JP2020174432A - Joint box - Google Patents

Abstract

To provide a joint box the handleability of which can be improved.SOLUTION: A joint box 1 includes: a casing 2; a pin 4 that is located inside the casing 2 and is formed into a columnar shape; and a plurality of terminals 7 that are respectively attached to terminals of a plurality of cables 5 and that are assembled and mutually and electrically connected to the pin 4. The pin 4 includes a tapered portion 42 having a radial dimension that gradually decreases from a base end side toward a leading end side. The terminal 7 includes: a terminal main body 70; an insertion hole 71 which is formed in the terminal main body 70 and into which the tapered portion 42 of the pin 4 is inserted; and a projected portion 74 that is formed on the terminal main body 70 so as to be projected toward the insertion hole 71 side and that is deformable by the pin 4.SELECTED DRAWING: Figure 1

Description

The present invention relates to a joint box.

As a conventional joint box, for example, in Patent Document 1, a connection portion formed by connecting the terminals of an insulated core constituting a wiring unit cable is integrated with or separately from the joint box main body and the joint box main body. A joint box for a wiring unit cable that protects a connection portion from the outside by accommodating it inside a joint box cover that engages in a state is disclosed.

Japanese Unexamined Patent Publication No. 2004-96983

However, there is room for further improvement in the above joint box from the viewpoint of handleability.

The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a joint box capable of improving handleability.

In order to solve the above problems, the joint box according to the present invention is attached to a housing, a pin formed in a columnar shape inside the housing, and terminals of a plurality of cables, and is assembled to the pin. It comprises a plurality of terminals that are electrically connected to each other, and the pin has a tapered portion whose radial dimension gradually decreases from the proximal end side to the distal end side, and the terminal is a terminal body and the terminal body. It is characterized by having an insertion hole formed in the terminal body into which the tapered portion of the pin is inserted, and a protruding portion formed in the terminal body protruding toward the insertion hole and deformable by the pin.

Further, in the joint box, the plurality of cables include a unit configuration cable in which the terminal is attached to one end and a plurality of cables are bundled to form a cable unit, and the unit configuration cable between different cable units connects the terminal. It is preferable to be electrically connected via.

Further, in the joint box, a plurality of the pins are provided in the housing, the plurality of cables include a connection cable to which the terminals are attached at both ends, and the connection cable has a first terminal. With the other cable assembled to the pin, the other terminal is assembled to the second pin, and the other cable assembled to the first pin via one terminal and the other terminal. It is preferable to electrically connect the other cable assembled to the second pin.

Further, in the joint box, the housing includes a pin holding space portion in which the terminal and the pin are located, an open space portion adjacent to the pin holding space portion and an insertion port for inserting the unit constituent cable, and an open space portion. The terminal accommodated in the pin holding space portion and the closed space portion located on the opposite side of the open space portion across the pin, and the connection cable may be provided in the closed space portion. preferable.

Further, in the joint box, the housing is arranged so as to have a separation distance corresponding to the thickness dimension of the unit configuration cable, and the unit configuration cable is restricted from moving in the width direction of the housing. It is preferable to provide a pair of movement restricting members.

Further, in the joint box, the pin has a columnar portion located on the proximal end side of the tapered portion and a gap portion located between the tapered portion and the columnar portion, and the gap portion has a columnar portion located between the tapered portion and the columnar portion. , It is preferable that the tip portion of the protruding portion can be inserted.

The joint box according to the present invention has the following configuration. The terminal has a terminal body, an insertion hole formed in the terminal body into which the tapered portion of the pin is inserted, and a protruding portion formed in the terminal body so as to project toward the insertion hole and deformable by the pin. With this configuration, when the pin is inserted into the insertion hole of the terminal, the protruding portion in contact with the pin is deformed, and the terminal can be temporarily fixed to the pin. With this joint box, if the pin that temporarily fixed the terminal is in the wrong position, the terminal can be removed from the pin without cutting the cable, and then the terminal can be temporarily fixed to the regular pin. .. As a result, the joint box can improve the handleability.

