JP2006032310A - Interior wiring unit cable connecting structure, interior wiring unit cable, interior wiring unit cable connection device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a connecting structure for an interior wiring unit cable that can improve workability, the interior wiring unit cable, and an interior wiring unit cable connecting device. <P>SOLUTION: Exposed lengths of a plurality of insulation wire cores 15 constructing a VVF cable are set having steps in exposed length direction. The exposure lengths of the cores 15 in the deep recess of a counter joint box 13 are the largest and smaller toward the front. A connection part 26 is formed by providing a plurality of the VVF cables as above, placing in line the cables, and crimp contacting long bus bars 20 and short bus bar 21 having a plurality of crimp contact edges on each steps of exposed insulation wire cores 15 to form a connection part 26. The interior wiring unit cable 11 is formed by accommodating the connection part 26 of the terminal of a cable group 12 in a joint box 13, and by fixing with a thermosetting resin. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a unit cable for indoor wiring, its connection structure, and a connection device.

  In recent years, a room unit that is unitized for each room, such as the entrance, living room, bedroom, etc., is manufactured at a factory of a housing maker, and assembled at the construction site according to the client's wishes and site shape, so that one house can be completed. The prefabricated house construction method is known. In the prefabricated house construction method, wiring for each room unit is also performed in the factory in advance, and simplification of indoor wiring work can be achieved by the wiring. In order to achieve simplification of indoor wiring work, a unit cable for indoor wiring having a joint box is used.

A conventional unit cable for indoor wiring has a structure in which an insulating thermosetting resin (epoxy resin, etc.) is filled and molded to fix and protect the branch connection part. (For example, refer to Patent Document 1). The indoor wiring unit cable is a two-core cable, a three-core cable, or the like depending on the application. The connection portion is connected using a crimp sleeve.
Registered Utility Model No. 3005912 (Page 2, Fig. 1)

  By the way, in the said prior art, since the connection structure by a crimping sleeve is employ | adopted, as shown in FIG. 13, it is necessary to pull together the insulated wire cores 1 connected together from each VVF cable 2. is there. In other words, it is necessary to pull and collect the plurality of insulated wire cores 1 to the place where the crimping sleeves 3 are connected.

  When collecting a plurality of insulated wire cores 1, the insulated wire cores 1 are easily overlapped with each other, and therefore, there is a problem that it is difficult to perform a connection work. In addition, there is also a problem that it takes work time.

  In addition, the connection structure using the crimp sleeve has a problem that the connection cannot be automated.

  The present invention has been made in view of the above-described circumstances, and provides an indoor wiring unit cable connection structure, an indoor wiring unit cable, and an indoor wiring unit cable connection device capable of improving workability. The issue is to provide.

  The connection structure of the unit cable for indoor wiring of the present invention according to claim 1, which has been made to solve the above-mentioned problems, is such that the exposed lengths of the plurality of insulation cores of the VVF cable are on the back side of the joint box. It is formed to have a stepped exposed length that is the longest and shortens toward the front, and is provided with a plurality of such VVF cables and arranged in a horizontal row, and for each exposed step of the insulated wire core. One or a plurality of bus bars having a plurality of press contact blades are press connected to form a connection portion.

  According to the present invention having such characteristics, a plurality of VVF cables processed so that the exposed length of the insulation core exposed from the terminal is stepped are prepared, and the prepared plurality of VVF cables are arranged in a horizontal row. When the bus bars are pressed and connected to each stage of the exposed insulated wire cores, the connection of the indoor wiring unit cables is completed.

  The connection structure of the unit cable for indoor wiring according to the second aspect of the present invention is the connection structure of the unit cable for indoor wiring according to claim 1, wherein the insulation core is inserted when the connection portion is formed. An insulating case having a plurality of through holes, a housing space for the insulating core inserted through the through holes, and a plurality of openings for inserting the bus bars is used.

  According to the present invention having such characteristics, an insulating case is used in forming the connection portion. After the insulated wire core is accommodated in the insulating case, it is pressure-contacted with the bus bar. A bus bar is inserted into the opening and insulated by the thickness of the insulating case material.

  The wiring structure for a unit cable for indoor wiring according to a third aspect of the present invention is the wiring structure for a unit cable for indoor wiring according to the second aspect, wherein positioning means used for inserting the bus bar into the opening is the bus bar. And the opening.

  According to the present invention having such a feature, the bus bar is inserted into the opening while being guided by the positioning means. The pressure connection between the bus bar and the insulated wire core is performed at a predetermined position by the positioning means.

  The indoor wiring unit cable of the present invention according to claim 4, which has been made to solve the above-mentioned problems, accommodates the connection portion related to the connection structure of the indoor wiring unit cable according to claim 1 in the joint box. It is characterized by being fixed by a thermosetting resin.

