JP6240796B2 - Core wire processing preparation device - Google Patents

Description

  The present invention relates to a core wire processing preparation device for a multi-core cable in which a core wire without twisting or twisting is removed in a bundle shape by removing the outer coating at the tip.

  As a pre-stage preparation device for processing a multi-core cable, for example, “coated wire alignment / extraction device” disclosed in Patent Document 1 below and “core wire supply device of core wire arranging device” disclosed in Patent Document 2 are disclosed. There is. In the disclosed technique of Patent Document 1, the coated wire is planarly aligned with the slit groove of the magazine to detect the position of the coated wire take-out side end, and the covered wire is taken out with a pin that moves based on the detected data. Configure as follows. Thereby, even if the covered wires accommodated in the magazine are arranged in a zigzag manner, the covered wires can be surely taken out from the magazine.

  Further, in the disclosed technique of Patent Document 2, the holding groove formed on the upper end side is pushed up by the endless belt that is slidably contacted with the core wire pushed from the lower end side into the core wire supply groove formed in the core wire insertion block. It is configured to hold the core wire inside. This prevents clogging in the groove due to deformation of the core wire, and allows each core wire to be inserted and held in the holding groove.

JP-A-6-215849 Japanese Utility Model Publication No. 5-77889

  In general, a multicore cable is configured by bundling a plurality of twisted pairs in which a pair of wires are twisted, as disclosed in the section “Prior Art” of Patent Document 1. Therefore, even if these are solved with a tool or the like and the twist is removed, the intersection or entanglement between the core wires is likely to remain. Therefore, in the automation technique, it is not easy to align the core wires of the multicore cable in a plane.

  For example, Patent Document 1 discloses an automation technique for the process of taking out the covered wire, but does not mention anything about the process of aligning the covered wire planarly with the slit groove of the magazine. Also, in Patent Document 2, nothing is disclosed about a technique for supplying a plurality of core wires (core wires) to the core wire supply grooves in order.

  The present invention has been made in order to solve the above-described problems. The purpose of the present invention is to set a multi-core cable in which a plurality of core wires that are not twisted or twisted are exposed to the apparatus, and then to the core wire processing machine. It is another object of the present invention to provide a core wire processing preparation device capable of automating the process until removal.

  In order to achieve the above object, the technical means of claim 1 described in claims is adopted. According to this means, the take-out guide controlled by the controller can take out the outermost core wire located on the side of one of the plurality of core wires collected between the first pin and the second pin. A gap can be formed, and a guide passage for guiding the core wire taken out in the take-out gap in a predetermined direction can be formed. The alignment guide sandwiches a plurality of core wires from both sides of the multi-core cable in the axial direction so that they do not overlap with each other at an interval that is less than twice the outer diameter of the core wires and wider than the outer diameter. Protrusions that can enter between the core wires are provided in the vicinity of the core wires. And since the cable holder is controlled by the controller to rotate the multi-core cable in the direction in which the outermost core wire moves to the take-out gap, for example, even if the core wire is not pushed with a pin or the like, The core wire can be taken out and moved to the clearance. After the outermost core wire is moved to the take-out gap, the alignment guide is controlled to narrow the interval between the alignment guides and push the core wire inside the outermost position core wire back to the opposite side of the take-out gap by the convex portion. This prevents the core wire inside the outermost core wire from moving to the take-out gap. Thereafter, the take-out guide is controlled to form a guide passage, and the feeding mechanism is controlled so as to push out the core wire moved to the guide passage in a predetermined direction. Thereby, one core wire can be taken out from the plurality of core wires collected between the first pin and the second pin. In the automation technology, one core wire can be taken out from a plurality of core wires of the multi-core cable.

  Further, the technical means of claim 2 described in claims is adopted. According to this means, the controller controls the rotation mechanism to rotate the multi-core cable in a direction in which the inner core wire returns when the inner core wire is pushed back from the outermost core wire by the convex portion. This makes it possible to more reliably prevent the inner core wire from moving to the take-out gap with the simple operation of rotating the multi-core cable in the direction in which the inner core wire returns. Become.

  According to the present invention, it is possible to automate the process from setting a multi-core cable with a plurality of core wires that are not twisted or twisted to the apparatus, and then loading and unloading the cable into a core wire processing machine.

It is a perspective view (perspective view in a split process) which shows the composition outline of the core wire processing preparation device concerning the embodiment of the present invention. It is a perspective view which shows the structure of a cable holding part and a split mechanism part in a split process, and the positional relationship of both. It is a figure which shows the structure of a cable holding part. It is a figure which shows the structure of a split mechanism part. It is explanatory drawing which shows the operation example of a split mechanism part in a split process. It is explanatory drawing which shows typically the operation example of a split mechanism part. It is a flowchart which shows the example of the split process performed by the control part. It is a figure which shows the structure of the alignment mechanism part. It is explanatory drawing which shows the operation example of the alignment mechanism part. It is a perspective view (perspective view in a taking-out process and a length measurement process) which shows the composition outline of a core wire processing preparation device. It is a perspective view which shows the structure of the taking-out mechanism part. It is a figure which shows the structure of an EW guide. It is a perspective view which shows the positional relationship of a cable holding part, an alignment mechanism part, and a taking-out mechanism part in a taking-out process. It is a figure which shows the positional relationship of the hold sleeve of a cable holding part, a C-type guide, and an EW guide in an extraction process. It is a flowchart which shows the example of the taking-out process performed by a control part. It is explanatory drawing which shows the operation example of the taking-out mechanism part etc. in the taking-out process. It is explanatory drawing ((D)-(F)) following FIG.16 (C). It is explanatory drawing ((G)-(I)) following FIG.17 (F). It is a perspective view which shows the structure of a cable holding | maintenance part, an alignment mechanism part, a length measurement mechanism part, and these positional relationships in a length measurement process. It is explanatory drawing which shows the operation example of the length measurement mechanism part in a length measurement process. It is a perspective view which shows the positional relationship and operation example of a cable holding part, an alignment mechanism part, and a length measurement mechanism part in a length measurement process. It is a flowchart which shows the example of the length measurement straightening process performed by a control part. It is a figure which shows the operation example of the length measurement mechanism part in a length measurement process. It is a top view explaining the example of a series of operations by the core wire processing preparation device. It is a perspective view (perspective view in a preparatory process) which shows the composition outline of a core wire processing preparation device. It is a flowchart which shows the example of the injection | throwing-in / out process with respect to the processing machine performed by the control part. It is explanatory drawing which shows the whole structure of a core wire processing preparation apparatus. It is explanatory drawing which shows the example of a split process. It is explanatory drawing which shows the operation example of the alignment mechanism part. It is explanatory drawing which shows the example of a taking-out process. It is explanatory drawing which shows the example of a length measurement process. It is explanatory drawing which shows the example of a processing machine injection | throwing-in / out process.

  Hereinafter, an embodiment of a core wire processing preparation device of the present invention will be described with reference to the drawings. The core wire processing preparation device (hereinafter referred to as “the present device”) of this embodiment takes out one core wire at a time from a multi-core cable from which the outer sheath of the tip has been removed and the core wire is exposed, and puts it into a processing machine. A series of processes until the core wire is taken out from the processing machine is automated.

  First, an outline of the configuration of the apparatus 1 will be described with reference to FIGS. 1 and 10. These drawings are different in that the rotation position of the turntable 13 is different. Further, when coordinate axes (X axis, Y axis, Z axis) are displayed in each figure, the axis names of the coordinates described in the figure are simply referred to as “X axis”, “ Sometimes referred to as “Y-axis” or “Z-axis”.

<Outline of the configuration of the device>
As shown in FIGS. 1 and 10, the apparatus 1 includes a cable holding unit 2, a split mechanism unit 3, an alignment mechanism unit 4, a take-out mechanism unit 5, a sending mechanism unit 6, a length measuring mechanism unit 7, and a retracting mechanism unit 8. And a control unit 9. These are mainly provided on the base 11, and the cable holding part 2, the alignment mechanism part 4, the feeding mechanism part 6 and the length measuring mechanism part 7 are rotating on the base table 12. Located on the table 13. The reason why these are rotated by the rotary table 13 will be described later.

  As shown in FIG. 27 to be referred to later, the base 11 is fixed on a device frame (not shown). The take-out mechanism unit 5 and the retracting mechanism unit 8 not shown in FIG. 1 are provided in the apparatus frame, that is, under the base 11, and as shown in FIG. 10, the rotary table 13 is rotated by 45 degrees. In some cases, these are configured to rise through the notch 11 a and appear on the base 11. Also, the control unit 9 is provided not on the base 11 but on the side of the apparatus frame as shown in FIG.

  Each of these devices is supplied with driving power from a power supply device (not shown), and each operation is controlled by the control unit 9. Therefore, it should be noted that although not specifically shown in FIGS. 1 and 10, a power line and a control line are connected to each device. Note that power supply lines and control lines connected to the cable holding unit 2 and the like provided on the rotary table 13 are laid in the harness holder 17. The harness holder 17 is a structure that moves in a plane as the turntable 13 rotates, and is placed on the rack 18.

  The base table 12 is positioned below the rotary table 13 and is configured to be movable on the guide rail 15 by a drive mechanism (not shown). In the present apparatus 1, two guide rails 15 are laid toward the processing apparatus base 19 adjacent to the base 11. Therefore, in addition to the rotation by the rotary table 13, the cable holding unit 2 and the like provided on the rotary table 13 also move in the direction of the processing apparatus table 19 (the arrow direction of the X axis in the coordinate axis display shown in FIG. 1).

  The processing device table 19 is provided adjacent to the base 11. The processing device base 19 is a base for fixing a processing machine 200 that processes the core wire of the multi-core cable 100. In the present embodiment, the processing machine 200 is, for example, a crimping device that crimps a terminal or the like to the core wire, but is not particularly limited as long as it is a device that processes the core wire of a multicore cable. In addition, the code | symbol 201 represented by FIG.1 and FIG.10 shows the insertion port of the processing machine 200 which throws in a core wire at the time of a process.

<Cable holding part, split mechanism part>
Next, the cable holding part 2 and the split mechanism part 3 will be described with reference to FIGS. First, the configuration of the cable holding unit 2 will be described with reference to FIGS. 2 and 3. The cable holding unit 2 is provided on the turntable 13, and the position on the base 11 varies as the turntable 13 rotates. 2 shows a state in which the rotary table 13 is rotated 90 degrees clockwise with respect to the preparation position. In this state, the cable holding unit 2 faces the split mechanism unit 3 ( (See FIG. 1).

