JP4920366B2 - Manufacturing method of continuous terminal, continuous terminal and terminal plate - Google Patents

Description

  The present invention relates to a continuous terminal manufacturing method, a continuous terminal, and a terminal original plate.

  Conventionally, a continuous terminal in which a large number of terminals are arranged at predetermined intervals along the longitudinal direction of a strip-shaped carrier is known (for example, see Patent Document 1).

FIG. 14 shows the configuration of a continuous terminal according to such a conventional example. As shown in FIG. 14, the conventional continuous terminal integrally includes a carrier 101 extending in a predetermined direction and a plurality of terminals 102, and these terminals 102 are arranged in a direction along the carrier 101, respectively. It is connected. In other words, the carrier 101 and the plurality of terminals 102 are arranged in a direction orthogonal to the arrangement direction of the terminals 102. Further, this conventional continuous terminal is manufactured using a terminal original plate shown in FIG. 15 punched out from a single metal plate, and a plurality of terminal expansion portions 102a connected to the carrier 101 of the terminal original plate are bent. Thus, the plurality of terminals 102 are formed. The carrier 101 has a circular positioning hole 101a for positioning the terminal deployment portion 102a by inserting a round bar-shaped positioning pin when the terminal 102 is molded, and a feeding claw of the crimping machine when the terminal 102 is crimped to the electric wire. And a rectangular feed hole 101b for feeding the terminal 102 to the crimping portion.
JP-A-5-326055

  In order to manufacture the conventional continuous terminal shown in FIG. 14, a metal original plate having a width equal to or larger than the sum of the axial dimension of the terminal 102 and the width dimension of the carrier 101 must be used. Moreover, the carrier 101 is a portion that is discarded after the terminal 102 is crimped to the electric wire. Therefore, this conventional continuous terminal has a problem that the material cost increases because the material cost is increased by the amount of the carrier 101.

  The present invention has been made in order to solve the above-described problems. The object of the present invention is to position the terminal deployment portion during molding of the terminal while reducing the material cost, and to crimp the terminal to a crimping machine. It is possible to convey to the part.

In order to achieve the above object, a method of manufacturing a continuous terminal according to the present invention integrally has a plurality of terminal expansion portions having terminal expansion shapes, and each terminal expansion portion is in a specific direction intersecting the axial direction. For the circular positioning in each of the terminal expansion portions, the terminal expansion plates that are arranged and adjacent to each other are punched out from the metal plate in a region between the axial ends of the terminal expansion portions . forming a hole, after positioning of the terminal expansion portion by inserting the positioning pin before Symbol positioning hole, forming a terminal by bending the terminal expansion portion of the terminal A shape different from the positioning hole at a position overlapping the positioning hole and capable of entering the feeding claw of the crimping machine, and the feeding claw moves in the specific direction in the entering state. The end The and forming the feed holes that can be sent to the crimping portion with respect to the covered electric wire along a particular direction, forming the positioning hole of the terminal original plate to the respective terminals deployed portion simultaneously punched from a metal plate In the step of performing, each terminal unfolding portion has an unfolded shape of an electric connecting portion electrically connected to the counterpart terminal, and an unfolded portion of the core wire crimping portion that is crimped to the core wire portion of the covered electric wire. a core wire crimping portion expansion portion having a shape, the said terminal original plate so as to have a coating crimping portion expansion portion having a developed shape of the insulation crimp portion which is crimped to the insulating covering of the covered electric wire unplug out from the metal plate In addition, in the step of forming the positioning hole in the covering crimping part developing part of each terminal developing part and forming the feeding hole, the feeding is performed at a position overlapping the positioning hole of the covering crimping part developing part. Shape hole To.

  In this continuous terminal manufacturing method, since the terminal original plate in which the adjacent terminal development portions are connected to each other in the region between both ends in the axial direction is punched from the metal plate, the shaft of the terminal expansion portion is used as the metal plate. Those having a width in the direction dimension can be used. As a result, the material cost can be reduced as compared with the conventional case where a metal plate having a width equal to or larger than the dimension obtained by adding the dimension in the axial direction of the terminal deployment portion and the dimension in the width direction of the carrier is used. .

  In addition, when forming the terminal by bending the terminal expansion part, a positioning pin is required for inserting the positioning pin to position the terminal expansion part, while the crimping machine is used for crimping the terminal to the electric wire. The feed holes for feeding the terminals to the crimping portion by locking with the feed claws are required, and the shapes of the positioning holes and the feed holes are different. In other words, the circular shape corresponding to the positioning pin is appropriate as the shape of the positioning hole, while the shape of the feeding hole is a shape into which the feeding claw of the crimping machine can enter and the feeding claw is in the entered state. It is necessary to have a shape that allows the terminal to be sent to the crimping portion along the specific direction by moving in the direction. Here, when providing a carrier for connecting each terminal separately from the terminal as in the prior art, it can be dealt with by separately forming positioning holes and feeding holes having different shapes on the carrier. Since such a carrier is not provided in the manufacturing method of the terminal, how to secure the region for forming the positioning hole and the feeding hole becomes a problem.