  According to the present invention having such a feature, a unit cable for indoor wiring provided with a joint box for protecting a connection portion is provided. The connection part is fixed to the joint box with a thermosetting resin.

  In order to solve the above-mentioned problems, the indoor wiring unit cable of the present invention according to claim 5 is characterized in that a cable holder is attached to a cable group having a connection structure for indoor wiring unit cables according to claim 2 or claim 3. The connecting portion of the end of the cable group to which the cable holder is attached is accommodated in the joint box, and the cable holder is locked to the locking portion of the joint box.

  According to the present invention having such a feature, a unit cable for indoor wiring provided with a joint box for protecting a connection portion is provided. The connection portion is prevented from falling off by locking the cable holder attached to the cable group to the locking portion of the joint box.

  In order to solve the above-mentioned problems, the wiring device for indoor wiring unit cables according to claim 6 of the present invention is such that the exposed lengths of the plurality of insulated cores of the VVF cable are on the back side of the joint box. The longest and stepped exposed lengths that become shorter toward the front are formed, and each of the exposed cable-insulating portion including a plurality of the VVF cables arranged in a horizontal row and the exposed insulated wire cores. A bus bar set structure portion for setting one or a plurality of bus bars having a plurality of press contact blades for each stage, and a bus bar press for forming a connection portion by collectively performing press contact connection with the insulating core by pressing the bus bar. And a structural part.

  According to the present invention having such characteristics, a connection device including a cable housing portion, a bus bar set structure portion, and a bus bar pressing structure portion is used to connect the unit cables for indoor wiring. A plurality of VVF cables arranged in a horizontal row are accommodated in the cable accommodating portion. In addition, a bus bar is set in the bus bar set structure portion for press-connecting to the insulation core of each stage. When the bus bar pressing structure portion is operated, the bus bars set in the bus bar set structure portion are collectively pressure-welded to the insulating core.

  The indoor wiring unit cable wiring device according to claim 7 of the present invention is the indoor wiring unit cable wiring device according to claim 6, wherein the cable housing portion includes the insulation core for each VVF cable. It is characterized by having a wire alignment guide that aligns at a desired interval.

  According to the present invention having such a feature, when the VVF cable is accommodated in the cable accommodating portion, the insulated cores are aligned in a state having a desired interval by the core alignment guide.

  The indoor wiring unit cable connection device according to claim 8 of the present invention is the indoor wiring unit cable connection device according to claim 6 or 7, wherein the bus bar set structure portion includes the cable housing portion. It has a structure that slides across, and has a holding portion and a receiving portion for the bus bar at each stage.

  According to the present invention having such characteristics, the bus bar set structure portion slides across the cable housing portion. The bus bar is held by the holding portion of the bus bar set structure portion. In addition, when the bus bar receives an action from the bus bar pressing structure portion, the bus bar is received by the receiving portion while being held by the holding portion. Insulation cores can also be received at the receiving portion of the bus bar set structure.

  The wiring unit for indoor wiring unit cables according to claim 9 of the present invention is the wiring unit for indoor wiring unit cables according to claim 8, wherein the bus bar set structure portion is provided for each stage of the insulation core. It further has a wire-center-interval-enlarging guide that expands the interval to a desired interval.

  According to the present invention having such a feature, the inter-wire-interval expansion guide enters between the insulated cores of each stage. The interval of each stage of the insulated wire core is expanded to a desired interval by a wire core interval expansion guide.

  According to the first aspect of the present invention, there is an effect that it is possible to facilitate the work of connecting the insulated wire cores. In addition, it is possible to improve productivity by facilitating the wiring work. Furthermore, since many connections can be made at a time just by aligning the VVF cables, the productivity can be further improved.

  According to the second aspect of the present invention, there is an effect that the insulation between the bus bars can be enhanced. In addition, there is an effect that the pressure contact connection of the bus bar can be facilitated.

  According to the present invention described in claim 3, there is an effect that the press-contact connection can be performed at an accurate position.

  According to the present invention described in claim 4, there is an effect that fixing and insulation between bus bars can be performed collectively.

  According to the present invention described in claim 5, there is an effect that the weight can be reduced. Moreover, there is an effect that productivity can be improved.

  According to the present invention described in claim 6, there is an effect that the press contact connection between the bus bar forming the connection portion and the insulating core can be performed collectively.

  According to the present invention described in claims 7 to 9, there is an effect that the press contact connection between the bus bar and the insulated wire core can be performed with high accuracy.