  As shown in FIG. 2, the cable holding unit 2 is a device that holds the multi-core cable 100 so as to be capable of rotational driving, and includes a holding unit and a drive unit 29. The holding unit is housed in a rectangular box-like case 21 except for the hold sleeve 28. The drive unit 29 is a drive unit that houses a motor (not shown), a reduction gear connected to the output shaft, and the like. The motor is configured to be able to rotate forward and backward and is rotationally controlled by a control signal input from a control unit 9 such as a sequencer. The output of the drive unit 29 is input to the case 21 of the holding unit via the drive shaft 24.

  FIG. 3 shows the configuration inside the case 21 of the holding unit. 3A is a perspective view of the holding unit in a state where the case 21 is opened, and FIG. 3B is a cross-sectional view in which the roller 25 is cut in the direction of the roller diameter. ing.

  As shown in FIG. 3A, the case 21 is configured to be split into an upper case 21a and a lower case 21b in the vertical direction, and the multi-core cable 100 held along the longitudinal direction can pass therethrough. Thus, an input hole 21c and an output hole 21d are formed on both sides. The upper case 21a and the lower case 21b are connected via a hinge 22 so as to be openable and closable, and a clasp portion that can lock both the upper and lower cases 21a and 21b in a closed state is also provided. In the present embodiment, the case 21 is divided into upper and lower parts in this way, so that the multicore cable 100 can be easily and easily set.

  A cylindrical hold sleeve 28 communicating with the output hole 21d is attached to the side wall where the output hole 21d is formed. The hold sleeve 28 has a cylindrical portion whose inner diameter is set to be slightly larger than the outer diameter of the multi-core cable 100, and a disk that is formed on one end side communicating with the output hole 21d and can be attached to the case 21. And a shape portion. In the present embodiment, since the case 21 is configured to be split into two parts, the hold sleeve 28 is also configured to be split into two in the axial direction accordingly, that is, vertically split.

  The other end side of the hold sleeve 28 is formed in a thin cylindrical shape whose outer diameter is set smaller than the cylindrical shape on the one end side without changing the inner diameter. As shown in FIG. 2, a bundle-like core wire 102 protrudes from the other end side, and an operation is performed on the core wire 103 by the alignment mechanism unit 4 and the take-out mechanism unit 5. Therefore, the other end side of the hold sleeve 28 is set to an outer diameter that does not hinder such operation. On the other hand, one end side of the hold sleeve 28 is set to have a thickness and an outer diameter that can secure a mechanical strength that can sufficiently withstand pressing and the like during the split operation by the split mechanism unit 3.

  As shown in FIG. 3B, a drive shaft 24 is rotatably supported on the lower case 21b by a bearing (not shown), and the driving force input from the drive unit 29 is connected to the drive shaft 24. The drive gear 23 and the belt 27 can be transmitted to the two upper rollers 25. The two rollers 25 are provided in the lower case 21b, and the multi-core cable 100 is rotatably held by the three rollers 25 together with the roller 25 rotatably provided in the upper case 21a. The outer peripheral surface of the roller 25 is covered with a rubber-based resin.

  By configuring the cable holding portion 2 in this way, when the multi-core cable 100 is set in the holding unit with the upper case 21a opened and the upper case 21a is closed, the multi-core cable 100 is rotatably held. Is done. Further, when the driving force by the driving unit 29 is input from the drive shaft 24, the driving force is transmitted to the roller shaft 26 via the belt 27, so that the two rollers 25 of the lower case 21b rotate and the multi-core cable is rotated. 100 is rotated, and the roller 25 of the upper case 21a is rotated in accordance with the rotation of the multi-core cable 100. Thereby, it becomes possible to rotate (rotate) the multi-core cable 100 stably.

  Note that the multi-core cable 100 set in the cable holding unit 2 has a plurality of core wires 103 exposed by removing the outer covering 101 of the front end 100a by a previous process (for example, a preparation process), and the rear end 100b side is appropriate. It is cut with a long length. Since the plurality of core wires 103 are formed in advance in a substantially linear shape without twisting or twisting by a tool or jig (not shown), the tip 100a of the multicore cable 100 shown in FIG. A bundle is formed (reference numeral 102). In addition, this is only an example of drawing representation, and if it is the core wire 103 from which the twist and twist are removed, it does not necessarily need to be bundled together.

  Next, the structure of the split mechanism part 3 is demonstrated based on FIG. 2 and FIG. The split mechanism unit 3 is provided on the base 11 (see FIG. 1). Therefore, the position of the split mechanism unit 3 does not fluctuate on the base 11.

  As shown in FIG. 2, the split mechanism unit 3 is a device that collects a bundle of core wires of the multicore cable 100 held by the cable holding unit 2 in a fan shape in a state of being planarly aligned. The split mechanism part 3 is mainly configured by a slide unit 31c provided on the mechanism part plate 31a, a drive motor 32a, a pusher 33, a pusher guide 34, and the like provided on the slide plate 31b. The slide unit 31 c is a drive mechanism that linearly moves a slider (not shown), and the amount of movement is controlled by a control signal input from the control unit 9. In this embodiment, the slide plate 31b is attached to this slider, so that the slide plate 31b can be moved in the Y-axis direction. The stopper 31d abuts on the slide plate 31b and restricts the movement of the sub plate 31e beyond a preset range.

  A drive motor 32a, a pusher 33, a pusher guide 34, and the like are provided on the slide plate 31b. The drive motor 32a is, for example, a stepping motor or a servo motor, and the rotation of the drive motor 32a is controlled by a control signal input from the control unit 9 so that a driving force for rotating the pusher guide 34 can be generated. The output of the drive motor 32a is transmitted to the pusher guide 34 via the drive gear 32b, the drive shaft 32c, the belt 32d, and the like. In the present embodiment, the pusher 33, the pusher guide 34, and the like are provided on the sub plate 31e attached to the slide plate 31b.

  FIG. 4 shows the configuration of the pusher 33, the pusher guide 34, and the like. 4A is a cross-sectional view taken along the axial direction of the pusher 33, FIG. 4B is a side view of the distal end portion of the pusher 33, and FIG. 4C is a distal end portion of the pusher 33. Are respectively shown in front views.

  As shown in FIG. 4A, the pusher 33 is a metal round bar whose tip 33a is processed into a conical shape, and a male screw is formed at the rear end 33b. The diameter on the distal end portion 33a side is set, for example, substantially the same as the outer diameter of the multicore cable 100, and the diameter of the rear end portion 33b is set smaller than that on the distal end portion 33a side. As will be described later, the pusher 33 is urged by a compression coil spring (hereinafter referred to as “spring”) 39 provided on the rear end portion 33 b side so as to protrude from the pusher guide 34. For this reason, in the present embodiment, a step portion is provided in the intermediate portion 33 c to enable contact with one end side of the spring 39. The pusher 33 may be, for example, a square bar having a quadrangular or polygonal cross-sectional shape as long as the tip 33a is a rod-shaped body having a tapered cone shape. The tip 33a in this case can take a pyramid shape or a cone shape.

  The pusher guide 34 is a cylindrical member that covers the outer periphery of the pusher 33 on the distal end portion 33a side in a cylindrical shape. The pusher guide 34 has an inner diameter that is set slightly larger than the outer diameter on the distal end portion 33a side of the pusher 33, and will be described later. And an outer diameter capable of securing a thickness capable of holding the moving pin 35b. The tip 33a of the pusher 33 protrudes from the tip 34a. The moving pin 35 b is formed in an L shape, and most of the moving pin 35 b is accommodated in the pusher guide 34, and protrudes radially outward so that the tip rises from the pusher guide 34. Since the moving pin 35 b is fixed to the pusher guide 34, the position of the moving pin 35 b varies as the pusher guide 34 rotates. A large-diameter portion 34 b is formed on the rear end side of the pusher guide 34, and is configured to be attachable to the joint portion 37 a of the rotating pipe 37.

  The pusher guide 34 is covered with a tip housing 36a having a hollow truncated cone shape except for both ends. A rod-like fixing pin 35a extending toward the distal end portion 34a along the outer peripheral surface of the pusher guide 34 is fixed to the tapered distal end side of the distal end housing 36a. A rear end housing 36b is connected to the base side of the front end housing 36a, and a pusher guide 34 and a rotating pipe 37 are connected in the rear end housing 36b.

  The fixing pin 35a has a thickness set to, for example, the outer diameter of the core wire 103, and the length slightly protrudes from the distal end portion 34a of the pusher guide 34 (than the protruding amount of the moving pin 35b). Small). As shown in FIGS. 4B and 4C, the moving pin 35b provided on the pusher guide 34 protrudes radially outward, so that the vicinity of the position overlapping the fixed pin 35a fixed to the tip housing 36a. Then both can touch. Therefore, the pusher guide 34 rotates in a range excluding the position where the pusher guide 34 is restricted by the fixing pin 35a and is in contact with the fixing pin 35a.

  In the present embodiment, the moving pin 35b positioned radially inward of the fixed pin 35a is provided in the rotatable pusher guide 34 so that the moving pin 35b can rotate together with the pusher guide 34. On the contrary, a mechanism capable of rotating the outer periphery of the pusher guide 34 is provided on the outer periphery of the pusher guide 34, and a moving pin 35b is attached to the pusher guide 34. The fixing pin 35a is fixed to the pusher guide 34 radially inward of the moving pin 35b. May be. In this case, the pusher guide 34 may be fixed so as not to rotate, or may be rotated.

  The rotating pipe 37 is a cylindrical member that covers the outer periphery of the pusher 33 on the side of the intermediate portion 33c and the rear end portion 33b in a cylindrical shape, and receives a driving force from a drive gear 32b provided substantially in the center in the axial direction to receive a pusher guide. 34. A joint 37a that can be attached to the large-diameter portion 34b of the pusher guide 34 is formed at one end of the rotating pipe 37, and a through-hole through which the rear end 33b of the pusher 33 can pass is formed at the other end. It is covered with a cap 37b. The inner diameter of the rotating pipe 37 is set to be slightly larger than the outer diameter of the spring 39, and the spring 39 that has passed through the rear end portion 33 b of the pusher 33 is inserted into the rotating pipe 37.

  The other end side of the spring 39 inserted into the rotating pipe 37 abuts against the inner bottom portion of the cap 37b, so that the larger the protruding amount of the rear end portion 33b protruding from the cap 37b, the more the spring 39 is compressed. Energizing power increases. That is, it is possible to arbitrarily set the urging force of the spring 39 that urges the pusher 33 by adjusting the protruding amount by the nut 33d screwed into the male screw of the rear end portion 33b. The pressure applied by the spring 39 depends on the number of core wires 103 included in the multicore cable 100, the wire diameter, and the like, and thus is appropriately set according to the type of the multicore cable 100.

