 has the same coordinates. The upper surface is moved so as to be located slightly below the lower surface of the circuit base material 12.

Specifically, in the cut and clinch unit 100, the distance between the second insertion holes 136 of the movable portion 122 of the pair of slide bodies 112 is between the two through holes 208 formed in the circuit base material 12. The distance between the pair of slide bodies 112 is adjusted by the pitch changing mechanism 114 so as to be the same as the distance. Then, by the operation of the unit moving device 102, the cut and clinch unit 100 moves in the XYZ direction and rotates on its axis. As a result, the coordinates of the second insertion hole 136 of the movable portion 122 in the XY direction and the coordinates of the through hole 208 of the circuit base material 12 in the XY direction match. Further, as described above, the upper end surface of the fixed portion 120 is formed with a protrusion 134 extending upward from the bent portion 133 of the movable portion 122, so that the upper surface of the movable portion 122 and the circuit base material 12 are formed. The distance to the bottom surface is secured by the protrusion 134. As a result, the upper surface of the movable portion 122 is located slightly below the lower surface of the circuit base material 12.

Then, when the lead 204 of the lead component 200 sucked and held by the suction nozzle 66 is inserted into the through hole 208 of the circuit base material 12, the tip of the lead 204 is cut and clinched as shown in FIG. It is inserted into the first insertion hole 130 of the fixing portion 120 via the second insertion hole 136 of the movable portion 122 of the unit 100. At this time, since the inner peripheral surface of the second insertion hole 136 located below the through hole 208 is a tapered surface, even if the lead 204 is bent to some extent, the tip of the lead 204 is the first. 2 It is possible to appropriately secure the introduction into the insertion hole 136.

Next, when the tip of the lead 204 is inserted into the first insertion hole 130 via the second insertion hole 136, the pair of movable portions 122 slides in the approaching direction by the operation of the slide device 124. .. As a result, the lead 204 is cut by the fixed blade 131 of the first insertion hole 130 and the movable blade 138 of the second insertion hole 136, as shown in FIG. Then, the tip portion separated by cutting the lead 204 falls inside the first insertion hole 130 and is discarded in the waste box 132.

Further, the pair of movable portions 122 are slid in a direction closer to each other even after the lead 204 is cut. Therefore, the new tip portion of the lead 204 due to cutting bends along the tapered surface of the inner circumference of the second insertion hole 136 as the movable portion 122 slides, and further, the movable portion 122 slides. , The tip of the lead 204 bends along the first outer guide groove 140b. At this time, the pair of leads 204 are bent in the direction of approaching each other along the direction in which the pair of leads 204 are arranged. As a result, the lead component 200 is mounted on the circuit base material 12 in a state where the lead 204 is prevented from coming off from the through hole 208.

As described above, in the component mounting machine 10, the lead component 200 is attached to the circuit base material 12 in a state where the pair of leads 204 is cut by the cut and clinch device 34 and bent inward (hereinafter, “inwardly bent state”). It will be installed. However, the lead component 200 may not be properly mounted on the circuit base material 12 in the inwardly bent state. Specifically, for example, when the distance between the pair of leads 204 is short, that is, when the distance between the pair of through holes 208 formed in the circuit base material 12 is short, the inwardly bent state is obtained. As shown in FIG. 10, a pair of leads 204 may come into contact with each other and cause a short circuit. Therefore, when the distance between the pair of leads 204 is short, the lead component 200 is mounted on the circuit base material 12 in a state where the pair of leads 204 is bent outward (hereinafter, “outer bent state”). Will be done.

Specifically, as shown in FIG. 8, the lead 204 passes through the through hole 208 to the first insertion hole 130 and the first insertion hole 130, as in the case where the lead component 200 is mounted on the circuit base material 12 in the inwardly bent state. 2 It is inserted into the insertion hole 136. Next, the pair of movable portions 122 slides in a direction away from each other by the operation of the slide device 124. As a result, the lead 204 is cut by the fixed blade 131 of the first insertion hole 130 and the movable blade 138 of the second insertion hole 136, as shown in FIG. Then, the pair of movable portions 122 are slid in a direction further separated even after the lead 204 is cut. Therefore, the new tip portion of the lead 204 due to cutting bends along the tapered surface of the inner circumference of the second insertion hole 136 as the movable portion 122 slides, and further, the movable portion 122 slides. , The tip of the lead 204 bends along the first inner guide groove 140a. At this time, the pair of leads 204 are bent in a direction away from each other along the direction in which the pair of leads 204 are arranged. As a result, the lead component 200 is mounted on the circuit base material 12 in the outward bent state.