Hereinafter, description will be given with reference to the drawings.
1A and 1B are diagrams showing an embodiment of an indoor wiring unit cable connection structure and an indoor wiring unit cable according to the present invention. FIG. 1A is a perspective view of an indoor wiring unit cable, and FIG. FIG. 2 is a cross-sectional view of the unit cable for indoor wiring in FIG. 1, FIG. 3 is a plan view of the connection portion in FIG. 1, FIG. 4 is a front view of the connection portion in FIG. It is a side view.

  In FIG. 1, reference numeral 11 indicates a unit cable for indoor wiring according to the present invention. Reference numeral 12 indicates a cable group having the connection structure of the present invention at the terminal. The indoor wiring unit cable 11 includes a joint box 13 at the end of the cable group 12. Hereinafter, each component will be described with reference to FIGS. 1 to 5.

  The cable group 12 is configured by arranging a plurality of VVF cables 14 in a horizontal row. In this embodiment, two types of VVF cables 14 are used, one having three insulated wire cores 15 and the other having two insulated wire cores 15 (one example). In this embodiment, VVF 3 cores with power supply ground 3 × 2 mm, 3 VVF 3 cores for switch × 1.6 mm × 2, VVF 2 cores for extinguishing light × 1.6 mm, VVF 3 cores with ground for outlet × 1. 6 mm × 5 are used). The end of each VVF cable 14 is formed so that the sheath 16 is peeled off at a predetermined length and the insulating core 15 is exposed. The three or two insulated wire cores 15 of each VVF cable 14 have different exposure lengths and are formed in a stepped state.

  More specifically, among the three or two insulated wire cores 15, the exposed wire core 15 on the front side in the drawing, that is, the front side of the indoor wiring unit cable 11 (a joint box lid side described later) is exposed length. Is formed to be the shortest. Moreover, the insulated wire core 15 which becomes the back side (the back side of the joint box main body mentioned later) of the cable group 12 is formed so that the exposure length may become the longest. The insulating core 15 disposed in the middle is formed to have an exposed length that is intermediate between the above lengths. As a forming method related to the exposed length, for example, a dedicated jig capable of step-cutting the insulating wire core 15 after the sheath 16 is peeled off with a jig may be used.

  Here, the line of the insulated wire cores 15 on the front side of the indoor wiring unit cable 11 is the first line core exposed line 17, the line of the insulated wire cores 15 arranged in the middle is the second line core exposed line 18, indoors. A row of the insulated wire cores 15 on the back side of the wiring unit cable 11 is defined as a third wire core exposed row 19.

  A long bus bar 20 and a short bus bar 21 are connected to the first line core exposed row 17 (assumed to be an example). In addition, a long bus bar 20 and a short bus bar 21 are also connected to the second line core exposed row 18 and the third line core exposed row 19 (assumed to be an example). Both the long bus bar 20 and the short bus bar 21 are formed of a conductive metal material. The long bus bar 20 includes a bus bar main body 22 and a plurality of press contact blades 23 coupled to one side of the bus bar main body 22. The short bus bar 21 also has a bus bar main body 24 and a plurality of press contact blades 23 coupled to one side of the bus bar main body 24.

  The bus bar body 22 of the long bus bar 20 is formed in a strip shape matching the length of the first wire core exposed row 17 (second wire core exposed row 18 and third wire core exposed row 19). The bus bar main body 24 of the short bus bar 21 is shorter than the bus bar main body 22 of the long bus bar 20, and in the present embodiment, the bus bar main body 24 is formed in a strip shape that extends over two adjacent insulating cores 15 and 15. Yes. At one end of the bus bar main body 24 of the short bus bar 21, a convex portion 25 as a positioning means is formed. The convex portion 25 will be described in another embodiment of the present invention.

  The long bus bar 20 and the short bus bar 21 can be pressure-welded from the front side of the cable group 12. Therefore, the press contact blades 23 of the long bus bar 20 and the short bus bar 21 corresponding to the first line core exposed row 17 are formed to have a short length, in other words, a short length to the portion where the press contact is performed. On the other hand, the press contact blade 23 of the long bus bar 20 and the short bus bar 21 corresponding to the third line core exposed row 19 is formed to have a long length, in other words, a length up to the portion where the press contact is performed. The press contact blades 23 of the long bus bar 20 and the short bus bar 21 corresponding to the second line core exposed row 18 are formed to have an intermediate length. In addition, if the length of the press contact blade 23 is unified, standardization can be achieved.

  The arrangement of the press contact blade 23 is arbitrary. For example, as shown in FIG. 3, the press contact blade 23 of the long bus bar 20 corresponding to the third core exposed row 19 includes the first insulating core 15 from the left and the fifth to right ends from the left. The insulating wire core 15 is disposed and formed so as to be able to be pressure-connected. Six press contact blades 23 of the long bus bar 20 corresponding to the third line core exposed row 19 are formed.