  Both ends of the rotating pipe 37 are rotatably supported by the sub plate 31e by two bearing portions 38 fixed to the sub plate 31e. The bearing portion 38 located on the pusher 33 side is connected to the front end housing 36a via the rear end housing 36b. Thereby, the front end housing 36a covering the pusher guide 34 is supported by the sub plate 31e via the rear end housing 36b and the bearing portion 38.

  In the split mechanism portion 3 configured as described above, the multi-core cable 100 in which the distal end portion 33a of the pusher 33 is opposed to the distal end 100a of the multi-core cable 100 and the pusher 33 is held by the cable holding portion 2 in the split process. The positional relationship with the cable holding portion 2 is set so as to be coaxial with the axis J. For example, as shown in FIG. 5 (A) and FIG. 6 (A), both face each other. When the slide plate 31b moves in the direction of the cable holding unit 2 (in the direction of the Y-axis arrow in the coordinate axis display shown in FIG. 5) by the control of the slide unit 31c, the tip 33a of the pusher 33 eventually becomes a bundle of multi-core cables 100. In contact with the core wire 102 (FIG. 6B). When the slide plate 31b further moves in the Y-axis direction, the distal end portion 33a is inserted into the bundled core wire 102, and the core wire 103 is expanded in the shape of an umbrella. As shown in FIG. 6 (A), in many of the multicore cables 100, since a plurality of core wires 103 are arranged around the axis J, the top of the tip 33a is brought into pressure contact with the center. As shown in FIG. 5 (B) and FIG. 6 (C), a plurality of core wires 103 can be expanded in the shape of an umbrella. After a plurality of core wires 103 are gathered in a fan shape and delivered to the split mechanism 3 by a core wire gathering process described later, the split mechanism portion 3 moves backward and leaves the cable holding portion 2.

  A moving mechanism corresponding to the slide plate 31b and the slider unit 31c that can move in the Y-axis direction as described above is provided, and the cable holding unit 2 is attached on the moving mechanism to approach or separate from the fixed split mechanism 3. You may move the cable holding part 2 so that it may. Further, both the cable holding unit 2 and the split mechanism 3 may be configured to be movable in the Y-axis direction so that the two approaches or separate from each other.

  Here, an example of the control process (split process) by the control unit 9 in the split process will be described with reference to FIGS. A typical example of the control unit 9 is a sequencer, and the split processing shown in FIG. 7 is programmed in advance and loaded into the memory of the control unit 9.

  As shown in FIG. 7, in the split process, after the predetermined preparation process such as setting the cable holding unit 2 and the split mechanism unit 3 at a predetermined origin position (S101), the drive motor 32a, the pusher 33, and the pusher described above are performed. The split slide unit 31c provided with the split mechanism such as the guide 34 is advanced in the direction of the cable holding portion 2 (the arrow direction of the Y axis shown in FIG. 5) as shown in FIG. 6A (S103, advance of the split mechanism) processing). Next, it is determined whether or not the core wire 103 is overlapped (S105, core wire overlap detection). The “overlap of the core wires 103” refers to a state where the core wires 103 are three-dimensionally overlapped and are not aligned in a plane. This determination is made based on, for example, the movement position of the slide plate 31b. That is, the position information (for example, the value of the address encoder (position sensor) output from the slide unit 31c) reached by the slide plate 31b when the core wires 103 are arranged in a plane is used as the type of the multi-core cable 100. It is acquired by a trial, adjustment, or the like according to the setting, and preset (stored) in the control unit 9 to determine whether or not the slide plate 31b has reached the position. Therefore, actually, even when the core wires 103 do not overlap three-dimensionally, “overlap of the core wires 103” may be detected in step S105. For example, in the case of FIGS. 6A and 6B, “overlap of core wire 103” is detected (S105; present).

  When “overlap of core wires 103” is detected, it is subsequently determined whether or not the position of the slide plate 31b has changed (S107, detection of position change). That is, in the case shown in FIGS. 6A and 6B, the distal end portion 33a of the pusher 33 does not press the base portions of the plurality of core wires 103. Therefore, since the position of the slide plate 31b has changed from the previous position, a change in the position is detected (S107; present), and the slide plate 31b is continuously advanced (S103). As a result, the tip 33a of the pusher 33 is further inserted into the bundled core wire 102 (FIG. 6C). On the other hand, when the distal end portion 33a presses the base portions of the plurality of core wires 103, the position of the slide plate 31b does not change compared to the previous position (S107; none). That is, in this case, since the slide plate 31b is stopped although the position preset (stored) in the control unit 9 has not been reached, there is a high possibility that the core wires 103 are three-dimensionally overlapped. . Accordingly, in such a case, the multicore cable 100 is then rotated (or rotated) (S109, cable rotation processing).

  The multi-core cable 100 is rotated (or rotated) by the cable holding unit 2. Specifically, for example, the drive motor is rotated 180 degrees in the normal rotation direction with respect to the drive unit 29 of the cable holding unit 2, then rotated 180 degrees in the reverse rotation direction, and this normal rotation and reverse rotation are repeated twice. . Thereby, the three-dimensional overlap of the core wire 103 is eliminated, and the core wire 103 can be aligned in a plane. Note that the rotation angle in the forward and reverse directions and the number of repetitions of such rotation control depend on the number of core wires 103 included in the multicore cable 100, the wire diameter, and the like. Is set as appropriate. When the cable rotation process is finished, the slide plate 31b is continuously advanced (S103). Thereby, when the three-dimensional overlap of the core wire 103 is eliminated, the moving position is also changed because the slide plate 31b moves.

  The multi-core cable 100 held by the cable holding unit 2 is held at a mechanical strength that can sufficiently withstand the pressing by the split mechanism unit 3 so that the periphery of the tip 100a is not bent or bent by the hold sleeve 28. . Therefore, as the movement of the slide plate 31b progresses, the tip 33a is pressed against the base portion of the plurality of core wires 103 and pushed back, so when the force exceeds the biasing force of the spring 39 biasing the pusher 33, The pusher 33 is pushed back in the direction of the pusher guide 34, and the distal end portion 33 a of the pusher 33 is inserted into the pusher guide 34 (reference numeral 33 a ′ shown in FIG. 4A), and the rear end portion 33 b further extends from the rotating pipe 37. It protrudes (reference numeral 33b ′ shown in FIG. 4A).

  As a result, the plurality of core wires 103 are further expanded and radially formed as shown in FIG. 6 (D) by the tip portions 34a of the pusher guide 34 coming into contact with the plurality of core wires 103 expanded in the shape of an umbrella. spread. At this time, when the slide plate 31b has reached the position preset (stored) in the control unit 9, the overlapping of the core wires is not detected (S105; not), and then the plurality of core wires 103 are gathered together. (S111, core line gathering process).

  The core line gathering process is performed by rotating the pusher guide 34. That is, the pusher guide 34 is provided with a moving pin 35b having a slightly protruding tip rather than the fixed pin 35a located on the outer peripheral surface thereof. Therefore, as shown in FIG. 6D, when the plurality of core wires 103 are aligned in a plane, the tips of the pins 35a and 35b are pressed by pressing the tips 34a of the pusher guide 34. It is inserted between the plurality of core wires 103. Since the tip of the moving pin 35b protrudes from the fixed pin 35a, the moving pin 35b is inserted between the core wires 103 deeper than the fixed pin 35a. In this state, for example, when the pusher guide 34 rotates in the clockwise direction, the moving pin 35b also moves in the circumferential direction clockwise. As a result, as shown in FIG. 6E, the core wires 103j, 103i, 103h and the like positioned in the clockwise direction with respect to the moving pin 35b are pushed by the moving pin 35b along with the movement of the moving pin 35b. Move around. For example, the pusher guide 34 continues to rotate until it rotates a predetermined angle from the start position, and stops rotating when the angle reaches that angle. In this embodiment, for example, the rotation is stopped by 170 degrees (reference numeral 35b 'shown in FIGS. 4B and 4C). Thereby, the plurality of core wires 103a to 103j aligned in a plane can be gathered in a fan shape within a range (for example, about 190 degrees) between the fixed pin 35a and the moving pin 35b. The predetermined angle from the start position depends on the number of core wires 103 included in the multicore cable 100, the wire diameter, and the like, and is thus set as appropriate according to the type of the multicore cable 100.

  In addition, when a rotatable mechanism with a moving pin 35b is provided on the outer periphery of the pusher guide 34 and the fixing pin 35a is fixed to the pusher guide 34 radially inward of the moving pin 35b, the moving pin 35b The rotation mechanism may be controlled so that the plurality of core wires 103 are gathered together with the fixing pin 35a in the same manner as described above by rotating the rotation mechanism to which is attached. In addition to the rotating mechanism, the radially inner pusher guide 34 may be rotated. As a result, both the fixed pin 35a and the moving pin 35b rotate. Therefore, when the rotational directions of both the pins 35a and 35b are opposite to each other, a plurality of core wires can be obtained in a shorter time than when only one of the pins is rotated. 103 can be collected and can be collected at an arbitrary position.

<Alignment mechanism part>
Next, the alignment mechanism unit 4 will be described with reference to FIGS. 1 and 8 to 10. First, the configuration of the alignment mechanism unit 4 will be described with reference to FIGS. 1 and 8. FIG. 8A is a perspective view illustrating the configuration of the alignment mechanism unit 4, and FIGS. 8B to 8E are explanatory diagrams illustrating a configuration example of the C-type guide 44 configuring the alignment mechanism unit 4. . As shown in FIG. 1, the alignment mechanism unit 4 is provided on the rotary table 13, and the radial direction of the multi-core cable 100 held by the cable holding unit 2 (on the axis of the multi-core cable 100). The right plate 45 and the left plate 46, which will be described later, can be interposed from the (perpendicular direction).

  As shown in FIG. 8 (A), the alignment mechanism unit 4 includes the plurality of core wires 103 gathered together in a fan shape by the split mechanism unit 3 in the splitting process from both sides, and maintaining the planar alignment. It is an apparatus provided to the take-out mechanism unit 5 in the (take-out step). The alignment mechanism unit 4 mainly includes a slide unit 41, a robot unit 43 provided on the slide plate 42, robot arms 43a and 43b, a C-type guide 44, and the like. The slide unit 41 is a drive mechanism that linearly moves a slider (not shown), and the amount of movement is controlled by a control signal input from the control unit 9. In the present embodiment, the slide plate 42 is attached to the slider, so that the slide plate 42 can be moved in a direction orthogonal to the multicore cable 100 held by the cable holding unit 2.