However, even in the outward bending state, the lead component 200 may not be properly mounted on the circuit base material 12. Specifically, for example, when the mounting positions of the two lead parts 200 are close to each other in the direction in which the leads 204 are lined up, as shown in FIG. 12, the through hole 208a for mounting the lead component 200 is used. , The through hole 208b for mounting another lead component 200 is adjacent to each other in the direction in which the leads 204 are arranged. Therefore, there is a possibility that the lead 204a of the lead component 200 mounted in the through hole 208a in the outward bent state and the lead 204b of the lead component 200 mounted in the through hole 208b in the outward bent state come into contact with each other and cause a short circuit. Therefore, in such a case, the lead component 200 is mounted on the circuit base material 12 in a state where the pair of leads 204 is bent in an N shape (hereinafter, “N bent state”).

Specifically, as shown in FIG. 8, the lead 204 is inserted through the through hole 208 as in the case where the lead component 200 is mounted on the circuit base material 12 in the inwardly bent state or the outwardly bent state. It is inserted into the first insertion hole 130 and the second insertion hole 136. Next, as shown in FIG. 13, the pair of slide bodies 112 are moved so that the distance between the pair of slide bodies 112 becomes long. That is, the pair of slide bodies 112 are slid in the direction in which they are separated from each other. This causes the pair of leads 204 to be slightly curved so as to spread.

The slide amount of the slide body 112 is applied to the blade end of the fixed blade 131 that cuts the lead 204 when the movable portion 122 slides inward, and the slide body 112 on the outer peripheral surface of the base end portion of the lead 204. It is set so that the nearest point matches in the vertical direction. That is, the slide body 112 is slid so that the base end of the lead 204 and the first insertion hole 130 slightly overlap each other in the vertical direction.

When the pair of slide bodies 112 are slid in the direction in which they are separated from each other, the pair of movable portions 122 are slid in the direction in which they are approached by the operation of the slide device 124. As a result, lead 2
04 is cut by the fixed blade 131 of the first insertion hole 130 and the movable blade 138 of the second insertion hole 136, as shown in FIG. Then, at the timing when the lead 204 is cut, the slide of the movable portion 122 is stopped. At this time, the through hole 208 and the second insertion hole 136 of the movable portion 122 substantially coincide with each other in the vertical direction. This is because the slide amount of the slide body 112 is set as described above. Therefore, the lead 204 curved by the slide of the slide body 112 is restored to be substantially linear by the slide of the movable portion 122.

Next, the cut and clinch unit 100 rotates by the operation of the rotation device 156. At this time, as shown in FIG. 15, the pair of slide bodies 112 rotate around the midpoint 210 of the straight line connecting the pair of slide bodies 112. The pair of slide bodies 112 rotate so that the protrusions 134 are in the traveling direction. That is, the pair of slide bodies 112 rotate so that the protrusion 134 is located in the front and the second guide groove 142 is located in the rear. This makes it possible to prevent the lead 204 from interfering with the protrusion 134 when the slide body 112 is rotated.

At this time, the lead 204 inserted in the second insertion hole 136 bends along the tapered surface of the inner circumference of the second insertion hole 136 as the slide body 112 rotates. Further, as the slide body 112 rotates, the tip end portion of the lead 204 bends along the second guide groove 142. The inner wall surface of the second guide groove 142 is oriented at a right angle to the first guide groove 140 on one side, and is oriented along the rotation direction of the slide body 112 on the other side. Therefore, the leads 204 are bent along the other side of the inner wall surface of the second guide groove 142, and as shown in FIG. 16, the pair of leads 204 is in a direction different from the direction in which the pair of leads 204 are arranged. , Bent in the direction of separation. That is, the pair of leads 204 is generally bent in an N shape. As a result, the lead component 200 is mounted on the circuit base material 12 in the N-bent state.