FIG. 1 is a perspective view of a joint box including the joint box according to the present invention. FIG. 2 is a perspective view of a cover included in the joint box. FIG. 3 is a perspective view of the terminal before being inserted into the pin. FIG. 4 is a cross-sectional view of a state in which a terminal insertion hole is being inserted into the pin. FIG. 5 is a perspective view after the terminal is inserted into the pin. FIG. 6 is a plan view of the joint box before attaching the cover. FIG. 7 is a perspective view of the terminal before being inserted into the pin in the joint box of the first modification. FIG. 8 is a perspective view of the joint box of the first modification after the terminal is inserted into the pin. FIG. 9 is a cross-sectional view taken along the line IX-IX of FIG. FIG. 10 is a cross-sectional view of a pin in the joint box of the second modification. FIG. 11 is a plan view of the terminals in the joint box of the modified example 3. FIG. 12 is a plan view of the terminals in the joint box of the modified example 4. FIG. 13 is a cross-sectional view taken along the line XIII-XIII of FIG.

Hereinafter, embodiments of the joint box according to the present invention will be described with reference to the drawings. The present invention is not limited to this embodiment.

[Embodiment]
FIG. 1 is a perspective view of a joint box including the joint box according to the present invention. FIG. 2 is a perspective view of a cover included in the joint box. FIG. 3 is a perspective view of the terminal before being inserted into the pin. FIG. 4 is a cross-sectional view of a state in which a terminal insertion hole is being inserted into the pin. FIG. 5 is a perspective view after the terminal is inserted into the pin. FIG. 6 is a plan view of the joint box before attaching the cover. The protrusions of the joint box 1 shown in FIGS. 1 and 6, which will be described later, are omitted.

As shown in FIG. 1, the X direction is the length direction of the joint box 1. The Y direction is the width direction of the joint box 1 that intersects (orthogonally) the length direction X. The Z direction is the thickness direction of the joint box 1 that intersects (orthogonally) with respect to each of the length direction X and the width direction Y.

The joint box 1 shown in FIG. 1 electrically connects the cables 5 described later to each other to protect the connection points. As shown in FIG. 1, the joint box 1 is attached to a housing 2, a pin 4 located inside the housing 2, and terminals of a plurality of cables 5, respectively, and is assembled to the pin 4 to be electrically connected to each other. It is provided with a plurality of terminals 7 connected to. The joint box 1 is used, for example, for connecting cables to each other in an indoor ceiling for the purpose of saving labor in indoor wiring work in a building. The joint box 1 is fixed to the building side of the indoor ceiling, for example, by being fixed to a bracket attached to the indoor ceiling.

The housing 2 has a case body 20 and a cover 30. The case body 20 is formed in a substantially rectangular parallelepiped shape by, for example, an electrically insulating synthetic resin.

The case body 20 has a bottom wall 21 located on one side of the thickness direction Z, both side walls 22 and 23 located on both sides of the bottom wall 21 in the width direction Y and facing each other, and one end of the length direction X. It has one end wall 24 located at. Further, the case body 20 has a first opening 25 located at the other end in the thickness direction Z and a second opening 26 located at the other end in the length direction X. Both side walls 22 and 23 of the case body 20 have claw portions 27 that project so as to be separated from each other. A plurality of pairs of movement restricting members 29a and 29b are provided on the bottom wall 21 (that is, the housing 2). Each of the pair of movement restricting members 29a and 29b is formed so as to be elastically deformable by, for example, an electrically insulating material. The plurality of movement restricting members 29a and 29b are arranged at equal intervals along the width direction Y. In the pair of movement restricting members 29a and 29b, one movement restricting member 29a and the other movement restricting member 29b are arranged so as to have a separation distance corresponding to the thickness dimension of the unit constituent cable 50 described later. In the case body 20 (that is, the housing 2), the dimension of the width direction Y of the pair of virtual lines is bisected between the virtual lines extending the pair of movement restricting members 29a and 29b in the length direction X, respectively. A pin 4 described later is provided at the position.