  On the slide plate 42, a robot unit 43 and the like are provided. The robot unit 43 includes two robot arms 43 a and 43 b that can move in parallel with each other, and the opening and closing of the arms is controlled by a control signal input from the control unit 9. A C-type guide 44 is attached to the tips of the robot arms 43a and 43b. The C-type guide 44 includes a right plate 45 and a left plate 46, and the left and right shapes are different. In the present embodiment, the right plate 45 is attached to the right robot arm 43a and the left plate 46 is attached to the left robot arm 43b.

  8 (B) and 8 (C) show a perspective view of the right plate 45, and FIGS. 8 (D) and 8 (E) show a perspective view of the left plate 46. . Therefore, the following description will be made with reference to these figures.

  As shown in FIGS. 8 (A), 8 (B) and 8 (C), the right plate 45 is formed in a strip shape with the tip cut out in a semicircular shape, and is opposed to the left plate 46. On the inner side, a C-shaped convex portion (hereinafter referred to as “C-shaped convex portion”) 45 a having a thick wall thickness is formed along the semicircular cutout. The reason why the tip of the right plate 45 is cut out in a semicircular shape in this way is to contact the hold sleeve 28 from the orthogonal direction with respect to the multi-core cable 100 held by the hold sleeve 28 of the cable holding portion 2. It is because it intervenes without. Further, the reason why the C-shaped convex portion is provided is that the plurality of core wires 103 gathered in a fan shape are securely sandwiched from both sides by sandwiching them with a wire rather than sandwiching them with a surface.

  Further, the light emitted from the optical fiber 47b for the fiber sensor is sent toward the optical fiber 48b of the left plate 46 on the inner upper side of the right plate 45 (in the direction of the arrow of the Z axis in the coordinate display shown in FIG. 1). An upper notch 45b is formed (a dotted line with an arrow shown in FIG. 8A indicates a light transmission direction). Further, a lower notch 45c is formed on the outer lower side of the right plate 45 (in the direction opposite to the Z axis). The lower notch 45c serves as a guide used for the guide passage when the core wire 103 is taken out in cooperation with the take-out mechanism 5 described later. Therefore, the lower cutout 45c is cut out at an angle of 45 degrees with respect to the surface of the right plate 45 in accordance with the shape of the guide passage formed by the EW guide that forms the take-out mechanism 5. The light emitting portion 47 a for the fiber sensor is attached to the upper end of the right plate 45 by a bracket 49.

  As shown in FIGS. 8 (A), 8 (D) and 8 (E), the left plate 46 is also formed in a strip shape with the tip cut out in a semicircular shape, similar to the right plate 45. Further, a C-shaped convex portion 46 a is formed on the inner side facing the right plate 45. The reason why these are formed is the same as that of the right plate 45, and a plurality of core wires 103 are arranged on both sides of the multi-core cable 100 from the orthogonal direction without contacting the pusher guide 34, the fixing pin 35 a, etc. This is to securely pinch.

  Further, an upper notch 46b for receiving light received by the optical fiber 48b for the fiber sensor from the optical fiber 47b of the right plate 45 is formed above the inner side of the left plate 46. Further, an upper convex portion 46c that protrudes in a direction facing the right plate 45 is formed inside the C-shaped convex portion 46a continuously to the upper cutout portion 46b. The upper convex portion 46c plays a role of pushing back the core wire 103 located inside the outermost position in cooperation with the take-out mechanism portion 5 described later. Therefore, the protruding amount of the upper convex portion 46 c is set slightly smaller than the wire diameter of the core wire 103. In addition, a lower convex portion 46 d that protrudes in a direction facing the right plate 45 is formed on the inner lower side of the left plate 46. The lower convex portion 46d abuts on the inner lower side of the right plate 45, thereby preventing the core wire 103 from moving outside so that the core wire 103 sandwiched between the plates 45 and 46 does not come out. . Therefore, the protruding amount of the lower convex portion 46 d is set slightly larger than the wire diameter of the core wire 103. The light receiving portion 48 a for the fiber sensor is attached to the upper end of the left plate 46 by a bracket 49.

  The fiber sensor detects whether or not the core wire 103 has come out of the C-shaped guide 44 by detecting light blocking or light intensity outside the C-shaped convex portions 45a and 46a. In the extraction step, data for determining whether or not the outermost core wire 103 has entered the extraction gap Sa of the EW guide 55 is output to the control unit 9.

  By configuring the alignment mechanism unit 4 in this manner, as shown in FIG. 9, the multi-core cable 100 held by the cable holding unit 2 approaches from the direction orthogonal to the axis J of the multi-core cable 100. . This movement is performed by the slide unit 41. At this time, the distance between the robot arms 43a and 43b is wide with a margin. FIG. 9A shows a state in which both plates 45 and 46 of the C-shaped guide 44 are sufficiently close to the hold sleeve 28 of the cable holding unit 2 and the pusher guide 34 of the split mechanism unit 3. The plurality of core wires 103 are sandwiched between the plates 45 and 46 at a predetermined pressure. Accordingly, the plurality of core wires 103 gathered in a fan shape by the split mechanism unit 3 can be provided to the take-out mechanism unit 5 in the take-out process while maintaining planar alignment. Extraction can be easily performed.

  Before reaching this state, for example, once the core wire 103 is lightly pinched to the extent that it is in contact with the core wire 103 (for example, the opposing distance between the plates 45 and 46 is set to 2 of the wire diameter of the core wire 103). It may be controlled so as to be sandwiched at a predetermined pressure). Since both the plates 45 and 46 are stopped once in the vicinity of the core wire 103 before being sandwiched at a predetermined pressure, acceleration is not accompanied as compared with a case where such a temporary stop is not performed. Pressurization becomes possible. This prevents the core wire 103 from being scratched in order to prevent the core wire 103 from being sandwiched by excessive pressure. FIG. 9 (B) shows a state after the split mechanism unit 3 is retracted (moved in the direction opposite to the X axis shown in the coordinate display shown in FIG. 9 (B)). 13 rotates 45 degrees counterclockwise from the state shown in FIG. 1 and shifts to a state rotated 45 degrees with respect to the preparation position. This state is illustrated in FIG. In FIG. 10, the alignment mechanism unit 4 is positioned away from the cable holding unit 2, but actually, as will be described below, the alignment mechanism unit 4 has its C-shaped guide 44 held by the cable. The position close to the hold sleeve 28 of the part 2 is maintained (see FIG. 13).

  Further, in the above-described splitting process, when the plurality of core wires 103 are gathered together in a fan shape, the plurality of core wires 103 are lightly sandwiched by the C-shaped guide 44 (for example, the opposing distance between both plates 45 and 46 is the wire diameter of the core wire 103). May be maintained in such a manner that it is sandwiched at an interval that is less than twice that of the wire diameter and wider than the wire diameter. This prevents the core wires 103 from overlapping in a three-dimensional manner when gathering together a plurality of core wires 103, so that the possibility that the core wires 103 overlap and cannot be planarly aligned during gathering can be greatly reduced. .

<Removal mechanism, delivery mechanism>
Next, the take-out mechanism 5 and the delivery mechanism 6 will be described with reference to FIGS. First, the configuration of the take-out mechanism unit 5 will be described with reference to FIGS. 14A is a schematic plan view seen from the direction of the arrow 14A shown in FIG. 13, and FIG. 14B is a schematic view seen from the direction of the arrow 14B shown in FIG. 14A. FIG. 14 (C) is a schematic arrow view seen from the direction of arrow 14C shown in FIG. 14 (A). In FIG. 14, in order to clearly indicate the position and range of the U-shaped portion 57 and the J-shaped portion 58 constituting the EW guide 55, the U-shaped portion 57 and the portion formed integrally therewith are light gray. The colored portion 58 and the portion formed integrally therewith are colored gray.

  The take-out mechanism unit 5 is a device that takes out the core wires 103 one by one from the plurality of core wires 103 gathered in a fan shape provided from the alignment mechanism unit 4 and is used in the take-out process. As shown in FIG. 10, the take-out mechanism unit 5 is provided below the base 11 and rises through the notch 11 a and appears on the base 11 when the rotary table 13 rotates 45 degrees. Therefore, as shown in FIG. 11, the take-out mechanism unit 5 is mainly composed of an elevator unit 52, a robot unit 54, an EW guide 55, and the like. The EW guide 55 is not used when the turntable 13 is rotated 90 degrees during the split process or when it is in the preparation position (0 degrees) during the preparation process. Therefore, the EW guide 55 is retracted under the base 11 in order to avoid contact with the rotary table 13.

  The elevator unit 52 is a drive mechanism that linearly moves the slider, and is attached to the elevator tower 51 that rises in the arrow direction of the Z axis. The amount of movement of the elevator unit 52 is controlled by a control signal input from the control unit 9, and the elevator plate 53 can be moved in the vertical direction by attaching an elevator plate 53 formed in an L shape to the slider. It is configured.

  A robot unit 54 and robot arms 54 a and 54 b that move in the X-axis direction by the robot unit 54 are attached to the XY plane of the elevator plate 53 formed in an L shape. Similarly to the elevator plate 53, the robot arms 54a and 54b are configured by plate portions 54a1 and 54b1 extending in the XY plane and standing portions 54a2 and 54b2 rising from the plate portions in the arrow direction of the Z axis. . A U-shaped portion 57 constituting one of the EW guides 55 is attached to the tip of the standing portion 54a2 of the robot arm 54a via an arm portion 56 and an attachment portion 59. Further, a J-shaped portion 58 constituting the other of the EW guide 55 is attached to the tip of the standing portion 54b2 of the robot arm 54b via an arm portion 56 and an attachment portion 59.

  12A is a perspective view of the EW guide 55 viewed from the arrow direction of the Y axis, FIG. 12B is a perspective view of the EW guide 55 viewed from the counter arrow direction of the Y axis, and FIG. C) is a plan view of the EW guide 55 as viewed from the opposite direction of the Z axis. 12 (D) to 12 (F) are enlarged views of the tip portion of the EW guide 55 shown in FIGS. 12 (A) to 12 (C). From here, it demonstrates, referring FIGS. 12-14. In FIG. 13, the robot arms 54a, 54b and the like are omitted.

  The EW guide 55 includes a U-shaped portion 57 and a J-shaped portion 58. The EW guide 55 is interposed without contacting the hold sleeve 28 from a direction orthogonal to the multicore cable 100 held by the hold sleeve 28 of the cable holding unit 2, and a plurality of core wires held by the C-type guide 44. From 103, one core wire 103 is taken out in cooperation with the delivery mechanism unit 6. Therefore, as shown in FIG. 13 and FIG. 14 (A), it approaches the hold sleeve 28 from the side opposite to the C-type guide 44 described above, that is, from the opposite direction of the X axis. Further, as shown in FIGS. 14B and 14C, since the semicircular cutout portion is formed in the C-shaped guide 44, it is necessary to avoid the range where the hold sleeve 28 exists, so that the EW guide. 55 also forms the U-shaped portion 57 and the J-shaped portion 58.