  In the above configuration, the bus bars necessary for connection to the first line core exposed row 17, the second line core exposed row 18, and the third line core exposed row 19, that is, in this embodiment, the long bus bar 20 and the short bus bar 21 are provided. When the pressure connection (the position of the pressure connection in the drawing is an example, and the number of bus bars is also an example), the connection portion 26 is formed at the end of the cable group 12 as illustrated. The connection structure of the present invention is constituted by a pressure contact of a bus bar. In addition, the connection structure of the present invention is configured such that many connections can be made at once by aligning the VVF cables 14.

  The joint box 13 is a member made of synthetic resin for protecting the connection portion 26 of the terminal of the cable group 12, and is not particularly denoted by a symbol, but is integrated with the joint box body and the joint box body. And a joint box lid that engages in a separate state. The joint box 13 is an attachment partner of the connection part 26, and is formed in a size that can accommodate the connection part 26 therein.

  In the above configuration, when the connection portion 26 of the end of the cable group 12 is accommodated in the joint box 13 and the thermosetting resin 27 is filled in the joint box 13 to cure the thermosetting resin 27. The connecting portion 26 and its periphery are fixed to the joint box 13, and the production of the indoor wiring unit cable 11 of the present invention is completed.

  As described above with reference to FIGS. 1 to 5, since the connection structure of the present invention is configured by the pressure contact of the bus bar, the connection work of the insulated wire core can be made easier than before. . Moreover, productivity can be improved by facilitating the wiring work. Furthermore, many wires can be connected at a time just by aligning the VVF cables, and further productivity improvement, that is, automation can be achieved. On the other hand, the unit cable 11 for indoor wiring according to the present invention collectively fixes the connection portion 26 of the terminal of the cable group 12 and the periphery thereof and insulates the bus bars (long bus bar 20 and short bus bar 21). , Productivity can be improved.

  Next, the structure and operation of the connection device of the present invention suitable for forming the connection structure will be described with reference to FIGS. FIG. 6 is a perspective view showing an embodiment of a unit cable connection device for indoor wiring according to the present invention, FIG. 7 is a perspective view of a state in which the bus bar set structure is slid, and FIG. FIG. 9 is an enlarged perspective view of the cable housing portion and the bus bar set structure portion, and FIG. 10 is an enlarged perspective view of the bus bar set structure portion.

  6 to 8, reference numeral 61 indicates a connection device of the present invention for forming the connection portion 26 of the terminal of the cable group 12 described above. The connection device 61 of the present invention includes a device main body 63 having a cable housing portion 62, a bus bar set structure portion 64 that is slidably attached to the device main body 63, and a bus bar pressing structure portion 65 that is rotatably attached to the device main body 63. And is configured. Note that the connection device 61 of the present invention described here is configured to manually form the connection portion 26 (see FIGS. 4 and 5). However, the connection device 61 of the present invention is automated by applying the structure of this embodiment. Shall not interfere. Hereinafter, each component will be described with reference to FIGS.

  The apparatus main body 63 is formed in a substantially rectangular parallelepiped shape. The device main body 63 is formed with a cable housing portion 62 and a slider housing portion 67 in a state where the surface 66 is recessed. The cable housing part 62 is formed so as to be able to house the terminal of the cable group 12. The slider accommodating portion 67 is formed so that the bus bar set structure portion 64 can cross the cable accommodating portion 62. Specifically, one end of the slider housing portion 67 is arranged and formed on one side surface of the cable housing portion 62.

  A cable center alignment guide 68 is formed in the cable housing portion 62. The line center alignment guide 68 is arranged and formed in accordance with the slide position of the bus bar set structure portion 64. The wire core alignment guide 68 is formed so that the insulated wire cores 15 can be aligned at a desired interval for each VVF cable 14 constituting the cable group 12. Specifically, a plurality of block-shaped members as illustrated are arranged side by side in the vertical and horizontal directions. The wire core alignment guide 68 is formed in a suitable shape in consideration of the insertion of the insulating wire core 15 and a slide portion to be described later of the bus bar set structure portion 64.

  The bus bar set structure part 64 is short with the bus bar 20 long with respect to the insulated wire cores 15 of the first wire core exposed row 17, the second wire core exposed row 18, and the third wire core exposed row 19 at the end of the cable group 12. The bus bar 21 and the bus bar 21 can be set respectively. The bus bar set structure portion 64 is a so-called slider, is accommodated in the slider accommodating portion 67, and can be slid across the cable accommodating portion 62 as necessary. Such a bus bar set structure 64 includes a base 69, a wire core presser 70, a pair of wire center space expansion guides 71, and three bus bar guides 72.