The cover 30 is formed of an electrically insulating synthetic resin, and has a cover main body 31, a plurality of protrusions 35, and a plurality of partition walls 39, as shown in FIG. The cover body 31 is formed in a substantially rectangular flat plate shape. The protrusion 35 is formed so as to project downward from the peripheral edge of the cover 30 in the width direction Y. The protrusion 35 has a fitting hole 36 that fits into the claw 27. Each partition wall portion 39 is formed so as to protrude from the cover main body 31 and extend along the length direction X. Each partition wall portion 39 is formed in a substantially rectangular plate shape in the plate thickness direction along the width direction Y. The plurality of partition walls 39 are arranged at equal intervals in the width direction Y. When the cover 30 is assembled to the case main body 20, the partition wall portion 39 is arranged at an intermediate position between two adjacent pins 4 in the width direction Y.

In the housing 2, the cover 30 is arranged so as to close the first opening 25 of the case body 20 shown in FIG. 1, and the claw portion 27 and the fitting hole 36 are fitted to the case body 20. The cover 30 is attached to form the housing 2. When the cover 30 is attached to the case body 20, a space 32 is formed between the case body 20 and the cover 30, that is, inside the housing 2. Further, at one end of the housing 2 in the length direction X, an insertion port 28 is formed by a second opening 26 of the case body 20.

As shown in FIG. 1, the pin 4 is provided on the bottom wall 21 of the case body 20. The pin 4 is formed in a columnar shape having an axial center extending along the thickness direction Z. The pin 4 is formed of, for example, an electrically conductive material, and is fixed to the bottom wall 21 by a screw (not shown) penetrating the bottom wall 21. A plurality of such pins 4 are provided on the bottom wall 21. Pins 4 provided on the bottom wall 21 have pin 4a, pin 4b, pin 4c, pin 4d, pin 4e, pin 4f, pin 4g, and pin 4h located in this order from the left in FIG. It is composed of. Matters common to a plurality of pins will be described as pin 4, and matters relating to individual pins will be described with reference numerals such as 4a. The shape of the pin 4 will be described in detail later. A plurality of pins 4 are arranged side by side along the width direction Y on the bottom wall 21 of the housing 2. Therefore, a pin holding space 32a in which the pin 4 is located is formed in the space 32 of the housing 2 (see FIG. 6).

The plurality of cables 5 are composed of a unit configuration cable 50 and a connection cable 54. The unit configuration cable 50 comprises two cables 51a and 51b constituting the first cable unit 61, two cables 52a and 52b constituting the second cable unit 62, and a third cable unit 63. Includes three cables 53a, 53b, 53c. The connection cable 54 includes two connection cables 54a and 54b.

Hereinafter, the cable 5 will be described, but since the cables 51a, 51b, 51c, 52a, 52b, 53a, 53b, 54a, and 54b have the same configuration, only the cable 5 shown in FIG. 3 will be described. The cable 5 has a lead wire 55 and an insulator 56.

The lead wire 55 is a core wire in the cable 5. The conducting wire 55 is a metal wire formed of a metal material having electrical conductivity and flexibility (for example, a copper alloy). The shape of the lead wire 55 in the cross section orthogonal to the length direction X is circular.

The insulator 56 covers the outer peripheral surface of the lead wire 55. The insulator 56 is formed by injection molding an electrically insulating synthetic resin (for example, vinyl chloride) on the outer peripheral surface side of the lead wire 55. The insulator 56 has electrical insulation. The shape of the insulator 56 in the cross section orthogonal to the length direction X is an annular shape. Further, since the insulator 56 has flexibility, when the lead wire 55 is bent by the wiring work, it can be bent following the lead wire 55.

The first cable unit 61 is a two-core "vinyl insulated vinyl sheath cable flat type (VVF)" formed by bundling two unit constituent cables 50 (first unit constituent cable 51a and second unit constituent cable 51b). Cable) ". The first cable unit 61 is formed into a flat shape by matching the extending directions of the cables 51a and 51b and arranging the cables 51a and 51b side by side in the width direction Y. Since the configuration of the second cable unit 62 is the same as the configuration of the first cable unit 61, the description of the configuration of the second cable unit 62 will be omitted.