  The reason why the outer shape of the U-shaped portion 57 and the J-shaped portion 58 is provided with a curved surface instead of a rectangular shape like the C-shaped guide 44 is that the sending stick 63 of the sending mechanism portion 6 will be described later. Moves around the EW guide 55 so as to draw an arc, so that the outer shape of the U-shaped portion 57 and the J-shaped portion 58 is set to a curved surface that draws an arc-shaped curve in accordance with the movement locus.

  As shown in FIG. 12D, the U-shaped portion 57 has a stepped portion 57a formed on one end side of the U-shaped, and the tip 57b is thin. As shown in FIG. 14A, when the EW guide 55 approaches the C-type guide 44, the tip 45t of the right plate 45 of the C-type guide 44 is easily combined with the U-shaped portion 57. (See FIG. 16A). Further, a notch 57c and a notch 57d are formed between one end of the U shape and the other end of the U shape to which the arm portion 56 is connected. As shown in FIG. 14 (A), when the U-shaped portion 57 is combined with the J-shaped portion 58, the notch portion 57c is formed to avoid contact with the protruding portion 58d formed on the J-shaped portion 58. In order to avoid contact with the hold sleeve 28, a notch 57d is formed.

  As shown in FIG. 12 (E), the J-shaped portion 58 is formed in a substantially ¼ arc shape, whereas the U-shaped portion 57 has a substantially ½ arc shape. As will be described later, when the core wire 103 taken out from the C-shaped guide 44 is transferred to the length measuring mechanism unit 7 through the guide passage Sc, the core wire 103 is moved to a broken arrow as shown in FIG. This is to secure a space to escape in the direction. The J-shaped portion 58 also has a stepped portion 58a formed on one end side of the J-shaped, and the tip 58b is thin. This is also because the tip 46t of the left plate 46 of the C-shaped guide 44 can be easily combined with the J-shaped portion 58, as can be seen with reference to FIG. Further, as will be described later, a notch portion 58 c is formed in the J-shaped portion 58 in order to form the extraction gap Sa. As shown in FIG. 12 (F), the protrusion 58d is formed to prevent the core wire 103 taken out into the guide passage Sc from falling down and falling off the EW guide 55 (FIG. 18G ) To FIG. 18 (I)).

  As shown in FIG. 12 (F), the EW guide 55 has a planar shape (in the direction of the arrow opposite to the Z axis) when the U-shaped portion 57 and the J-shaped portion 58 are combined to form the guide passage Sc. The U-shaped portion 57 and the J-shaped portion 58 are formed such that the shape 57 viewed from the side) forms an isosceles triangle αβγ having the stepped portion 57a and the stepped portion 58a as the base α. This is because the hold sleeve 28 of the cable holding unit 2 and the C-shaped guide 44 of the alignment mechanism unit 4 are orthogonal to each other, the axis of the hold sleeve 28 is parallel to the side α, and the core wire 103 taken out is passed. The length measuring plates 77 to 79 of the length measuring mechanism unit 7 are waiting in a positional relationship parallel to the side β, and the direction in which the base table 12 moves toward the processing machine 200 (X-axis direction) is the side γ. And isosceles triangles αβγ are formed based on the fact that they are parallel to each other.

  As shown in FIG. 10, the delivery mechanism unit 6 includes a slide unit 61, a drive unit 63, an arm 65, a delivery stick 67, and the like, and is above the robot arm 43b of the alignment mechanism unit 4 (see FIG. 13). It is provided in a range 60) represented by a two-dot chain line on the robot arm 43b shown. The slide unit 61 is a drive mechanism that linearly moves the slider, and the amount of movement is controlled by a control signal input from the control unit 9. In the present embodiment, the drive unit 63 and the like are attached to the slider so that the drive unit 63 and the like can move in the direction of the C-type guide 44 of the alignment mechanism unit 4. The drive unit 63 is a stepping motor or servo motor controlled by the control unit 9 and is configured such that the tip of the arm 65 rotates in a circle or arc by this rotation. For example, in the coordinate display shown in FIG. 10, a circle or arc corresponding to the outer circumference of the EW guide 55 is drawn on the XZ plane with the Y-axis direction as an axis. A delivery stick 67 extending toward the distal end of the C-shaped guide 44 of the alignment mechanism unit 4 is attached to the distal end of the arm 65. As shown in FIG. 10, the delivery stick 67 is composed of an elongated rod formed in an L shape (see FIGS. 27 to 32).

  When the slide unit 61 and the drive unit 63 are driven by the control signal from the control unit 9, the delivery mechanism unit 6 configured as described above is configured such that the tip of the delivery stick 67 is the U-shaped part 57 or J-shaped part of the EW guide 55. It moves along the outer periphery of 58. Therefore, it becomes possible for the delivery stick 67 to push down the core wire 103 positioned in the guide passage Sc of the EW guide 55 (see FIGS. 18G to 18I).

  Here, with reference to FIGS. 15 to 18, an example of control processing (extraction processing) by the control unit 9 (for example, a sequencer) in the extraction process will be described. 16 to 18, in order to clearly indicate the position and range of the U-shaped portion 57 and the J-shaped portion 58 constituting the EW guide 55, the U-shaped portion 57 and a portion formed integrally therewith are The J-shaped part 58 and the part molded integrally therewith are colored gray. 15 is pre-programmed and loaded into the memory of the control unit 9. Further, the movement of the EW guide 55 (the U-shaped portion 57 and the J-shaped portion 58) described below is caused by the robot arms 54a and 54b of the take-out mechanism portion 5. The movement of the C-type guide 44 (the right plate 45 and the left plate 46) is caused by the robot arms 43a and 43b of the alignment mechanism unit 4.

  As shown in FIG. 15, in the take-out process, as a preparatory process, the U-shape of the EW guide 55 is formed on the right plate 45 and the left plate 46 of the C-type guide 44 sandwiching the plurality of core wires 103a, 103b,. The portion 57 and the J-shaped portion 58 are brought close to each other, the tip 45t of the right plate 45 is placed on the stepped portion 57a of the U-shaped portion 57, and the tip 46t of the left plate 46 is placed on the stepped portion 58a of the J-shaped portion 58. They are combined (S201, FIG. 16 (A)). Next, the EW guide 55 (the U-shaped portion 57 and the J-shaped portion 58) is moved in the arrow direction shown in FIG. 16A while maintaining the combined state of the EW guide 55 and the C-shaped guide 44. (S203, gap formation processing). As a result, as shown in FIG. 16B, the notch portion 58c is provided in the J-shaped portion 58, so that an extraction gap Sa is formed. Subsequently, the left plate 46 of the C-type guide 44 is moved in the arrow direction shown in FIG. 16B (S205, C-type guide opening process). As a result, as shown in FIG. 16 (C), the space between the right plate 45 and the left plate 46 is opened, so that the plurality of core wires 103 that have been sandwiched by the C-shaped guide 44 and restricted in movement until then are Movement within both plates 45 and 46 is possible. Further, the interval between the extraction gaps Sa is also a wider extraction gap Sb.

  Next, the multi-core cable 100 is rotated in the direction of the arrow shown in FIG. 17D by the cable holding unit 2 (S207, core line shift process). That is, among the plurality of core wires 103 positioned between the plates 45 and 46, the entire core wires 103 are moved in the direction of the dotted arrow so that the core wire 103a existing at the outermost position enters the extraction gap Sb. Then, the multicore cable 100 in the hold sleeve 28 is rotated. At this time, in order to determine whether or not the outermost core wire 103a has entered the extraction gap Sb, the core wire 103a is passed through the core wire 103a by referring to the presence / absence of light shielding sent from the fiber sensor, that is, in the extraction gap Sb. It is determined whether it has entered (S209, core wire detection). The multi-core cable 100 is rotated until the core wire 103a enters the take-out gap Sb (S209; No). When the core wire 103a enters the extraction gap Sb (S209; Yes), the C-type guide 44 is then closed (S211, C-type guide closing process). The left plate 46 is moved in the direction of the arrow shown in FIG. As a result, the upper convex portion 46c of the left plate 46 enters between the core wire 103a that has entered the extraction gap Sb and the core wire 103b adjacent thereto, so that the core wire 103a at the outermost position further enters the extraction gap Sb. The adjacent core wire 103b moves by being pushed in the direction of the dotted arrow shown in FIG. As a result, only the core wire 103a located at the outermost position can be reliably moved to the take-out gap Sb. At this time, the multi-core cable 100 is rotated in the direction opposite to the direction of the arrow shown in FIG. 17D by the cable holding portion 2, leaving the core wire 103 a at the outermost position in the take-out gap Sb and other core wires. 103b, 103c, etc. can be moved in the direction of the dotted arrow shown in FIG. Therefore, it is possible to prevent the core wires 103b, 103c and the like from moving in the direction of the take-out gap Sb. Next, the EW guide 55 (the U-shaped part 57 and the J-shaped part 58) is moved in the arrow direction shown in FIG. 17E (S213, core wire extrusion process). As a result, as shown in FIG. 17F, the core wire 103a in the take-out gap Sb is pushed by the tip 57b of the U-shaped portion 57 and moves to the upper notch 46b of the left plate 46.

  Next, only the J-shaped portion 58 is moved in the direction of the arrow shown in FIG. 17F (S215, guide passage formation process). Thereby, a gap is formed between the U-shaped portion 57 and the J-shaped portion 58. That is, as shown in FIG. 18 (G), the guide path Sc is formed in the EW guide 55 and the X-axis direction of the core wire 103a is opened. Further, the slide unit 61 is controlled to move the delivery stick 67 in the arrow direction shown in FIG. 18G (S217, delivery stick insertion process). Accordingly, as shown in FIG. 18 (H), the delivery stick 67 is inserted between the core wire 103a positioned in front of the guide passage Sc and the core wire 103b positioned outermost in the C-shaped guide 44. When the delivery stick 67 is inserted in this way, the drive unit 63 is controlled to rotate the delivery stick 67 in the arrow direction (rotation from above to below) shown in FIG. 18H (S219, delivery stick). Rotation processing). As a result, as shown in FIG. 18 (I), the core wire 103a is pushed down in the guide passage Sc by the delivery stick 67 that rotates downward, and comes into contact with the protrusion 58d of the J-shaped portion 58 and stops. . Since the guide passage Sc extends along the X-axis direction, the core wire 103a that has fallen into the guide passage Sc also maintains the posture along the X-axis direction.