  The base portion 69 is a block-shaped portion formed in accordance with the width and depth of the slider accommodating portion 67, and a handle 73 is formed on the upper surface of the base portion 69 when it is slid. On the side surface of the base portion 69 on the cable housing portion 62 side, a wire core pressing portion 70, a wire center space expansion guide 71, and a bus bar guide 72 are formed so as to protrude from the side surface. The wire core holding portion 70, the wire core interval expansion guide 71, and the bus bar guide 72 are arranged and formed so as not to interfere with the wire core alignment guide 68 of the cable housing portion 62.

  The wire core holding portion 70 is a portion for holding the first wire core exposed row 17 formed by exposing the insulating wire cores 15 and is formed in a columnar shape having a rectangular cross section. The pair of line center interval enlargement guides 71 are portions for expanding the intervals of the first line center exposed row 17, the second line core exposed row 18, and the third line core exposed row 19 to a desired interval. It arrange | positions so that it may be located in the base end side of the core exposed rows 17-19, ie, the base end side of the exposed insulated wire core 15. A taper surface (reference numeral omitted) for guiding the first line core exposed row 17 and the third line core exposed row 19 is formed in the wire center interval expanding guide 71. The three bus bar guides 72 are portions for setting the long bus bar 20 and the short bus bar 21 respectively on the leading end sides of the first line core exposed row 17, the second line core exposed row 18, and the third line core exposed row 19. And it has the holding | maintenance part 74 and the receiving part 75. FIG. The holding part 74 has a portion for inserting and holding the long bus bar 20 and a portion for inserting and holding the short bus bar 21.

  The long bus bar 20 and the short bus bar 21 are held by the holding unit 74 in a state of being arranged as shown in the drawing. Further, when the long bus bar 20 and the short bus bar 21 receive the action from the bus bar pressing structure portion 65, the long bus bar 20 and the short bus bar 21 are held by the receiving portion 75 while being held by the holding portion 74. In the receiving portion 75, the insulated wire core 15 is also received.

  The bus bar pressing structure portion 65 is configured to press the long bus bar 20 and the short bus bar 21 set in the bus bar set structure portion 64 to form the connection portion 26 (see FIGS. 4 and 5). Yes. Such a bus bar pressing structure portion 65 is attached to the cable housing portion 62 so as to be continuous. The bus bar pressing structure portion 65 includes a pair of attachment fixing portions 76, a rotating shaft portion 77, a pair of support arms 78, and a bus bar pressing portion 79.

  The pair of attachment fixing portions 76 are fixed so as to be in close contact with the side surface of the cable housing portion 62. Further, the pair of attachment fixing portions 76 are each formed in an L shape. A rotation shaft 77 is attached to a portion of the pair of attachment fixing portions 76 that protrudes from the surface 66 of the apparatus main body 63. One end of the support arm 78 is attached to the end of the rotating shaft 77 so as to be pierced. The pair of support arms 78 are rotatably attached at a predetermined interval.

  A bus bar pressing portion 79 is fixed to each other end of the pair of support arms 78. The bus bar pressing portion 79 is fixed so as to be sandwiched by the other end of the support arm 78. The bus bar pressing portion 79 is formed with a step portion 80 for pressing the long bus bar 20 and the short bus bar 21. The bus bar pressing portion 79 is formed with a handle 81 for rotating the bus bar pressing structure portion 65.

  The bus bar pressing structure portion 65 is not limited to a structure that presses the long bus bar 20 and the short bus bar 21 by performing the rotation operation as described above, but also other pressing structures using air pressure, hydraulic pressure, and mechanical means ( (Pressure structure) may be adopted.

  In the above configuration, from the initial state as shown in FIG. 6, first, the bus bar set structure portion 64 is slid toward the cable housing portion 62, and the wire center alignment guide 68 and the bus bar set structure portion 64 are combined. A substantially lattice-shaped core wire insertion portion 82 as shown in FIG. Next, the terminal of the cable group 12 is brought close to the wire core insertion portion 82 and the corresponding insulation wire core 15 is inserted into each insertion space 83 of the core wire insertion portion 82 while the terminal of the cable group 12 is shown in FIG. As shown, it is housed in a predetermined position of the cable housing portion 62.

  Subsequently, the long bus bar 20 and the short bus bar 21 are respectively set on the three bus bar guides 72 of the bus bar setting structure 64. Subsequently, as shown in FIG. 8, the bus bar pressing structure portion 65 is rotated downward, and the step portion 80 of the bus bar pressing portion 79 is pressed against the long bus bar 20 and the short bus bar 21. At this time, the long bus bars 20 and the short bus bars 21 set for the first line core exposed row 17, the second line core exposed row 18, and the third line core exposed row 19 receive the pressing force and receive the insulating wire cores. 15 is press-connected. Thereby, the connection part 26 is formed collectively.