The third cable unit 63 has a three-core structure formed by bundling three unit-constituting cables 50 (first unit-constituting cable 53a, second unit-constituting cable 53b, and third unit-constituting cable 53c). It is a "vinyl insulated vinyl sheath cable flat type (VVF cable)". The third cable unit 63 is formed in a flat shape by matching the extending directions of the cables 53a, 53b, and 53c and arranging the cables 53a, 53b, and 53c side by side in the width direction Y.

The first cable unit 61 has two unit-constituting cables 51a and 51b and an exterior member 57a located in the outermost shell. The second cable unit 62 has two unit-constituting cables 52a and 52b and an exterior member 57b located in the outermost shell. The third cable unit 63 has three unit-constituting cables 53a, 53b, 53c and an exterior member 57c located at the outermost shell. Since the exterior members 57a, 57b, 57c of the cable units 61, 62, 63 have the same configuration, the exterior member 57a of the first cable unit 61 will be described, and the exterior members 57b of the other cable units 62, 63 will be described. , 57c will be omitted.

The exterior member 57a is provided on the outermost shell of the unit constituent cables 51a and 51b, and is a so-called sheath. The exterior member 57a collectively covers the radial outer sides of the unit-constituting cables 51a and 51b arranged side by side in the width direction Y, and bundles a plurality of unit-constituting cables 51a and 51b. The exterior member 57a is formed, for example, by injection molding an electrically insulating synthetic resin (for example, vinyl chloride) on the radial outer side of the unit constituent cables 51a and 51b arranged in the width direction Y. The exterior member 57a is shaped like an oval ring in a cross section orthogonal to the length direction X. The exterior member 57a has electrical insulation. Further, since the exterior member 57a has flexibility, when the lead wire 55 is bent by the wiring work, it can be bent following the lead wire 55.

The connection cable 54 has terminals 7 attached to both ends thereof, and electrically connects different electric devices via one terminal 7 and the other terminal 7. Here, the connection cable 54 includes a first connection cable 54a and a second connection cable 54b. The first connection cable 54a electrically connects the electrical device connected to the third unit configuration cable 53c and the electrical device connected to the first unit configuration cable 51a. The second connection cable 54b electrically connects the electrical equipment connected to the second unit configuration cable 53b and the electrical equipment connected to the second unit configuration cable 52b.

In such a joint box 1, if a connection error is found after electrically connecting (connecting) the unit configuration cables of cable yuts that are different from each other by the connector, the following problems will occur. May occur. That is, when a connection error is found and reconnection is required, the ends of both unit configuration cables are cut off, the connector is removed, the insulator is removed from the lead wire, and then the lead wire is exposed. , It is inconvenient to handle because a new connector will be installed. Therefore, the joint box 1 according to the present embodiment has the terminal 7 described below in order to improve the handleability.

As shown in FIG. 3, the terminal 7 has a terminal body 70, an insertion hole 71, a wire caulking portion 72, a connecting portion 73, and a protrusion, for example, by using an electrically conductive metal material (for example, a copper alloy). It is formed so as to have a portion 74, and these are integrally formed. The terminal body 70, the connection portion 73, and the lead wire caulking portion 72 are arranged side by side along the length direction X.

The terminal body 70 is, for example, formed on a flat plate and in an annular shape. The insertion hole 71 is formed in the terminal body 70 and the pin 4 is inserted. In the terminal 7, the terminal body 70 and the insertion hole 71 are arranged so that the axis X1 of the annular terminal body 70 and the axis X2 of the insertion hole 71 coincide with each other.