In response to this problem, in the method of manufacturing a continuous terminal according to the present invention, after the terminal is molded from the terminal development portion positioned using the positioning hole and the positioning hole becomes unnecessary, the positioning hole of each terminal is formed. Since the feeding hole is formed at the overlapping position, even if the area that can be used is limited without providing a carrier, the positioning of the terminal deployment part can be performed at the time of molding the terminal using the positioning hole, By providing a feed hole at a position that overlaps with this positioning hole, the terminal is crimped by a crimping machine when crimping the terminal to the electric wire using the feed hole while suppressing the space required to form both holes. It can be conveyed to the part. Therefore, in this continuous terminal manufacturing method, while reducing the material cost, it is possible to position the terminal unfolding portion at the time of molding the terminal, and to convey the terminal to the crimping portion of the crimping machine. In addition, since the feed hole remains on the terminal even after the terminal is crimped to the coated electric wire, according to this continuous terminal manufacturing method, when the feed hole is formed in the electrical connection part development part or the core wire crimp part development part Inconveniences that occur can be avoided. That is, when the feed hole is formed in the electrical connection portion developing portion, the feed hole remains in the electrical connection portion of the terminal, so that there is a possibility that the electrical connection with the counterpart terminal may be hindered. In addition, when a feed hole is formed in the developed portion of the core wire crimping portion, the feed hole remains in the core wire crimp portion of the terminal, which hinders electrical connection between the core wire portion of the covered wire and the core wire crimp portion of the terminal. May occur. On the other hand, when the feeding hole is formed in the covering crimping portion developing portion as described above, the covering crimping portion is originally not electrically connected even if the feeding hole remains in the covering crimping portion of the terminal. Since it is crimped | bonded to the insulation coating | coated part of a non-covered electric wire, it can avoid that the problem that the electrical connectivity of a covered electric wire and a terminal deteriorates arises.

  In the method of manufacturing the continuous terminal, in the step of forming the feed hole, it is preferable that the feed hole is formed in a region including all the positioning holes. If comprised in this way, compared with the case where a feed hole is formed in the area | region which overlaps with the positioning hole, a positioning hole and a feed hole can be formed in a smaller area | region.

The terminal original plate according to the present invention has a developed shape of terminals, and a plurality of terminal developed portions arranged in a specific direction intersecting the axial direction, and the adjacent terminal developed portions between the axial ends thereof. And a connecting portion connected to each other in the region. And each said terminal expansion | deployment part has the expansion | deployment shape of the electrical connection part expansion | deployment part which has the expansion | deployment shape of the electrical connection part electrically connected with the other party terminal, and the crimping | compression-bonding part crimped | bonded to the core part of a covered electric wire. A core crimping portion developing portion and a covering crimping portion developing portion having a developed shape of a covering crimping portion to be crimped to the insulating coating portion of the coated electric wire, and one of the covering crimping portion developing portion and the connecting portion is , Having a positioning hole for positioning the terminal expansion part by inserting a positioning pin when the terminal is formed from the terminal expansion part, the other of the covering crimping part expansion part and the connecting part is The feeding hole of the crimping machine has a feeding hole capable of feeding the terminal to the crimping portion with respect to the covered electric wire along the specific direction by moving in the specific direction with the feeding claw entering, the feeding hole being The shape is different from the positioning hole The feed pawl has a possible entry shape.

  In this terminal original plate, adjacent terminal development portions are connected to each other in a region between both ends in the axial direction, so that the terminal original plate has a width in the axial dimension of the terminal development portion. A metal plate can be used. As a result, the material cost can be reduced as compared with the conventional case where a metal plate having a width equal to or larger than the dimension obtained by adding the dimension in the axial direction of the terminal deployment portion and the dimension in the width direction of the carrier is used. .

  In addition, when forming the terminal by bending the terminal expansion part of the terminal original plate, positioning pins are required to insert the positioning pins to position the terminal expansion part, while the terminal is crimped to the electric wire. Sometimes it is necessary to have a feed hole for feeding the terminal to the crimping part by locking with a feed claw of the crimping machine, and the positioning hole and the feed hole have different shapes. In other words, the circular shape corresponding to the positioning pin is appropriate as the shape of the positioning hole, while the shape of the feeding hole is a shape into which the feeding claw of the crimping machine can enter and the feeding claw is in the entered state. It is necessary to have a shape that allows the terminal to be sent to the crimping portion along the specific direction by moving in the direction. Here, when providing a carrier that connects each terminal expansion part separately from the terminal expansion part as in the prior art, it can be dealt with by separately forming positioning holes and feeding holes having different shapes in the carrier, Since such a carrier is not provided in the terminal original plate according to the present invention, how to secure a region for forming the positioning hole and the feeding hole becomes a problem.

  In response to this problem, in the terminal original plate according to the present invention, one of the terminal expansion part and the connection part has a positioning hole, and the other of the terminal expansion part and the connection part has a feed hole. Even if the area that can be used is limited, the positioning of the terminal deployment part can be performed during molding of the terminal using the positioning hole, and the terminal can be fixed when crimping the terminal to the electric wire using the feeding hole. It can be conveyed to the crimping part of the crimping machine. Therefore, with this terminal original plate, while reducing the material cost, the terminal unfolding portion can be positioned during the molding of the terminal, and the terminal can be conveyed to the crimping portion of the crimping machine.

  The method of manufacturing a continuous terminal according to the present invention includes a step of punching the terminal original plate from a metal plate, a positioning pin inserted into the positioning hole to position the terminal expanded portion, and then bending the terminal expanded portion And a step of forming the terminal.

  In this continuous terminal manufacturing method, adjacent terminals are connected to each other via a connecting portion in a region between their axial ends, and one of the terminal and the connecting portion has a positioning hole. Since the terminal and the other of the connecting part can form a continuous terminal having a feed hole, the terminal unfolding part can be positioned at the time of molding the terminal while reducing the material cost as in the case of the terminal original plate. At the same time, the terminal can be conveyed to the crimping part of the crimping machine.