  Thus, in the take-out process, the cable holding part 2, the alignment mechanism part 4, the take-out mechanism part 5 and the delivery mechanism part 6 are controlled by the take-out process, so that the core wire 103a located at the outermost position of the C-type guide 44 is moved to the EW guide. 55 can be taken out into the guide passage Sc. The core wire 103 taken out in the take-out process is transferred to the length measuring mechanism unit 7.

<Length measuring mechanism>
Next, the length measuring mechanism unit 7 will be described with reference to FIGS. First, the configuration of the length measuring mechanism unit 7 will be described with reference to FIGS. In FIGS. 21 and 23, the core wire 103 is colored gray in order to clearly indicate the position and range of the core wire 103. As shown in FIG. 19, the length measuring mechanism unit 7 measures the length of the core wire 103 taken out by the take-out mechanism unit 5 and straightens the shape of the core wire 103 (hereinafter referred to as “straightening”). Used in long processes. As shown in FIG. 19, the length measurement mechanism unit 7 is mainly configured by an elevator tower 71, an elevator unit 72a, a slide unit 73a, a robot 74, length measurement plates 77, 78, 79, and the like. The elevator tower 71 is provided on the rotary table 13. Therefore, the length measuring mechanism unit 7 rotates on the base table 12 by the rotary table 13 together with the cable holding unit 2, the alignment mechanism unit 4, and the delivery mechanism unit 6 described so far.

  The elevator unit 72a is a drive mechanism that linearly moves the slider, and is attached to the elevator tower 71 that rises in the arrow direction of the Z axis. The amount of movement of the elevator unit 72a is controlled by a control signal input from the control unit 9, and an elevator plate 72b formed in an L shape is attached to the slider, so that the elevator plate 72b is moved in the vertical direction (Z-axis). Direction).

  A slide unit 73a is attached to the elevator plate 72b. The slide unit 73 a is a drive mechanism that linearly moves the slider, and the amount of movement is controlled by a control signal input from the control unit 9. In this embodiment, the slide plate 73b is attached to this slider, so that the slide plate 73b can be moved in the X-axis direction as shown in FIGS. 20 (A) and 20 (B). A robot 74 is attached to the slide plate 73b. Robot arms 75 a and 75 b that move in the X-axis direction are attached to the robot 74. The robot arms 75a and 75b are configured to be able to pressurize in the closing direction by both arms 75a and 75b and to move both arms 75a and 75b in the same direction or in the opposite direction in the Y-axis direction. Length measuring arms 76a and 76b are provided at the tips thereof. Length measuring plates 77, 78, 79 are attached to the length measuring arms 76a, 76b.

  As shown in FIG. 20, the length measuring plates 77, 78, and 79 hang in the Z-axis direction from the robot arms 75a and 75b bent in a U-shape through the length measuring arms 76a and 76b. The length measuring plates 77, 78, 79 are made of, for example, an aluminum plate. The length measuring plate 77 composed of one sheet and the length measuring plates 78, 79 composed of two sheets are symmetrical in shape. Is made. For example, as shown in FIGS. 21 and 23, one corner of a vertically long rectangle is formed in a chamfered shape, and the notches are directed toward each other from the opposite direction of the X axis. A single length measuring plate 77 is positioned on the right side, and two length measuring plates 78 and 79 are positioned on the left side. Moreover, the recessed part which can determine the position which pinches | interposes the core wire 103 is formed in the edge part which a right and left length measuring plate opposes.

  The two length measuring plates 78 and 79 are configured such that two plates overlap with a gap in which the one length measuring plate 77 can be interposed. Therefore, as shown in FIG. 23 (D) and FIG. 23 (E), when nothing is interposed between the left and right length measuring plates, one sheet is formed between the two length measuring plates 78 and 79. A length measuring plate 77 can enter. As described above, these length measuring plates are attached to the robot arms 75a and 75b that can be pressurized in the closing direction. Therefore, as shown in FIG. 23 (B) and FIG. 23 (C), when the core wire 103a is interposed between the length measuring plate 77 and the length measuring plates 78/79, between the length measuring plates 78/79. The length measuring plate 77 does not enter. However, as shown in FIGS. 23 (D) and 23 (E), when the core wire 103a is not interposed between the length measuring plate 77 and the length measuring plates 78/79, it is between the length measuring plates 78/79. Length measuring plate 77 enters.

  As shown in FIG. 21, the length measuring mechanism section 7 configured as described above is subjected to a length measuring process, as shown in FIG. 21. With respect to 55, the length measuring mechanism unit 7 is positioned so as to be interposed from the X-axis direction. Accordingly, the single core wire 103a taken out by the take-out mechanism unit 5 from the plurality of core wires 103a, 103b, 103c and the like sandwiched between the C-shaped guides 44 is also guided in the posture along the X-axis direction as described above. Since it falls into Sc, the length measuring mechanism part 7 can receive the fallen core wire 103a as it is with the length measuring plates 77, 78 and 79. Although not shown in FIG. 21, the core wire 103 a that has fallen along the X axis is held down by being held down by the delivery stick 67 of the delivery mechanism unit 6 from above.

  Here, with reference to FIG. 22 and FIG. 23, an example of a control process (length measurement straightening process) by the control unit 9 (for example, a sequencer) in the length measurement process will be described. 22 is programmed in advance and loaded into the memory of the control unit 9. FIG. 23A shows a schematic diagram of an operation example of the length measuring mechanism unit 7 in the length measuring step. FIG. 23B is a schematic diagram showing the length measuring plates 77, 78 and 79 in a state where the core wire 103a is being pressed. Further, FIG. 23C shows the length measuring plates 77, 78 in the same state. -The schematic diagram which looked at 79 from the opposite direction of the Z-axis is illustrated. FIG. 23 (D) is a schematic diagram showing the length measuring plates 77, 78 and 79 in a state immediately after reaching the tip of the core wire 103a, and FIG. 23 (E) further shows the length measuring plate 77 in the same state. , 78 and 79 are shown in a schematic view as seen from the direction of the arrow opposite to the Z axis.

  As shown in FIG. 22, in the length measurement processing, as preparation processing, the elevator unit 72a is controlled so that the core wire 103a that has fallen along the X axis can be sandwiched from both sides, and the length measurement arms 76a, The length measuring plates 77, 78 and 79 located at the tip of 76b are aligned (S301). Next, the length measuring plates 77, 78 and 79 are closed with a predetermined pressure (S303, plate closing process). The applied pressure here is, for example, such that when the length measuring plates 77, 78, and 79 are moved in the axial direction of the core wire 103 while the core wire 103 of the multicore cable 100 is sandwiched between the applied wires, the core wire 103 is straightened. Is the value of

  The position information before moving the length measuring plates 77, 78, 79 by the slide unit 73a and the state information of the length measuring plates 77, 78, 79 are stored (S305, start state storage processing). The position information is, for example, an address counter value by an encoder. Further, the state information of the length measuring plates 77, 78, 79 is, for example, the opening / closing positions and pressure values of the length measuring plates 77, 78, 79. Next, the slide unit 73a is controlled to advance the robot arms 75a and 75b including the length measuring plates 77, 78 and 79 in the arrow direction of the X axis (S307, plate advance processing). Subsequently, the closed state of the length measuring plates 77, 78, 79 is detected (S309, closed change detection), and if it is not different from the state information stored in step S305 (S309; No), the process returns to step S307 to return to the robot arm. 75a and 75b are advanced in the direction of the arrow on the X axis, and are repeated until the closed state changes. For example, as shown in FIG. 23A, the length measuring plates 77 ', 78' and 79 'are sandwiching the middle of the core wire 103a.

  On the other hand, when there is a change in the closed state of the length measuring plates 77, 78, 79 (S309; Yes), the position information and the state information immediately after the detection of the close change are stored (S311, end state). Amnestic processing). The case where there is a change in the closed state is, for example, a case where the length measuring plates 77 ″, 78 ″ and 79 ″ shown in FIG. 23 (A) reach the tip of the core wire 103a. Whether or not it has reached, for example, the core wire 103a that has been clamped so far does not exist between the length measuring plate 77 and the length measuring plates 78 and 79, so that the pressure value that has been pressed fluctuates abruptly. Therefore, it is determined by detecting the pressure change.

  Next, the length of the core wire 103a is obtained by calculation based on the start state information stored in step S305 and the end state information stored in step S311 (S313, length measurement calculation process). For example, the length of the core wire 103a from the start position is obtained by subtracting the encoder value of the start address from the encoder value of the end address. The actual length of the core wire 103a is added to the length from the root of the core wire 103a to the start position. After storing the length of the core wire 103a obtained in step S313, the length measuring plates 77, 78 and 79 are returned to the start position (S315, start position return process). At this time, the length measuring plates 77, 78 and 79 are returned in a sufficiently open state. Thus, once the length measuring plates 77, 78, 79 are returned to the starting position, the core wire 103a is moved to the length measuring plates 77, 78, 79 after the length measuring plates 77, 78, 79 reach the tip of the core wire 103a. This is because the position of the core wire 103a is lost due to separation from the position 79. Therefore, instead of searching for the tip or the like of the core wire 103, the length measuring plates 77, 78 and 79 are returned to the start position where the core wire 103a is surely present. As a result, it is possible to find the core wire 103a without wasteful movement.

  As described above, in the length measurement according to the present embodiment, the core wire 103a is pressed by the length measuring plates 77, 78, and 79 while the length to the tip of the core wire 103a is measured by the length measuring plates 77, 78, and 79. Since the length measuring plates 77, 78 and 79 are moved to the tip of the core wire 103a without changing the length, the core wire 103a can be adjusted. That is, since the wire length is measured and trimmed in one step, there is no need to provide a step of straightening the core wire 103a in the subsequent step. Thereby, the time required for the preparation of the core wire 103 can be shortened. In addition, since it is not necessary to newly provide a straightening device or jig, the equipment cost can be reduced.

  In the length measurement process described above, the length measurement process is performed once for the core wire 103a, but may be performed for the same core wire 103a a plurality of times. Thereby, since a plurality of length measurement data is obtained for one core wire 103a, it is possible to improve the accuracy of the length measurement value. Further, since the single core wire 103a is subjected to a plurality of adjustments, the shape of the core wire 103a can be further straightened.

  In the length measurement process described above, the case of the core wire 103a that is first taken out of the plurality of core wires 103 constituting the multi-core cable 100 has been described as an example. Similarly to the core wire 103a, the length measuring process can be performed on the core wire 103c taken out. In addition, it is not always necessary to perform the length measurement processing by the length measurement process on all the core wires 103 included in the multicore cable 100. For example, when the multicore cable 100 includes ten core wires 103, for example, the first (first), middle (fifth or sixth), and last (10th) length measurement by the length measurement process described above. Perform direct processing. Thereby, since it is not necessary to perform the length measurement process every time, it is possible to further reduce the time required for the preparation of the core wire 103.