Further, by a method different from the above method, the lead component 200 can be mounted on the circuit base material 12 in the N-bent state. Specifically, as shown in FIG. 8, the lead 204 is inserted through the through hole 208 as in the case where the lead component 200 is mounted on the circuit base material 12 in the inwardly bent state or the outwardly bent state. It is inserted into the first insertion hole 130 and the second insertion hole 136. Next, as shown in FIG. 17, the pair of slide bodies 112 are moved so that the distance between the pair of slide bodies 112 is shortened. That is, the pair of slide bodies 112 are slid in the approaching direction. This causes the pair of leads 204 to bend slightly so that it closes. The slide amount of the slide body 112 is set by the same method as the above method.

When the pair of sliding bodies 112 are slid in the approaching direction, the pair of movable portions 122 are slid in the separating direction by the operation of the sliding device 124. As a result, the lead 204 is cut by the fixed blade 131 of the first insertion hole 130 and the movable blade 138 of the second insertion hole 136, as shown in FIG. Then, at the timing when the lead 204 is cut, the slide of the movable portion 122 is stopped. At this time, the through hole 208 and the second insertion hole 136 of the movable portion 122 substantially coincide with each other in the vertical direction. Therefore, the lead 204 curved by the slide of the slide body 112 is restored to be substantially linear by the slide of the movable portion 122.

Next, the cut-and-clinch unit 100 rotates by the operation of the rotation device 156, so that the pair of slide bodies 112 becomes the midpoint 210 of the straight line connecting the pair of slide bodies 112 as shown in FIG. Rotate around. The pair of slide bodies 112 rotate so that the protrusions 134 are in the traveling direction. The lead 204 inserted into the second insertion hole 136 bends along the tapered surface of the inner circumference of the second insertion hole 136 as the slide body 112 rotates. Further, as the slide body 112 rotates, the tip end portion of the lead 204 bends along the second guide groove 142. As a result, as shown in FIG. 16, the pair of leads 204 is generally bent in an N shape, and the lead component 200 is mounted on the circuit base material 12 in the N-bent state.

In this way, the pair of slide bodies 112 are slid in a direction to be separated from each other, and the pair of movable portions 122 are slid in a direction to be approached to cut the lead 204, and then the rotation of the cut and clinch unit 100 is performed. The lead 204 is brought into the N-bending state (hereinafter, may be referred to as "first N-bending method"), and the pair of slide bodies 112 are slid in the approaching direction to separate the pair of movable portions 122. A method in which the lead 204 is cut by sliding in the direction of the lead 204, and then the lead 204 is brought into an N-bent state by the rotation of the cut-and-clinch unit 100 (hereinafter, may be referred to as "second N-bending method"). According to any of the above methods, the lead component 200 can be mounted on the circuit base material 12 in an N-bent state.

It is preferable to adopt the first N bending method when the distance between the pair of leads 204 is short, and it is preferable to adopt the second N bending method when the distance between the pair of leads 204 is long. preferable.

Further, even in the N-bent state, the lead component 200 may not be properly mounted on the circuit base material 12. Specifically, for example, when the mounting positions of the two lead components 200 are close to each other in a direction different from the direction in which the leads 204 are lined up, as shown in FIG. 19, the penetration for mounting the lead component 200 of 1 is performed. The hole 208a and the through hole 208b for mounting another lead component 200 are adjacent to each other in a direction different from the direction in which the leads 204 are arranged. Therefore, there is a possibility that the lead 204a of the lead component 200 mounted in the through hole 208a in the outward bent state and the lead 204b of the lead component 200 mounted in the through hole 208b in the outward bent state come into contact with each other and cause a short circuit. Therefore, in such a case, the lead component 200 is mounted on the circuit base material 12 in the outward bent state or the inward bent state.

As described above, in the cut and clinch device 34, the lead component 200 can be mounted on the circuit base material 12 in any of the inward bending state, the outward bending state, and the N bending state. As a result, the lead component 200 can be mounted on the circuit base material 12 in various ways. For example, even when a plurality of lead parts 200 are mounted on the circuit base material 12 in close contact with each other, the lead component 200 can be mounted on the circuit base material 12. The lead component 200 can be appropriately mounted on the circuit base material 12 without causing a short circuit or the like.

As shown in FIG. 7, the controller 190 of the control device 36 has a first operation control unit 250, a second operation control unit 252, and a third operation control unit 254. The first operation control unit 250 is a functional unit for mounting the lead component 200 on the circuit base material 12 in an inwardly bent state. The second operation control unit 252 is a functional unit for mounting the lead component 200 on the circuit base material 12 in the outward bent state. The third operation control unit 254 is a functional unit for mounting the lead component 200 on the circuit base material 12 in the N-bent state.