In the method for manufacturing the continuous terminals, wherein in the step of forming the feed holes, and the edge of the feeding direction downstream side of the terminal to which the feed pawl as the hole abuts when sending the terminal, the feed prior SL terminal It is preferable to form a feed hole having an edge portion on the upstream side in the direction. According to this structure, it is possible that the nail feeding the feed holes easily configured to engage locks with structure Ru can der sending terminal.

  In this case, in the step of forming the feed hole, it is preferable that the edge portion on the downstream side in the feed direction of the feed hole is formed in a straight line extending in a direction orthogonal to the specific direction. If comprised in this way, the edge part of the said feed direction downstream of the feed hole may be formed in the shape which the surface of the said feed direction downstream of a feed claw can contact | abut stably when sending a terminal. it can. For this reason, the structure which can send a terminal stably to a predetermined feed position with a feed claw can be comprised.

  In the continuous terminal manufacturing method, in the step of forming the feed hole, the feed hole may be formed in a long hole shape along the specific direction.

In the method for manufacturing the continuous terminal, in the step of forming the feed hole, both edges of the feed hole in a direction orthogonal to the specific direction are moved from the upstream side to the downstream side in the feed direction of the terminal. It is preferable to form in a shape that gradually approaches each other. With this configuration, when the feed claw feeds the terminal, even if the terminal is displaced in the direction orthogonal to the feed direction, the feed hole is formed in a shape that can correct the displacement. can do.

  The continuous terminal according to the present invention is a continuous terminal produced by the above-described continuous terminal manufacturing method, and integrally includes a plurality of terminals arranged in the specific direction, and the adjacent terminals are in the axial direction thereof. Are connected to each other in the region between the two ends of.

  Since this continuous terminal is manufactured by the above-described continuous terminal manufacturing method, the terminal deployment portion is positioned at the time of molding the terminal, while reducing the material cost, as in the continuous terminal manufacturing method. It can be made transportable to the crimping part of the crimping machine.

  As described above, according to the present invention, it is possible to position the terminal unfolding portion at the time of molding the terminal and to transport the terminal to the crimping portion of the crimping machine while reducing the material cost.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

(First embodiment)
FIG. 1 is a schematic view showing the configuration of a production line used in the method for producing a continuous terminal according to the first embodiment of the present invention. FIG. 2 is a plan view showing a configuration of a terminal original plate used for manufacturing a continuous terminal according to the first embodiment of the present invention. FIG. 3 is a plan view showing the configuration of the continuous terminal according to the first embodiment of the present invention. 4-6 is a figure for demonstrating the state at the time of sending the continuous terminal shown in FIG. 3 to a crimping | compression-bonding part with the feed claw of a crimping machine. A method of manufacturing a continuous terminal according to the first embodiment of the present invention will be described with reference to FIGS.

  In the continuous terminal manufacturing method according to the first embodiment, a continuous terminal is manufactured in a series of continuous steps using a manufacturing line as shown in FIG. This production line includes a punching part 201, a terminal forming part 202, a hole forming part 203, and a winding part 204.

  In this production line, first, a long and wide thin metal plate 200 (metal plate) serving as a material for a continuous terminal is sequentially fed into the punched portion 201 along its longitudinal direction. Then, by punching the metal thin plate 200 in the punching portion 201, the terminal original plate shown in FIG. 2 is manufactured.

  The produced terminal original plate integrally has a plurality of identical terminal expanding portions 1 arranged in a specific direction. Each terminal expansion part 1 has a developed shape of a terminal 11 described later. And each terminal expansion | deployment part 1 has the electrical connection part expansion | deployment part 2, the wire barrel expansion | deployment part 3, and the insulation barrel expansion | deployment part 4, respectively. The electrical connection part development part 2, the wire barrel development part 3, and the insulation barrel development part 4 are provided in this order in a direction orthogonal to the arrangement direction of the terminal development parts 1. The electrical connecting portion developing portion 2 has a developed shape of an electric connecting portion 12 described later, and the wire barrel developing portion 3 has a developed shape of a wire barrel 13 described later. Moreover, the insulation barrel development part 4 has the expansion | deployment shape of the insulation barrel crimped | bonded to the insulation coating part of a covered electric wire. And the insulation barrel expansion | deployment parts 4 of the adjacent terminal expansion | deployment part 1 are connected along the sequence direction of the terminal expansion | deployment part 1 via the connection part 5 between insulation barrels. Simultaneously with the punching process of the terminal original plate, a circular positioning hole 4a is formed at the center in the longitudinal direction of the insulation barrel expanding portion 4 of each terminal expanding portion 1. The terminal original plate produced in this way is sequentially fed into the terminal molding part 202.

  In the terminal molding part 202, the terminal 11 (see FIG. 3) is formed by bending the terminal development part 1 of the terminal original plate. Specifically, first, a round bar-shaped positioning pin (not shown) is inserted into the positioning hole 4 a of the terminal deployment part 1. And each terminal expansion | deployment part 1 is positioned in the shaping | molding position of the terminal shaping | molding part 202 in order with this positioning pin. Then, the electric connecting portion 12 is formed by bending the electric connecting portion developing portion 2 of the terminal expanding portion 1, and the wire barrel developing portion 3 of the terminal expanding portion 1 is bent, so that the cross section is substantially U. A character-shaped wire barrel 13 is formed. At this time, the insulation barrel development part 4 of the terminal development part 1 is not bent and its shape is maintained. In this way, a structure in which the insulation barrel developing portions 4 of the adjacent terminals 11 are connected to each other via the inter-insulation barrel connecting portion 5 is formed.