<Example of core wire feeding operation to processing machine and example of core wire take-out operation after processing>
In the present apparatus 1, since the multi-core cable 100 to be processed is held by the cable holding unit 2, even if the rotary table 13 is rotated, the multi-core cable 100 can be input to the input port 201 of the processing machine 200. I can't. Therefore, the present apparatus 1 is configured so that the base table 12 positioned between the base 11 and the rotary table 13 can be moved toward the processing machine 200.

  Here, with reference to FIG. 24, the flow of all the steps will be described as an example of a series of operations by the apparatus 1. 24A is a preparation process, FIG. 24B is a split process, FIG. 24C is a take-out process and a length measurement process, and FIG. 24D is a processing machine loading / unloading process. Main devices (cable holding unit 2, split mechanism unit 3, alignment mechanism unit 4, take-out mechanism unit 5, delivery mechanism unit 6, length measuring mechanism unit 7, retraction mechanism unit 8 and the like), base table 12 and rotary table 13 The positional relationship is illustrated. In FIG. 24, “Figure xx” (xx is a drawing number) and its arrow described in a rounded frame are the perspective views in FIGS. 1, 10, 25, and 27 to 32. Indicates the viewpoint and its direction. Moreover, in order to clarify the rotation state of the turntable 13, the turntable 13 is colored gray.

  As shown in FIG. 24A, in the present apparatus 1a in the preparation process, the turntable 13 is located at the preparation position. In this preparation position, the cable holding part 2 is located in a place where the operator can easily access. The preparation process is a process of setting the multi-core cable 100 in the cable holding unit 2, and since this work is performed by an operator, the rotary table 13 is rotated so that the cable holding unit 2 faces the side surface of the apparatus 1. . In the rotary table 13, the preparation position is defined as 0 degree, and the clockwise direction is defined as forward rotation (+) and the counterclockwise direction is defined as reverse rotation (-).

  As shown in FIG. 24 (B), in the apparatus 1b in the split process, the rotary table 13 is positioned at 90 degrees forward rotation from the preparation position. As a result, the cable holding unit 2 is disposed at a position facing the split mechanism unit 3, and the above-described split processing can be performed.

  As shown in FIG. 24C, in the apparatus 1c in the take-out process and the length measurement process, the rotary table 13 is positioned 45 degrees reverse from the position at the time of the split process (45 degrees normal rotation from the preparation position). ing. Thereby, since the moving direction of the length measuring mechanism unit 7 is the X-axis direction, the length measuring mechanism unit 7 faces the direction in which the processing machine 200 can be accessed. At this time, the take-out mechanism 5 and the retracting mechanism 8 rise from the bottom of the base 11 and appear on the base 11 from the notch 11a. Although it cannot be confirmed in this figure, since the guide passage Sc of the take-out mechanism section 5 is also oriented in the X-axis direction, the length measuring mechanism section 7 can easily hold the core wire 103 that falls over the guide path Sc.

  As shown in FIG. 24 (D), in this apparatus 1d in the processing machine loading / unloading process, the rotary table 13 does not rotate and the base table 12 faces the direction of the processing machine 200 in the direction of the arrow on the X axis (processing). Move in a direction approaching the machine 200, that is, move forward. As a result, the rotary table 13 provided with the length measuring mechanism unit 7 together with the base table 12 also moves forward toward the processing machine 200, so that the robot arms 75 a and 75 b of the length measuring mechanism unit 7 exceed the range of the base 11. It becomes possible to make it approach the input port of the processing machine 200. In the present apparatus 1, since the basic shape of the rotary table 13 is substantially square, the base table 12 is closer to the processing machine 200 at the corner of the square than at the side of the square. It is possible to shorten the moving distance of the. Further, the range that protrudes from the base 11 when approaching the processing machine 200 can be made smaller when approaching at a corner than when approaching at a side. Therefore, in the present apparatus 1, the rotary table 13 rotates 45 degrees forward from the reference position (or reverses 45 degrees from the position at the time of the split process) in the processing machine loading / unloading process, the removing process, and the length measuring process. The approach to the processing machine 200 by the corners of the rotary table 13 is realized. In the present apparatus 1, a work area for the cable holding unit 2, the alignment mechanism unit 4, the take-out mechanism unit 5, and the length measurement mechanism unit 7 is set at the corner. The reason why a part of the corner portion is notched in a W shape is to secure a space for arranging the take-out mechanism unit 5 and the retracting mechanism unit 8 rising from below the base 11.

  FIG. 25 shows a perspective view of the apparatus 1 in a preparation step corresponding to FIG. In FIG. 25, a guide rail 15 that guides movement by the base table 12 and a guide rail 16 that guides movement by the rotary table 13 are shown. In addition, a notch 13w that is notched in a W shape at the corner of the rotary table 13 is also illustrated.

  In FIG. 24D, the outline of the loading / unloading process with respect to the processing machine 200 executed by the control unit 9 will be described with reference to FIG. This insertion / removal processing is essentially performed continuously with the length measurement processing by the length measurement mechanism unit 7 described above. Therefore, here, it will be described as a continuation of the start position return process shown in FIG.

  As shown in FIG. 26, first, a process of calculating the movement amounts of the robot arms 75a and 75b of the base table 12 and the length measurement mechanism unit 7 is performed (S501, movement amount calculation process). In this process, based on the length of the core wire 103a measured by the length measurement straightening process in the previous process, the amount of movement of the base table 12 to be brought close to the processing machine 200 and the moved base table 12 (on the rotary table 13). The amount of movement of the robot arms 75a and 75b of the length measuring mechanism unit 7 in the above), that is, the moving position of the length measuring plates 77, 78 and 79 is obtained. These include the length inserted into the processing machine 200.

  Next, the robot arms 75a and 75b (measurement plates 77, 78 and 79) are moved by the slide unit 73a by the movement amount obtained in step S501 (S503, plate movement process). As a result, the length measuring plates 77, 78 and 79 are closed in order to reach a position where the core wire 103a which has been previously measured and remains as it is can be clamped (S505, plate closing process). Thereby, since the core wire 103a is clamped by the length measuring plates 77, 78 and 79, the leading end position of the core wire 103a is then moved according to the insertion port 201 (YZ plane) of the processing machine 200 (S507, Y · Z). Positioning process). This movement is movement other than the X-axis direction by the base table 12, and is performed by robot arms 75a and 75b (Y-axis direction) by the robot 74 and an elevator plate 72b (Z-axis direction) by the elevator unit 72a. The coordinates of the position on the YZ plane are also calculated in step S501.

  When the positioning of the length measuring plates 77, 78 and 79 is completed, the base table 12 is then moved (S509, base table advance processing). Thereby, the front-end | tip of the core wire 103a is thrown into the insertion slot 201, and the process by the processing machine 200 is attained (S511). When the processing by the processing machine 200 is finished (S513; Yes), the base table 12 is then retracted (S515, base table retracting process). Thereby, since the processed core wire 103a is taken out from the processing machine 200, the processed core wire 103a is retracted downward so as not to obstruct the removal of the next core wire 103b or the insertion into the processing machine 200 (S517, Processed core evacuation process).

  In the example described above, the movement in the X-axis direction approaching the processing machine 200 is performed by the base table 12. For example, the processing device table 19 on which the processing machine 200 is placed is configured to be movable in the X-axis direction. Thus, the processing machine 200 may be brought close to the apparatus 1. In this case, the amount of movement (movement position) of the processing machine 200 by the processing apparatus base 19 is obtained in step S501, and movement control of the processing apparatus base 19 is controlled by the control unit 9. Moreover, you may control movement to the direction in which both the processing machine 200 and the base table 12 approach a difference. Also in this case, each moving amount (moving position) is obtained in step S501. Since both move at the same time, the travel time can be shortened.

<A series of operation examples of this device>
Next, an example of a series of operations performed by the apparatus 1 will be briefly described with reference to FIGS. Note that the explanatory diagrams shown in these drawings are photographs of the prototype of the device 1. Therefore, it should be noted that some of the figures shown in FIGS. 1 to 26 described above are slightly different. For example, the drive unit 29 of the cable holding unit 2 is covered with the case in FIG. 1 and the like, and the structure inside is not shown, but in FIG. 27A and the like to be described later, the case is removed. Is different.

  In FIG. 28 to FIG. 32, the reference numerals and the like are not shown because the reference numerals, lead lines and the like hinder the drawing expression. Therefore, before describing an example of a series of operations by the present apparatus 1, each apparatus represented in FIGS. 28 to 32 is confirmed by attaching a reference numeral in FIG. In addition, the code | symbol which is not displayed in FIGS. 27-32 is described with a parenthesis writing below.

  FIG. 27A shows a perspective view of the entire configuration of the apparatus 1 in a preparation process. In this figure, the cable holding part (2) and the drive unit (29) are shown substantially at the center. Above these, the length measuring mechanism section 7, the harness holder 17, and the rack 18 are shown. The processing device base 19 is provided with a crimping machine as the processing machine 200. A control unit 9, a device frame 10, and a base 11 are also shown.

  FIG. 27B is a perspective view of the entire process of the apparatus 1 in the take-out process and the length measurement process, as viewed from the position where the processing machine 200 originally exists. In this figure, the take-out mechanism unit 5 and the retracting mechanism unit 8 that are hidden under the base 11 in other processes also appear to rise from the notch 11 a of the base 11. A guide rail 15 can be seen below the base table 12. Further, a w-shaped notch (13 w) formed at the corner of the rotary table 13 can also be seen behind the take-out mechanism 5 and the retracting mechanism 8. In addition, a cable holding unit 2, a split mechanism unit 3, an alignment mechanism unit 4, a sending mechanism unit 6, a length measuring mechanism unit 7, and a device frame 10 are also shown.

  FIG. 28 is an explanatory diagram showing an example of the split process. In FIG. 28A, the bundled core wire (102) is exposed from the tip (100a) of the multicore cable (100) held by the hold sleeve (28) of the cable holding portion (2). The pusher (33) and pusher guide (34) of the split mechanism section 3 are shown on the left side of the figure. In addition, on the upper left side of the figure, the feeding mechanism section (6) is displayed, and in the upper center, the measuring arms (76a, 76b) and the measuring plates (77, 78, 79) of the measuring mechanism section 7 are displayed. Has been. FIG. 28B shows that the pusher (33) of the split mechanism (3) is inserted into the bundled core wire (102) and the plurality of core wires (103) are pressed by the pusher guide (34). Has been. A plurality of core wires 103 are spread radially. FIG. 28C shows FIG. 28B with different angles.