The protruding portion 74 is formed in the terminal body 70 so as to project toward the insertion hole 71 and can be deformed by the pin 4. More specifically, the protruding portion 74 has, for example, a base end portion 74b adjacent to the inner edge of the terminal body 70 and a tip portion 74a located in the radial direction with respect to the base end portion 74b. It is formed in a shape. The terminal 7 has a plurality of such protrusions 74, the plurality of protrusions 74 are arranged along the circumferential direction with respect to the axial center X1 of the terminal body 70, and the plurality of protrusions 74 are arranged in an annular shape. ..

Since the protruding portion 74 is formed at the terminal 7 as described above, the insertion hole 71 is different from the portion located in the innermost diameter direction with respect to the axial center X2 and the portion located in the outermost diameter direction. , It is formed in a substantially star shape. In the following description, for convenience, the radial dimension D3 of the insertion hole 71 with respect to the axial center X2 is the dimension of the portion located most in the radial direction with respect to the axial center X2.

The wire caulking portion 72 of the terminal 7 having such a configuration is electrically connected to the wire 55 in which the insulator 56 is peeled off and exposed at the terminal of the cable 5. The connection portion 73 connects the terminal body 70 and the lead wire caulking portion 72.

As shown in FIG. 1, a terminal 7 is assembled to one end of each unit configuration cable 51a, 51b, 52a, 52b, 53a, 52b, 52c by a lead wire caulking portion 72. Further, terminals 7 are assembled to both ends of the connection cable 54 by the lead wire caulking portion 72. As shown in FIG. 1, the terminal 7 is composed of a terminal 7 assembled to one end of each unit configuration cable 50 and a terminal 7 assembled to one end of the connection cable 54, respectively. The terminal 7 assembled to one end of each unit configuration cable 50 is composed of a terminal 7a, a terminal 7b, a terminal 7c, a terminal 7d, a terminal 7e, a terminal 7f, and a terminal 7g in order from the left in FIG. The terminal 7 assembled to one end of the connection cable 54 is composed of a terminal 7h, a terminal 7i, a terminal 7j, and a terminal 7k in order from the left in FIG. Matters common to a plurality of terminals will be described as terminal 7, and matters relating to individual terminals will be described with reference numerals such as 7a.

As shown in FIGS. 1 and 3, the pin 4 has a columnar portion 41 located on the base end side on the bottom wall 21 side and a first opening on the opposite side of the bottom wall 21 side in the thickness direction Z. It has a tapered portion 42 located on the 25 side. That is, the columnar portion 41 is located on the proximal end side of the tapered portion 42. The columnar portion 41 is formed in a columnar shape having an axial center X3 extending in the thickness direction Z, for example. The tapered portion 42 is formed in a truncated cone shape having an axial center X4 extending in the thickness direction Z, for example. The tapered portion 42 has the smallest radial dimension D1 with respect to the axial center X4 of the first portion 42a located on the most tip side, and has a diameter with respect to the axial center X4 as it goes closer to the proximal end side in the thickness direction Z. The dimension in the direction gradually increases. Therefore, in the tapered portion 42, the radial dimension D2 with respect to the axial center X4 of the second portion 42b located closest to the proximal end side and adjacent to the columnar portion 41 has the largest radial dimension with respect to the axial center X4. In other words, the tapered portion 42 gradually decreases in radial dimension from the proximal end side to the distal end side.

The pin 4 has a columnar portion 41 and a tapered portion 42 arranged so that the axial center X3 of the columnar portion 41 and the axial center X4 of the truncated cone-shaped tapered portion 42 coincide with each other. Further, the radial dimension D1 of the first portion 42a of the tapered portion 42 with respect to the axial center X4 is smaller than the radial dimension D3 with respect to the axial center X2 of the insertion hole 71 of the terminal 7. Therefore, the first portion 42a located at the tip of the pin 4 can be inserted into the insertion hole 71 of the terminal 7. Further, the radial dimension D1 of the first portion 42a of the tapered portion 42 with respect to the axial center X4 is smaller than the radial dimension D4 of the columnar portion 41 with respect to the axial center X3. Therefore, it is easy to insert the first portion 42a located at the tip of the tapered portion 42 into the insertion hole 71. Further, the radial dimension D2 of the second portion 42b of the tapered portion 42 with respect to the axial center X4 is larger than the radial dimension D3 with respect to the axial center X2 of the insertion hole 71 of the terminal 7. Therefore, when the pin 4 is inserted into the insertion hole 71, the peripheral surface of the tapered portion 42 comes into contact with the insertion hole 71 during the insertion.