  Thereafter, in the hole forming portion 203, a later-described feed hole 14a is formed in the insulation barrel developing portion 4 of each terminal 11. At this time, since the molding of the terminal 11 has already been completed and the positioning hole 4a is not necessary, the feeding hole 14a is formed at a position overlapping the positioning hole 4a of the terminal 11. Moreover, the feed hole 14a is larger than the positioning hole 4a and is formed in a region including all the positioning holes 4a. In this way, the continuous terminal shown in FIG. 3 is produced.

  The produced continuous terminal includes a plurality of terminals 11 integrally. The terminal 11 is crimped to the covered electric wire and is attached to the housing of the connector. When the connector is mated with the mating connector, the terminal 11 is coupled with the mating connector terminal to make an electrical connection. is there. In this continuous terminal, a large number of terminals 11 are arranged at predetermined intervals in a specific direction orthogonal to the axial direction. Each terminal 11 integrally includes an electrical connecting portion 12, a wire barrel 13, and an insulation barrel developing portion 4. The electrical connecting portion 12, the wire barrel 13, and the insulation barrel expanding portion 4 are provided in this order along the axial direction of the terminal 11.

  The electrical connection portion 12 is a portion that is electrically connected to the terminal of the counterpart connector. The wire barrel 13 is a part that is crimped to the exposed core part of the covered electric wire. The insulation barrel developing part 4 extends in the arrangement direction of the terminals 11. And the insulation barrel expansion | deployment parts 4 of the adjacent terminal 11 are mutually connected along the sequence direction of the terminal 11 via the connection part 5 between insulation barrels. Thereby, the adjacent terminals 11 are mutually connected in the area | region between the both ends of those axial directions. In addition, when the insulation barrel is crimped to the insulation coating portion of the covered electric wire, after the coupling portion between the insulation barrel deployment portion 4 and the connection portion 5 between the insulation barrels is cut, the insulation barrel deployment portion 4 is By bending, an insulation barrel having a substantially U-shaped cross section is formed. And while the insulation coating part of a covered electric wire is set in this insulation barrel, it is crimped | bonded so that an insulation barrel may hold an insulation coating part.

  Further, a feed hole 14a is formed in the center portion in the longitudinal direction of the insulation barrel developing portion 4 of each terminal 11. As shown in FIG. 4, the feed hole 14 a is used to feed the terminal 11 in turn to the crimping portion of the crimping machine when the feed claw 100 of the crimping machine is locked when the terminal 11 is crimped to the covered electric wire. It is The feed hole 14a has a shape different from that of the positioning hole 4a and has a shape into which the feed claw 100 of the crimping machine can enter. And this feed hole 14a is a shape which can send the terminal 11 to the said crimping | compression-bonding part along the specific direction by moving to the specific direction where the terminal 11 was arranged in the state which the said feed claw 100 approached. Is formed. Further, the feed hole 14a includes an edge portion 14b on the downstream side in the feed direction of the terminal 11 that abuts when the feed claw 100 sends the terminal 11, and a feed direction of the terminal 11 after the feed claw 100 sends the terminal 11. And an edge portion 14c on the upstream side in the feed direction of the terminal 11 that can be removed from the feed hole 14a when returned in the opposite direction.

  Specifically, as shown in FIG. 5, the feed hole 14 a is formed in a trapezoidal long hole along the arrangement direction of the terminals 11 (feed direction of the terminals 11). Then, the edge 14b on the downstream side in the feed direction and the edge 14c on the upstream side in the feed direction of the feed hole 14a extend linearly in a direction orthogonal to the arrangement direction (feed direction) of the terminals 11, respectively. When the terminal 11 is fed, the feed claw 100 is stably engaged with the feed hole 14a by the plane in the feed claw 100 on the downstream side in the feed direction coming into contact with the edge 14b on the downstream side in the feed direction of the feed hole 14a. It comes to stop. Then, both end portions of the feed hole 14a in the direction perpendicular to the feed direction of the feed claw 100 when the feed claw 100 comes into contact with the edge portion 14b at both ends of the edge portion 14b on the downstream side in the feed direction. Are provided with contact portions 14d and 14d. Further, both edge portions 14e, 14e of the feed hole 14a in the direction orthogonal to the feed direction are formed so as to gradually approach each other as they go from the upstream side to the downstream side in the feed direction.

  Then, the feeding claw 100 is returned to the direction opposite to the feeding direction of the terminal 11 along the trajectory indicated by the positions A to D in FIG. 6 after feeding the terminal 11 to a predetermined position. At this time, the feed claw 100 is extracted obliquely upward from the feed hole 14a while moving to the upstream side of the terminal 11 in the feed direction. At this time, the inclined surface on the upstream side in the feed direction of the feed claw 100 is in sliding contact with the edge portion 14c on the upstream side in the feed direction of the feed hole 14a. The edge portion 14c is arranged in the arrangement direction of the terminals 11 (feed direction). ) Linearly extends in a direction perpendicular to the edge 14c, so that the feed claw 100 can be smoothly pulled out without being caught by the edge portion 14c. Thereafter, the feeding claw 100 enters the next feeding hole 14a and repeats the above operation, thereby feeding each terminal 11 in turn.

  Finally, the continuous terminals produced as described above are sequentially wound around the reel in the winding unit 204. As described above, the continuous terminal according to the first embodiment is manufactured.