  Finally, the bus bar pressing structure portion 65 is pivoted upward, the bus bar set structure portion 64 is slid so as to be accommodated in the slider accommodating portion 67, and the ends of the cable group 12 are moved upward to align the cores. When the guide 68 is pulled out, a series of operations are completed.

  As described above with reference to FIG. 6 to FIG. 10, the connection device 61 of the present invention includes a bus bar (here, the long bus bar 20 and the short bus bar 21) that forms the connection portion 26 and the insulating core 15. It is configured so that the press contact connection can be performed collectively. Therefore, the connection device 61 of the present invention is a device that can improve workability.

  Next, another embodiment of the indoor wiring unit cable connection structure and the indoor wiring unit cable according to the present invention will be described with reference to FIGS. 11 and 12. In addition, about the structural member fundamentally the same as the above-mentioned form, the same code | symbol is attached | subjected and description is abbreviate | omitted. FIG. 11 is an exploded perspective view showing another embodiment. FIG. 12 is a diagram of the unit cable for indoor wiring in FIG. 11, (a) is a perspective view with the joint box lid closed, and (b) is a perspective view with the joint box lid open. is there.

  In FIG.11 and FIG.12, the reference number 31 has shown the unit cable for indoor wiring of this invention. The unit cable 31 for indoor wiring according to the present invention includes a joint box 32 and the cable group 12 described above.

  In the cable group 12 according to another embodiment, a cable holder 33 and band members 34 and 34 are provided. In addition, an insulating case 36 is used in such a cable group 12 in order to form the connection portion 35. The connection part 35 further includes an insulating case 36 in addition to the configuration of the connection part 26 (see FIG. 1B).

  The cable holder 33 is a synthetic resin member, and includes a plurality of comb-shaped projections 37, locking projections 38 and 38 positioned on both sides of the plurality of projections 37, and supports these. And a strip-like base portion 39. The plurality of protrusions 37 are arranged and formed so as to be inserted between the VVF cables 14 arranged in a horizontal row of the cable group 12. The locking projections 38 and 38 are formed to be locked to locking portions 50 and 50 described later of the joint box 32. Specifically, it is formed as a thick protrusion that protrudes in the lateral direction of the cable group 12, and when hooked and locked by locking portions 50, 50 (to be described later) of the joint box 32, the cable group 12. It itself has a function of being fixed to the joint box 32.

  The band members 34 and 34 are members for preventing the positional deviation of the cable holder 33 from occurring, and are attached to the upper and lower sides of the cable holder 33. In this embodiment, the band members 34 and 34 are formed using a synthetic resin material.

  When the upper and lower portions of the cable holder 33 are tightened with the band members 34, 34 with the projections 37 inserted between the VVF cables 14, the VVF cables 14 positioned between the band members 34, 34 and the cable holder 33 are connected to each VVF cable 14. Forcible bending occurs, and as a result, displacement of the cable holder 33 is prevented. When the cable holder 33 is locked to the joint box 32, the cable group 12 is fixed to the joint box 32.

  Similar to the above-described connection portion 26 (see FIG. 1B), the connection portion 35 is respectively connected to the first wire core exposed row 17, the second wire core exposed row 18, and the third wire core exposed row 19 of the cable group 12. The bus bars (long bus bar 20 and short bus bar 21) required for connection are connected by pressure contact, but the difference is that an insulating case 36 is used for pressure connection by the bus bar.

  The insulating case 36 is a member made of synthetic resin having insulation properties, and a plurality of through holes 40 for inserting the insulating cores 15 and accommodation for the insulating cores 15 inserted through the through holes 40. A space 41 and a plurality of openings 42 for inserting bus bars (long bus bar 20 and short bus bar 21) are provided.

  The plurality of through holes 40 are formed in the bottom wall of the insulating case 36. Further, the plurality of through holes 40 are formed at positions corresponding to the insulated wire cores 15 of the first wire core exposed row 17, the second wire core exposed row 18, and the third wire core exposed row 19 of the cable group 12. Yes.

  The plurality of openings 42 are formed so as to open the front wall of the insulating case 36 (in this embodiment, six openings are formed in accordance with the number of bus bars). The plurality of openings 42 are formed at positions corresponding to the first wire core exposed row 17, the second wire core exposed row 18, and the third wire core exposed row 19 of the cable group 12. Among such a plurality of openings 42, a plurality of recesses 43 that guide the protrusions 25 of the short bus bar 21 are formed in the opening 42 corresponding to the short bus bar 21. The concave portion 43 constitutes a positioning means together with the convex portion 25, and has a function for press-connecting the short bus bar 21 at an accurate position. The plurality of openings 42 are formed so as to communicate with the accommodation space 41.