  FIG. 29 is an explanatory diagram illustrating an operation example of the alignment mechanism unit, which is continued from FIG. In FIG. 29 (A), the pusher guide (34) of the split mechanism part (3) is rotated and a plurality of core wires (103) are gathered together in a fan shape by the fixing pin (35a) and the moving pin (35b). Is represented. FIG. 29 (B) shows a state in which the alignment mechanism section 4 is sandwiched from both sides by the C-shaped guide (44) with the plurality of core wires (103) gathered in a fan shape. ). FIG. 29 (C) shows a state after the split mechanism portion (3) is retracted, and corresponds to FIG. 9 (B) described above. In FIGS. 29 (B) and 29 (C), the delivery stick (67) of the delivery mechanism section (6) is close to the plurality of core wires (103). ) Is only shown as such.

  FIG. 30 is an explanatory diagram showing an example of the take-out process, and is a process that continues after the rotary table (13) is reversed 45 degrees from the state shown in FIG. FIG. 30 (A) shows a state in the middle of taking out one core wire (103) from a plurality of core wires (103) sandwiched between C-shaped guides (44). It is equivalent. FIG. 30B and FIG. 30C are also continued from FIG. 30A and correspond to FIG. 18I described above.

  FIG. 31 is an explanatory diagram showing an example of a length measurement process and a processing machine loading / unloading process, and is a process continued from FIG. FIGS. 31 (A) and 31 (B) show how the core wire 103a is resized by the length measuring plates 77, 78 and 79 of the length measuring mechanism section 7. FIG. ). On the other hand, in FIG. 31C, after the length measuring step, the core wire 103a sandwiched between the length measuring plates 77, 78 and 79 of the length measuring mechanism section 7 is input to the input port 201 by the advancement of the base table 12. This corresponds to FIG. 24D, although the angle is different.

  FIG. 32 is an explanatory diagram showing an example of the processing machine loading / unloading process, which continues from FIG. 31 (C). FIG. 32A shows a state immediately after the processed core wire 103a is taken out by retraction of the base table 12. FIG. 32 (B) and 32 (C) show a state in which the core wire 103 released from clamping by the length measuring plates 77, 78, 79 is retracted downward by the retracting mechanism portion 8. FIG. is there. As can be seen from this figure, the retraction mechanism unit 8 is constituted by a drive motor that is driven and controlled by the control unit 9, and a wire-like arm connected to the output shaft (rotary shaft) of the drive motor. .

  As described above, according to the present apparatus 1, the pusher 33 having the conical tip portion 33 a is connected to the tip portion 100 a of the multicore cable 100 held by the cable holding portion 2 so that the tip portion 33 a faces the multicore cable. 100 and coaxial. Then, the control unit 9 that controls the slide unit 31 c and the cable holding unit 2 moves at least one of the pusher guide 34 or the cable holding unit 2, and inserts the distal end portion 33 a of the pusher 33 into the bundled core wire 102. The core wire 103 is expanded. Then, the slide unit 31c is controlled so that the one end side tip part 34a of the pusher guide 34 presses the plurality of core wires 103 expanded. Further, the multi-core cable 100 is controlled by controlling the cable holding portion 2 until the pusher guide 34 or the cable holding portion 2 reaches a predetermined position where the plurality of core wires 103 pressed by the pusher guide 34 spread so as not to overlap each other radially. Rotate. Thereby, it becomes possible to align the core wire 103 of the multi-core cable 100 planarly in an automation technique. In addition, since a position sensor used in the slide unit 31c can detect a state in which a plurality of core wires 103 expand radially so as not to overlap with each other, a multi-core cable can be used without providing a dedicated sensor or camera. It becomes possible to align 100 core wires 103 in a plane.

  Further, according to the apparatus 1 described above, the EW guide 55 controlled by the control unit 9 is the outermost one positioned on the moving pin 35b side among the plurality of core wires 103 collected between the fixed pin 35a and the moving pin 35b. An extraction gap Sb through which the core wire 103a at the outer position can be taken out can be formed, and a guide passage Sc for guiding the core wire 103a taken out in the extraction gap Sb in a predetermined direction can be formed. The C-shaped guide 44 sandwiches a plurality of core wires 103 from both sides in the axial direction of the multi-core cable 100 at intervals that are less than twice the outer diameter of the core wire 103 and wider than the outer diameter so as not to overlap each other. In the vicinity of the outermost core wire 103a, an upper convex portion 46c that can enter between the core wires is provided. And since the cable holding part 2 is controlled by the control part 9 to rotate the multi-core cable 100 in the direction in which the outermost core wire 103a moves to the take-out gap Sb, for example, without pressing the core wire with a pin or the like. Even in this case, the outermost core wire 103a can be moved to the extraction gap Sb. After the outermost core wire 103a is moved to the take-out gap Sb, the C-shaped guide 44 is controlled to narrow the interval between the C-shaped guides 44 so that the inner core wire 103b from the outermost core wire 103a is moved upward. Push back by 46c. This prevents the core wire 103b on the inner side of the outermost core wire 103a from moving to the take-out gap Sb. Thereafter, the EW guide 55 is controlled to form a guide passage Sc, and the delivery mechanism 6 is controlled so as to push out the core wire 103a moved to the guide passage Sc in a predetermined direction. This makes it possible to take out one core wire from the plurality of core wires 103a to 103j collected between the fixed pin 35a and the moving pin 35b. In the automation technology, it is possible not only to align the plurality of core wires 103 of the multi-core cable 100 in a planar manner, but also to take out one core wire therefrom.

  Furthermore, according to the apparatus 1 described above, the control unit 9 controls the slide unit 73 a so that the length measuring plates 77, 78, and 79 holding the core wire 103 a with a predetermined pressure are moved in the distal direction of the core wire 103. At the same time, the position information of the length measuring plates 77, 78, 79 when the length measuring plates 77, 78, 79 are no longer sandwiched is obtained from the position sensor, and the length of the core wire 103a is calculated based on this. . As a result, the length of the core wire 103a is calculated by the control unit 9, and the length measuring plates 77, 78, 79 are clamped by the length measuring plates 77, 78, 79 at a predetermined pressure so that the length of the core wire 103a is the tip of the core wire 103a. Move in the direction. Therefore, the shape of the core wire 103a is straightened. That is, since the line is adjusted while measuring the line length, it is not necessary to separately provide a straightening process. As a result, it is possible to reduce the time required for the preparation of the core wire 103, and it is not necessary to newly provide a straightening device or jig, thereby reducing the equipment cost.

DESCRIPTION OF SYMBOLS 1 ... Core wire processing preparation apparatus 2 ... Cable holding part (cable holder)
DESCRIPTION OF SYMBOLS 3 ... Split mechanism part 4 ... Alignment mechanism part 5 ... Extraction mechanism part 6 ... Sending mechanism part 7 ... Length measuring mechanism part 8 ... Retraction mechanism part 9 ... Control part (controller)
11 ... Base 12 ... Base table (table)
DESCRIPTION OF SYMBOLS 13 ... Rotary table 19 ... Processing apparatus stand 28 ... Hold sleeve 31c ... Slide unit (movement mechanism)
32a ... Drive motor (rotating mechanism)
32b ... Drive gear (rotating mechanism)
32c ... Drive shaft (rotating mechanism)
32d ... belt (rotating mechanism)
33 ... Pusher 34 ... Pusher guide (Pusher guide, rotation mechanism)
34a ... tip (one end side)
35a ... Fixing pin (second pin, one pin)
35b ... Moving pin (first pin, other pin)
37 ... Rotating pipe (pusher guide, rotating mechanism)
39 ... Spring (Pusher Guide)
41 ... Slide unit 43 ... Robot unit 43a, 43b ... Robot arm 44 ... C-type guide (alignment guide)
46c ... Upper convex part (convex part)
52 ... Elevator unit 54 ... Robot unit 54a, 54b ... Robot arm 55 ... EW guide (extraction guide)
57 ... U-shaped part 58 ... J-shaped part 61 ... Slide unit 63 ... Drive part (sending mechanism)
65. Arm (delivery mechanism)
67 ... Sending stick (sending mechanism)
72a ... Elevator unit 73a ... Slide unit (drive mechanism)
74 ... Robot 75a, 75b ... Robot arm (drive mechanism)
76a, 76b ... Length measuring arms 77, 78, 79 ... Length measuring plates (clamping parts)
DESCRIPTION OF SYMBOLS 100 ... Multi-core cable 100a ... Tip 101 ... Outer coating 103 ... Core wire 103a ... Core wire of outermost position 200 ... Processing machine (core wire processing apparatus)
201 ... Input port J ... Shaft of multi-core cable Sa, Sb ... Extraction gap Sc ... Guide passage

Claims (2)

A plurality of core wires are fan-shaped between a first pin extending in the axial direction of the multi-core cable and a second pin extending in the axial direction at a position different from the first pin in the outer circumferential direction of the multi-core cable. A multi-core cable core wire processing preparation device extending to
A cable holder for holding the multi-core cable so as to be rotatable about its axis;
A controller for controlling the cable holder;
An extraction gap that can take out the outermost core wire located on the side of one of the two pins among the plurality of core wires can be formed, and the core wire taken out in the extraction gap is arranged in a predetermined direction. A take-out guide controlled by the controller so as to form a guide passage for guiding;
A plurality of core wires are sandwiched from both sides of the multi-core cable in the axial direction so that they do not overlap with each other at an interval that is less than twice the outer diameter of the core wires and wider than the outer diameter. An alignment guide provided with convex portions that can enter between the core wires in the vicinity;
A feeding mechanism controlled by the controller so as to be able to push out the core wire taken out by the take-out guide in the predetermined direction;
The controller controls the cable holder so as to rotate the multi-core cable in a direction in which the core wire at the outermost position moves to the take-out gap, and then narrows the interval between the alignment guides to reduce the core wire at the outermost position. The alignment guide is controlled so that the inner core wire is pushed back to the opposite side of the take-out gap by the convex portion, and then the take-out guide is controlled so that the guide passage is formed. An apparatus for preparing a core wire processing, wherein the feeding mechanism is controlled so as to push out the moved core wire in the predetermined direction. A rotation mechanism capable of fixing one of the first pin and the second pin and rotating the other pin along the outer circumferential direction of the multicore cable;
The controller controls the rotation mechanism to rotate the multi-core cable in a direction in which the inner core wire returns when the inner core wire is pushed back from the outermost core wire by the convex portion. The core wire processing preparation device according to claim 1.