  As described above, in the manufacturing method of the continuous terminal according to the first embodiment, the terminal original plate in which the adjacent terminal development portions 1 are connected to each other in the region between both ends in the axial direction is formed from the metal thin plate 200. Since the punching is performed, it is possible to use the metal thin plate 200 having a width in the axial direction of the terminal expansion portion 1. As a result, the material cost can be reduced as compared with the conventional case where a metal plate having a width equal to or larger than the dimension obtained by adding the dimension in the axial direction of the terminal deployment portion and the dimension in the width direction of the carrier is used. .

  Further, when forming the terminal 11 by bending the terminal expanding portion 1, a positioning hole 4 a for inserting the positioning pin to position the terminal expanding portion 1 is necessary, while the covered wire of the terminal 11 is formed. At the time of crimping, the feeding claw 100 of the crimping machine is locked and a feeding hole 14a for feeding the terminal 11 to the crimping portion is necessary, and the positioning hole 4a and the feeding hole 14a have different shapes. That is, the circular shape corresponding to the positioning pin is appropriate as the shape of the positioning hole 4a, while the shape of the feeding hole 14a is a shape into which the feeding claw 100 of the crimping machine can enter and the feeding claw 100 enters. It is necessary that the terminal 11 has a shape capable of being sent to the crimping portion along the arrangement direction by moving in the arrangement direction of the terminal 11 in the state. Here, when providing a carrier for connecting each terminal separately from the terminal as in the conventional case, this carrier can be coped with by individually forming the positioning hole 4a and the feeding hole 14a having different shapes in the carrier, In the manufacturing method of the continuous terminal according to the first embodiment, such a carrier is not provided. Therefore, how to secure a region for forming the positioning hole 4a and the feeding hole 14a becomes a problem.

  In response to this problem, in the manufacturing method of the continuous terminal according to the first embodiment, after the terminal 11 is formed from the terminal development portion 1 positioned using the positioning hole 4a and the positioning hole 4a becomes unnecessary, each terminal is Since the feed hole 14a is formed at a position overlapping the 11 positioning hole 4a, even if the carrier is not provided and the usable area is limited, the terminal expanding portion is formed when the terminal 11 is formed using the positioning hole 4a. 1 can be positioned, and the feed hole 14a is provided at a position overlapping with the positioning hole 4a, so that the space required for forming both holes is reduced and the terminal using the feed hole 14a is used. The terminal 11 can be conveyed to the crimping | compression-bonding part of a crimping machine at the time of the crimping | compression-bonding to 11 covered electric wires. Therefore, in this continuous terminal manufacturing method, the terminal unfolding portion 1 can be positioned during molding of the terminal 11 while reducing the material cost, and the terminal 11 can be conveyed to the crimping portion of the crimping machine.

  Moreover, in the manufacturing method of the continuous terminal by 1st Embodiment, the positioning hole 4a is formed in the insulation barrel expansion | deployment part 4, and the hole 14a for a feed is formed in the area | region which overlaps the positioning hole 4a of the insulation barrel expansion | deployment part 4 after that. Form. Since the feed hole 14a remains on the terminal 11 even after the terminal 11 is crimped to the covered electric wire, if the feed hole 14a is formed in the insulation barrel developing part 4 in this way, the electric connecting part developing part 2 or the wire barrel Inconveniences that occur when the feed hole 14a is formed in the development part 3 can be avoided. That is, when the feed hole 14a is formed in the electrical connection portion developing portion 2, the feed hole 14a remains in the electrical connection portion 12 of the terminal 11, so that there is a risk of hindering electrical connection with the counterpart terminal. is there. Further, when the feed hole 14a is formed in the wire barrel developing portion 3, the feed hole 14a remains in the wire barrel 13 of the terminal 11, so that the electrical connection between the core wire portion of the covered wire and the wire barrel 13 is hindered. May occur. On the other hand, in the case where the feed hole 14a is formed in the insulation barrel developing portion 4 as described above, the insulation barrel is originally electrically connected even if the feed hole 14a remains in the insulation barrel of the terminal 11. Since it is crimped | bonded to the insulation coating | coated part of the covered electric wire which does not take an easy connection, it can avoid that the problem that the electrical connection property of a covered electric wire and the terminal 11 deteriorates arises.

  In the continuous terminal manufacturing method according to the first embodiment, since the feed hole 14a is formed in a region including all the positioning holes 4a of the terminal 11, the feed hole 14a is formed in a region partially overlapping with the positioning hole 4a. As compared with the case of forming the positioning hole 4a, the positioning hole 4a and the feeding hole 14a can be formed in a smaller area.

  Moreover, in the manufacturing method of the continuous terminal by 1st Embodiment, since the edge part 14b of the said feed direction downstream side of the feed hole 14a is formed in the linear form extended in the direction orthogonal to the arrangement direction of the terminal 11, the terminal 11 is formed. When feeding, the surface of the feeding claw 100 on the downstream side in the feeding direction can stably come into contact with the edge portion 14b. For this reason, the terminal 11 can be stably sent to the predetermined feed position by the feed claw 100.

  Moreover, in the manufacturing method of the continuous terminal by 1st Embodiment, both edge part 14e, 14e of the hole 14a for a feed in the direction orthogonal to the arrangement direction of the terminal 11 goes to the downstream from the feed direction upstream of the terminal 11. Since they are formed so as to gradually approach each other, even when the feed claw 100 sends the terminal 11, even if the terminal 11 is displaced in the direction perpendicular to the feed direction, the feed claw 100 is The position shift can be corrected by contacting the portions 14e and 14e.