  In the above-described configuration, each insulated wire core 15 of the cable group 12 is inserted into the corresponding through hole 40 of the insulating case 36 to be accommodated in the accommodating space 41, and the first wire core exposed row 17 is disposed through the corresponding opening 42. When the long bus bar 20 and the short bus bar 21 are press-connected to the second line core exposed row 18 and the third line core exposed row 19 respectively (the press-connecting position in the drawing is an example), the cable group 12 The connection part 35 is formed in the terminal.

  The connection structure according to another embodiment of the present invention is configured to press-contact the bus bar using an insulating case 36. In addition, the connection structure of another embodiment of the present invention is configured so that a large number of connections can be made at once by aligning the VVF cables 14.

  Furthermore, the connection structure of another embodiment of the present invention is configured so that force is distributed over the entire cable holder 33 even when, for example, one VVF cable 14 is pulled (when indoor wiring is performed). Even if the VVF cable 14 is pulled with a large force, a load is not applied to the press contact connection portion, and no disconnection occurs.

  The joint box 32 is a member made of synthetic resin for protecting the connection portion 35 of the terminal end of the cable group 12, and includes a joint box main body 44 and a joint box lid body 45. The joint box 32 is formed in a size that can accommodate the connection portion 35 therein.

  The joint box main body 44 is a substantially box-shaped member in which a surface in a direction in which the connection portion 35 of the terminal of the cable group 12 is inserted and a surface in a direction in which the cable group 12 is pulled out are opened. It has a portion 47 and side walls 48, 48.

  The substrate 46 is a plate-like portion having a flat front and back surface and a rectangular shape in plan view, and a mounting portion 47 is coupled to the upper edge of the substrate 46. A through hole 49 for attaching to a wall or a pillar is formed in the attachment portion 47.

  The side walls 48 are formed on the substrate 46 so as to protrude from both side edges of the substrate 46. Further, the side walls 48 and 48 have an appropriate height and are integrally formed with the substrate 46. Locking portions 50 and 50 for locking the locking projections 38 and 38 of the cable holder 33 are formed below the side walls 48 and 48. The locking portions 50, 50 are formed in a concave shape in this embodiment (it is only necessary that the cable holder 33 can be locked so as not to move). A plurality of locking means 51, 51 for engaging the joint box lid 45 are formed on the side walls 48, 48.

  The joint box lid body 45 is formed as a substantially plate-like member. The joint box lid 45 is formed with locking portions 52 and 52 that engage with the locking means 51 and 51 of the joint box main body 44. The joint box lid 45 is formed with a substantially bridge-shaped cable presser 53 having elasticity. The joint box cover body 45 is formed so as to be detachably engaged with the joint box main body 44 (in this embodiment, the joint box cover body 45 is integrated via the hinges 54, 54, but may be separated. Note that a sealed structure may be adopted).

  In the above configuration, the connection portion 35 of the end of the cable group 12 is housed in the joint box body 44, the locking projections 38, 38 of the cable holder 33 are locked to the locking portions 50, 50, and When the joint box lid 45 is engaged with the joint box body 44, the cable group 12 is fixed to the joint box 32, and the production of the indoor wiring unit cable 31 according to another embodiment of the present invention is completed.

  As described above with reference to FIG. 11 and FIG. 12, the connection structure of another embodiment of the present invention is also configured by the pressure contact of the bus bar. Can be easily. Moreover, productivity can be improved by facilitating the wiring work. Furthermore, many wires can be connected at a time just by aligning the VVF cables, and further productivity improvement, that is, automation can be achieved. On the other hand, the indoor wiring unit cable 31 according to another embodiment of the present invention is fixed by a locking structure that does not use a thermosetting resin, so that it is lighter than the indoor wiring unit cable 11 of FIG. Can be achieved. Further, the time for curing the resin is not required, and the productivity can be improved.

  In addition, it goes without saying that the present invention can be variously modified without departing from the spirit of the present invention.