The cut and clinch device 34 is an example of a cutting / bending device and a cutting device. The control device 36 is an example of a control device. The unit body 110 is an example of a holding portion. The slide body 112 is an example of the main body portion. The fixed portion 120 is an example of the first portion. The movable portion 122 is an example of the movable portion. The first insertion hole 130 is an example of a first through hole. The protrusion 134 is an example of a protrusion. The second insertion hole 136 is an example of the second through hole. The first guide groove 140 is an example of the first groove. The second guide groove 142 is an example of the second groove. The rotation device 156 is an example of a rotation mechanism. The lead component 200 is an example of a lead component. Lead 204 is an example of a lead. The first operation control unit 250 is an example of the first operation control unit. The second operation control unit 252 is an example of the second operation control unit. The third operation control unit 254 is an example of the third operation control unit.

The present invention is not limited to the above embodiment, and can be carried out in various embodiments with various changes and improvements based on the knowledge of those skilled in the art. Specifically, for example, in the above embodiment, the present invention is applied to the cut and clinch device 34 that cuts and bends the lead 204, but the present invention is applied to the lead cutting device that cuts the lead 204. It is possible to do. That is, when the lead component 200 is mounted on the circuit base material 12 in the N-bent state, the pair of movable portions 122 are slid in one of the direction in which the pair of slide bodies 112 are separated and the direction in which the pair of slide bodies 112 are brought close to each other. The present invention can be applied to a device that cuts a lead 204 by sliding it in the opposite direction of separation and approach. This makes it possible to make the cut lead 204 linear.

Further, in the above embodiment, the suction nozzle 66 is adopted as a holder for holding the lead component 200, but the lead chuck for gripping the lead 204 of the lead component 200 and the component fixing portion 202 of the lead component 200 are gripped. It is possible to use a body chuck or the like.

Further, in the above embodiment, as shown in FIG. 15, the cut and clinch unit 100 is rotated counterclockwise, so that the lead 204 is bent into an N-bent state as shown in FIG. By rotating the cut-and-clinch unit 100 clockwise, the lead 204 can be bent into a reverse N-bending state in which the lead 204 is bent in the direction opposite to the N-bending state shown in FIG. However, in order to realize the reverse N bending state, it is necessary to dispose the protrusion 134 and the second guide groove 142 on the opposite side of the position shown in FIG. 15 and the second insertion hole 136.

34: Cut and clinch device (cutting / bending device) (cutting device) 36: Control device 110: Unit main body (holding part) 112: Slide body (main body part) 120: Fixed part (first part) 122: Movable part (movable part) Part 2) 130: 1st insertion hole (1st through hole)
134: Protrusion 136: Second insertion hole (second through hole) 140a: First inner guide groove (first groove) 140b: First outer guide groove (first groove) 142: Second guide groove (second groove) ) 156: Rotation device (rotation mechanism) 200: Lead parts 204: Lead
250: 1st operation control unit 252: 2nd operation control unit 254: 3rd operation control unit

Claims (2)

A cutting / bending method in which a pair of leads of a lead component is cut and then bent.
A pair of body parts and
A holding part that holds the pair of main bodies so that they can approach and separate in the horizontal direction,
A rotation mechanism that rotates the holding portion and
With one unit equipped with
After cutting a pair of leads of the first lead component, the pair of leads is rotated by the rotation mechanism while the pair of leads are aligned with the pair of main bodies, respectively, to form a pair of leads. After performing N-bending to bend in the direction of separation and cutting a pair of leads of a lead component different from the first lead component, the pair of leads are aligned along the main body of the pair. A cutting / bending method characterized by performing reverse N bending in which a pair of leads are bent in a direction in which a pair of leads are separated by rotating the main body portion in a direction opposite to the rotation by the rotation mechanism. Each of the pair of main bodies is formed with a groove along the rotation direction of the main body by the rotation mechanism and a groove along the direction opposite to the rotation of the main body by the rotation mechanism . , N-bending to bend the pair of leads of the first lead component along the groove of the main body of the pair, and the pair of lead components different from the first lead component . The cutting / bending method according to claim 1, wherein the lead is bent along the groove of the pair of main bodies by reverse N bending.

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