  Moreover, in the manufacturing method of the continuous terminal by 1st Embodiment, when the feed nail | claw 100 latches in the hole 14a for a feed, the contact | abutment which each contact | abuts to the both ends of the direction orthogonal to the feed direction of the terminal 11 of the feed claw 100 respectively. Since the portions 14d and 14d are formed in the feeding hole 14a, it is possible to prevent the terminal 11 from being displaced in the direction orthogonal to the feeding direction by the contact portions 14d and 14d when the terminal 11 is transported.

  Note that, at the position upstream of the contact portions 14d and 14d in the feed direction, the width of the feed hole 14a in the direction orthogonal to the feed direction is larger than that of the feed claw 100. When 100 enters the feed hole 14a, the feed claw 100 can easily enter the feed hole 14a even if the position of the feed hole 14a with respect to the feed claw 100 is slightly shifted in the direction perpendicular to the feed direction. Is possible.

  Moreover, the effect by the continuous terminal of 1st Embodiment is the same as the effect by the manufacturing method of the continuous terminal of the said 1st Embodiment.

(Second Embodiment)
FIG. 7 is a plan view showing the configuration of the terminal original plate according to the second embodiment of the present invention. Next, with reference to FIG. 7, the manufacturing method of the continuous terminal by 2nd Embodiment of this invention and the structure of the terminal original plate used for the manufacturing method are demonstrated.

  In the continuous terminal manufacturing method according to the second embodiment, a terminal original plate having the structure shown in FIG. 7 is punched from the metal thin plate 200 at the punching portion 201 (see FIG. 1) of the manufacturing line. In this terminal original plate, the wire barrel development parts 33 of the adjacent terminal development parts 31 are connected to each other via a wire barrel connection part 40 (connection part) provided between them. By this wire barrel connecting portion 40, adjacent terminal development portions 31 are connected to each other in a region between both ends in the axial direction. And unlike the said 1st Embodiment, the insulation barrel expansion | deployment part 34 of the adjacent terminal expansion | deployment part 31 is not connected mutually.

  And in the manufacturing method of the continuous terminal by this 2nd Embodiment, when punching a terminal original board, while simultaneously forming the feed hole 14a in the center part of the longitudinal direction of the insulation barrel expansion part 34, a connection part between wire barrels A positioning hole 40a is formed in the central portion of the longitudinal direction of 40. The feed hole 14a is similar to the feed hole 14a according to the first embodiment, and the positioning hole 40a is similar to the positioning hole 4a according to the first embodiment.

  Then, after a positioning pin is inserted into the positioning hole 40a, the terminal development portion 31 is positioned at the molding position of the terminal molding portion 202 (see FIG. 1) of the production line by the positioning pin. Thereafter, the terminal development part 31 is bent to form a terminal. Specifically, the electrical connection portion deployment portion 2 of the terminal deployment portion 31 is bent to form an electrical connection portion, and the insulation barrel deployment portion 34 is bent to form an insulation barrel. On the other hand, the wire barrel development part 33 of the terminal development part 31 is not bent and its shape is maintained. In this way, a continuous terminal is formed in which the wire barrel developing portions 33 of adjacent terminals are connected to each other via the wire barrel connecting portion 40.

  In the production line according to the second embodiment, unlike the first embodiment, the hole forming portion 203 (see FIG. 1) is not provided, and the continuous terminal manufactured as described above is provided in the winding portion 204 ( (See FIG. 1). The other processes of the continuous terminal manufacturing method according to the second embodiment are the same as those of the continuous terminal manufacturing method according to the first embodiment.

  When the terminal is crimped to the covered electric wire, the continuous terminal is set in the crimping machine, and the feeding claw of the crimping machine is locked in the feeding hole 14a to convey the terminal to the crimping part. Then, immediately before the terminal is crimped to the covered electric wire, the connecting portion between the wire barrel connecting portion 40 and the wire barrel expanding portion 33 is cut and the wire barrel connecting portion 40 is discarded, and the wire barrel expanding portion 33 is The wire barrel is formed by bending.

  As described above, in the manufacturing method of the continuous terminal according to the second embodiment, the terminal original plate in which the adjacent terminal development portions 31 are connected to each other in the region between both ends in the axial direction is formed from the metal thin plate 200. Since the punching is performed, the material cost can be reduced as in the manufacturing method of the continuous terminal according to the first embodiment.

  Moreover, in the manufacturing method of the continuous terminal by 2nd Embodiment, while the connection part 40 between wire barrels has the positioning hole 40a, while the insulation barrel expansion | deployment part 34 has the hole 14a for feeding, the terminal original board is the metal thin plate 200. Therefore, even if the carrier is not provided and the usable area is limited, the terminal deployment portion 31 can be positioned at the time of molding the terminal using the positioning hole 40a and the feed hole 14a is used. The terminal can be conveyed to the crimping part of the crimping machine when the terminal is crimped to the covered electric wire. Therefore, while reducing the material cost, the terminal deployment part 31 can be positioned at the time of molding the terminal, and the terminal can be conveyed to the crimping part of the crimping machine.

  The effects of the continuous terminal manufacturing method according to the second embodiment, the continuous terminals, and the terminal original plate other than those described above are the same as the effects according to the first embodiment.

  The embodiment disclosed this time should be considered as illustrative in all points and not restrictive. The scope of the present invention is shown not by the above description of the embodiments but by the scope of claims for patent, and further includes meanings equivalent to the scope of claims for patent and all modifications within the scope.

  For example, not only the configuration of the continuous terminal according to the first embodiment, but also a continuous terminal in which the insulation barrel developing portions 44 of adjacent terminals 11 are directly connected to each other as in the first modification shown in FIG. Also good.