It is a figure which shows one Embodiment of the connection structure of the unit cable for indoor wiring of this invention, and the unit cable for indoor wiring, (a) is a perspective view of the unit cable for indoor wiring, (b) is a perspective view of a connection part. It is. It is sectional drawing of the unit cable for indoor wiring of FIG. It is a top view of the connection part of FIG. It is a front view of the connection part of FIG. It is a side view of the connection part of FIG. It is a perspective view which shows one Embodiment of the connection apparatus of the unit cable for indoor wiring of this invention. It is a perspective view of the state which made the bus-bar set structure part slide. It is a perspective view of the state which made the bus-bar press structure part act. It is an expansion perspective view of a cable accommodating part and a bus-bar set structure part. It is an expansion perspective view of a bus-bar set structure part. It is a disassembled perspective view which shows other one Embodiment of the connection structure of the unit cable for indoor wiring of this invention, and the unit cable for indoor wiring. It is a figure of the unit cable for indoor wiring of FIG. 6, (a) is a perspective view of the state which closed the joint box cover body, (b) is a perspective view of the state which opened the joint box cover body. It is sectional drawing of the unit cable for indoor wiring of a prior art example.

Explanation of symbols

DESCRIPTION OF SYMBOLS 11 Unit cable for indoor wiring 12 Cable group 13 Joint box 14 VVF cable 15 Insulated wire core 16 Sheath 17 First wire core exposed row 18 Second wire core exposed row 19 Third wire core exposed row 20 Long bus bar (bus bar)
21 Short bus bar (bus bar)
22 Busbar body 23 Press contact blade 24 Busbar body 25 Convex part (positioning means)
26 Connection part 27 Thermosetting resin 31 Unit cable for indoor wiring 32 Joint box 33 Cable holder 34 Band member 35 Connection part 36 Insulating case 37 Protrusion part 38 Locking protrusion part 39 Base part 40 Through-hole 41 Housing space 42 Opening part 43 Concave portion (positioning means)
44 Joint box body 45 Joint box lid 46 Substrate 47 Mounting portion 48 Side wall 49 Through hole 50 Locking portion 51 Locking means 52 Locking portion 53 Cable retainer 54 Hinge 61 Connecting device 62 Cable housing portion 63 Device body 64 Busbar set structure portion 65 Bus bar pressing structure part 66 Surface 67 Slider accommodating part 68 Wire center alignment guide 69 Base part 70 Wire center pressing part 71 Line center space expansion guide 72 Bus bar guide 73 Handle 74 Holding part 75 Receiving part 76 Mounting fixing part 77 Rotating shaft part 78 Support arm 79 Busbar pressing part 80 Step part 81 Handle 82 Wire core insertion part 83 Insertion space

Claims (9)

The exposed lengths of the plurality of insulated wire cores of the VVF cable are formed to have a stepped exposed length such that the innermost side of the joint box is the longest and becomes shorter toward the front, A plurality of cables are arranged in a horizontal row, and one or a plurality of bus bars having a plurality of press contact blades are press-connected for each stage of the exposed insulated wire core to form a connection portion. Wiring unit cable connection structure. In the connection structure of the unit cable for indoor wiring according to claim 1,
In forming the connection portion, a plurality of through holes for inserting the insulating wire cores, a housing space for the insulating wire cores inserted through the through holes, and a plurality of openings for inserting the bus bars are provided. An indoor wiring unit cable connection structure characterized by using an insulating case. In the connection structure of the unit cable for indoor wiring according to claim 2,
A connection structure for a unit cable for indoor wiring, wherein positioning means used for inserting the bus bar into the opening is provided in the bus bar and the opening. A unit cable for indoor wiring, comprising: a connection portion according to the connection structure for a unit cable for indoor wiring according to claim 1; and a fixing portion that is fixed with a thermosetting resin. A cable holder is attached to the cable group having the connection structure of the unit cable for indoor wiring according to claim 2 or 3, and the connection part of the terminal of the cable group to which the cable holder is attached is accommodated in the joint box. A unit cable for indoor wiring, wherein the cable holder is locked to a locking portion of the joint box. The exposed lengths of the plurality of insulated wire cores of the VVF cable are formed to have a stepped exposed length such that the innermost side of the joint box is the longest and becomes shorter toward the front, A cable housing portion including a plurality of cables and arranged in a horizontal row;
A bus bar set structure for setting one or a plurality of bus bars having a plurality of press contact blades for each stage of the exposed insulated wire core;
A bus bar pressing structure portion that presses the bus bar and collectively performs a press-contact connection with the insulated wire core to form a connection portion;
A unit cable connection device for indoor wiring, comprising: In the connection apparatus of the unit cable for indoor wiring of Claim 6,
The cable housing unit includes a wire core alignment guide for aligning the insulated wire cores at a desired interval for each VVF cable. In the connection apparatus of the unit cable for indoor wiring of Claim 6 or Claim 7,
The bus bar set structure section has a structure that slides across the cable housing section, and has a holding section and a receiving section for the bus bar at each stage. apparatus. In the connection apparatus of the unit cable for indoor wiring of Claim 8,
The bus bar set structure part further includes a wire core interval expansion guide for expanding the interval of each stage of the insulated wire core to a desired interval.

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