  Further, not limited to the configuration of the second embodiment, as in the second modified example shown in FIG. 9, the connection connecting the respective wire barrel deployment portions 33 and the insulation barrel deployment portions 34 in the adjacent terminal deployment portions 31. The terminal original plate may be formed such that the portions 35 are connected to each other via the connecting portion connecting portion 50 (connecting portion). And the continuous terminal which the connection parts 35 of the adjacent terminal connected mutually via the connection part connection part 50 using this terminal original plate | board may be formed. In this second modified example, the terminal original plate is punched, and at the same time, a positioning hole 50a similar to the positioning hole 40a according to the second embodiment is formed in the central portion in the longitudinal direction of the connecting portion connecting portion 50, and the insulation is formed. A feed hole 14 a is formed in the barrel developing portion 34. The position where the positioning hole 50a is formed and the position where the feed hole 14a is formed may be interchanged. In other words, the positioning hole 50a may be formed in the central portion in the longitudinal direction of the insulation barrel developing portion 34, and the feed hole 14a may be formed in the central portion in the longitudinal direction of the connecting portion connecting portion 50. In the second embodiment, the position where the positioning hole 40a is formed and the position where the feeding hole 14a is formed may be interchanged. That is, in the second embodiment, the positioning hole 40a is formed in the longitudinal center portion of the insulation barrel developing portion 34, and the feed hole 14a is formed in the longitudinal center portion of the wire barrel connecting portion 40. May be.

  Further, as in the third modified example shown in FIG. 10, the wire barrel development part 33, the insulation barrel development part 34, and the connection part 35 of the adjacent terminal development part 31 are respectively connected between the wire barrel connection part 40 and the insulation barrel. You may form a terminal original plate so that it may mutually connect via the connection part 60 (connection part) which consists of the connection part 5 and the connection part 50 between connection parts. That is, the adjacent wire barrel development portions 33 are connected to each other via the wire barrel connecting portion 40, and the adjacent insulation barrel development portions 34 are connected to each other via the insulation barrel connecting portion 5. Further, the adjacent connecting portions 35 are connected to each other via the connecting portion connecting portion 50. And the wire barrel expansion | deployment part 33 of the adjacent terminal using this terminal original plate, the insulation barrel expansion | deployment part 34, and the connection part 35 are the connection part 40 between wire barrels, the connection part 5 between insulation barrels, and the connection part between connection parts, respectively. You may form the continuous terminal mutually connected via 50. FIG. And in this 3rd modification, while punching a terminal original board, while forming the positioning hole 40a in the center part of the longitudinal direction of the connection part 40 between wire barrels, the feed hole 14a is formed in the insulation barrel expansion part 34 To do.

  In the third modification, the position where the positioning hole 40a is formed and the position where the feeding hole 14a is formed may be interchanged. That is, the positioning hole 40 a may be formed in the longitudinal center portion of the insulation barrel developing portion 34, and the feeding hole 14 a may be formed in the longitudinal center portion of the wire barrel connecting portion 40. Further, in this third modification, one of the positioning hole and the feeding hole is formed in the central portion in the longitudinal direction of the connecting portion connecting portion 50 and the other is formed in the central portion in the longitudinal direction of the insulation barrel developing portion 34. You may form in. At this time, the positioning hole and the feeding hole are not formed in the wire barrel connecting portion 40.

  Further, in each of the above embodiments and each of the above modifications, the feed hole 14a is formed as a trapezoidal elongated hole along the feed direction of the terminal, but the feed hole is formed in various shapes other than such a shape. May be. For example, as in the fourth modification shown in FIG. 11, the feeding hole 64a may be formed in a triangular elongated hole along the terminal feeding direction. When the feeding hole 64a is such a triangular slot, a feeding claw 100a having a triangular cross section corresponding to the shape of the feeding hole 64a is provided as in the fifth modification shown in FIG. May be used to transport the terminals. If comprised in this way, since the shape of the part of the said feed claw 100a in the said feed direction downstream and the shape of the edge of the said feed hole 64a on the said feed direction downstream side match, The edge of the feed hole 64a can be fitted to prevent the terminal from being displaced in the direction orthogonal to the feed direction. Further, as in the sixth modification shown in FIG. 13, the feed hole 74 a may be formed in a substantially rectangular long hole along the feed direction of the terminal.

  In the first embodiment, the feed hole 14a is formed in the region including all the positioning holes 4a of the terminal 11. However, the present invention is not limited thereto, and the feed hole 14a is fed to the region partially overlapping with the positioning hole 4a of the terminal 11. A service hole may be formed.

It is the schematic which showed the structure of the manufacturing line used for the manufacturing method of the continuous terminal by 1st Embodiment of this invention. It is the top view which showed the structure of the terminal original plate used for manufacture of the continuous terminal by 1st Embodiment of this invention. It is the top view which showed the structure of the continuous terminal by 1st Embodiment of this invention. It is a longitudinal cross-sectional view for demonstrating the state at the time of sending the continuous terminal shown in FIG. 3 to a crimping | compression-bonding part with the feed claw of a crimping machine. It is sectional drawing along the VV line of the structure shown in FIG. It is a longitudinal cross-sectional view corresponding to FIG. 4 for demonstrating a state when extracting the feed nail of a crimping machine from the hole for a feed. It is the top view which showed the structure of the terminal original plate by 2nd Embodiment of this invention. It is the top view which showed the structure of the continuous terminal by the 1st modification of embodiment of this invention. It is the top view which showed the structure of the terminal original plate by the 2nd modification of embodiment of this invention. It is the top view which showed the structure of the terminal original plate by the 3rd modification of embodiment of this invention. It is the top view which showed the structure of the hole for a continuous terminal by the 4th modification of embodiment of this invention. It is the top view which showed the structure of the hole for a continuous terminal by the 5th modification of embodiment of this invention. It is the top view which showed the structure of the hole for a continuous terminal by the 6th modification of embodiment of this invention. It is the top view which showed the structure of the continuous terminal by a conventional example. It is the top view which showed the structure of the terminal original plate for forming the conventional continuous terminal shown in FIG.

Explanation of symbols

1, 31 Terminal expansion part 2 Electrical connection part expansion part 3, 33 Wire barrel expansion part (core wire crimping part expansion part)
4, 34, 44 Insulation barrel developed part (Coating crimping part developed part)
4a, 40a, 50a Positioning hole 5 Insulation barrel connecting part (connecting part)
11 Terminal 12 Electrical connection 13 Wire barrel (core crimping part)
14a, 64a, 74a 14d for feed contact part 40 wire barrel connecting part (connecting part)
50 Connection part (connection part) between connection parts
60 Connection between terminals (connection)
100, 100a Feeding claw 200 Metal thin plate (metal plate)

Claims (9)

A plurality of terminal expansion portions having a terminal expansion shape are integrally formed, the terminal expansion portions are arranged in a specific direction intersecting the axial direction, and the adjacent terminal expansion portions are arranged in their axial directions. A step of punching out terminal metal plates connected to each other in a region between both ends from the metal plate, and simultaneously forming a circular positioning hole in each terminal unfolded portion ;
After pre-Symbol insert and positioning of the terminal development part positioning pin into the positioning hole, forming a terminal by bending the terminal expansion unit,
The terminal has a shape different from that of the positioning hole at a position overlapping the positioning hole of the terminal, and has a shape into which the feeding claw of the crimping machine can enter, and the feeding claw moves in the specific direction in the entering state. Forming a hole for feeding capable of feeding the terminal along the specific direction to the crimping portion with respect to the covered electric wire,
In the step of punching the terminal original plate from the metal plate and simultaneously forming the positioning hole in each terminal expansion portion, each terminal expansion portion has an expanded shape of an electrical connection portion that is electrically connected to the mating terminal. Expanded portion of the electrical connection portion, the expanded portion of the core wire crimp portion crimped to the core wire portion of the coated electric wire, and the expanded shape of the coated crimp portion crimped to the insulating coating portion of the coated electric wire the terminal original plate so as to have a coating crimping portion expansion portion disconnect rather with out from the metal plate, wherein the positioning hole is formed before said Symbol insulation crimp portion expansion portion of the terminal expansion unit,
In the step of forming the feed hole, the continuous hole manufacturing method is such that the feed hole is formed at a position overlapping the positioning hole of the coated crimping portion developing portion.   The method for manufacturing a continuous terminal according to claim 1, wherein in the step of forming the feed hole, the feed hole is formed in a region including all the positioning holes. A plurality of terminal expansion portions having a developed shape of the terminals and arranged in a specific direction intersecting the axial direction;
A connecting portion that connects the adjacent terminal development portions to each other in a region between both axial ends thereof, and
Each said terminal expansion | deployment part is a core wire which has the expansion | deployment shape of the electrical connection part expansion | deployment part with the expansion | deployment shape of the electrical connection part electrically connected with the other party terminal, and the core wire crimping | crimping part crimped | bonded to the core line part of a covered wire A crimping portion developing portion, and a covering crimping portion developing portion having a developed shape of a covering crimping portion to be crimped to the insulating coating portion of the coated electric wire,
One of the covering crimping portion developing portion and the connecting portion has a positioning hole for positioning the terminal expanding portion by inserting a positioning pin when a terminal is formed from the terminal expanding portion,
The other of the covering crimping portion developing portion and the connecting portion is capable of feeding the terminal along the specific direction to the crimping portion for the covered electric wire by moving in the specific direction with the feeding claw of the crimping machine entering. With possible feed holes,
The feed hole has a shape different from that of the positioning hole and has a shape into which the feed claw can enter. A step of punching out the terminal original plate according to claim 3 from a metal plate;
And a step of forming the terminal by inserting a positioning pin into the positioning hole to position the terminal expanding portion and then bending the terminal expanding portion. In the step of forming the feed holes, and the downstream side in the transport direction of the edge of the terminal to which the feed pawl as the hole abuts when sending the terminal, and a feeding direction upstream side of the edge portion of the front SL terminal The manufacturing method of the continuous terminal of Claim 1 or 2 which forms the hole for a feed to have.   6. The method of manufacturing a continuous terminal according to claim 5, wherein in the step of forming the feed hole, an edge portion on the downstream side in the feed direction of the feed hole is formed in a straight line extending in a direction orthogonal to the specific direction. . In the step of forming the feed holes, forming the feed holes in the long hole shape along the specific direction, producing continuous terminal according to claim 1, any one of 5及beauty 6 Method. In the step of forming the feed hole, both edges of the feed hole in a direction orthogonal to the specific direction gradually approach each other as the terminal moves from the upstream side to the downstream side in the feed direction. method for producing a continuous terminal according to any one of to claim 1, 2, and 5-7 formed. A continuous terminal made by the method for producing a continuous terminal according to any one of claims 1, 2 and 4-8,
Integrally having a plurality of terminals arranged in the specific direction;
The said continuous terminal is mutually connected in the area | region between those axial ends, and the continuous terminal.

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