As shown in FIG. 1, a plurality of such pins 4 are provided in the housing 2. More specifically, the plurality of pins 4 are arranged side by side along the width direction Y.

In the joint box 1 having the above configuration, the terminal 7 is assembled to the pin 4 as follows. Hereinafter, the work of assembling the terminal 7 to the pin 4 will be described with reference to FIGS. 3 and 4.

First, as shown in FIG. 1, the operator deforms the terminals of the cable 50s of each unit of the cable unit 6 so as to be separated from each other. The operator then separates the pin 4 and the terminal 7 in the thickness direction Z and the axial center of the tapered portion 42 of the pin 4 in the length direction X and the width direction Y, as shown in FIG. The pin 4 and the terminal 7 are arranged so that the X4 and the axis X2 of the insertion hole 71 of the terminal 7 are aligned with each other.

The pin 4 and the terminal 7 have a radial dimension D1 with respect to the axial center X4 of the first portion 42a located at the tip of the tapered portion 42, which is smaller than the radial dimension D3 with respect to the axial center X2 of the insertion hole 71. Therefore, when the operator brings the terminal 7 close to the pin 4, the first portion 42a located at the tip of the tapered portion 42 of the pin 4 enters the insertion hole 71 of the terminal 7.

The pin 4 and the terminal 7 have a radial dimension D2 with respect to the axial center X4 at the second portion 42b located on the most proximal side of the tapered portion 42, and the radial dimension D2 with respect to the axial center X2 of the insertion hole 71 of the terminal 7. Greater than Therefore, when the operator moves the terminal 7 to one of the thickness directions Z so that the terminal 7 is close to the bottom wall 21 (in the following description, the terminal 7 which is one direction in the thickness direction Z is moved. The direction closer to the bottom wall 21 is referred to as the insertion direction W (see FIG. 4)), and during the insertion of the terminal 7 into the tapered portion 42 of the pin 4, the peripheral surface of the tapered portion 42 becomes the tip portion 74a of the protruding portion 74. Contact. Since the protruding portion 74 is deformably formed on the terminal 7, when the peripheral surface of the tapered portion 42 comes into contact with the tip portion 74a of the protruding portion 74, the protruding portion 74 is deformed as shown in FIG. More specifically, the protruding portion 74 is bent with respect to the terminal body 70 so that the tip end portion 74a is located above and the base end portion 74b is located below with respect to the insertion direction W.

When the operator further moves the terminal 7 toward the back side of the insertion direction W (the direction closer to the bottom wall 21), the angle at which the terminal body 70 and the protruding portion 74 intersect increases. When the insertion hole 71 passes through the tapered portion 42 of the pin 4 and the columnar portion 41 of the pin 4 is located inside the insertion hole 71, the deformation of the protruding portion 74 stops, and as shown in FIG. 5, the terminal body 70 (In the insertion direction W, the tip portion 74a of the protrusion 74 is located on the tip side of the pin 4, and the base end portion of the protrusion 74 is located on the base end side of the pin 4. The terminal 7 can be temporarily fixed to the pin 4 in the deformed state in which the 74b is located).

By performing the same work as above, the operator attaches the terminals 7 located at the terminals of the cables 51a, 51b, 52a, 52b, 53a, 53b, 53c, and 54 to the pins 4, respectively, as shown in FIG. Assemble and temporarily fix the terminal 7 and the cable 5 to the pin 4.

The operator then confirms whether or not the terminal 7 is assembled in the proper position with respect to the pin 4. At the time of this confirmation, if the position of the pin 4 temporarily fixing the terminal 7 is incorrect, the operator removes the terminal 7 from the pin 4 without cutting the cable 5, and then removes the terminal 7. It can be temporarily fixed to the regular pin 4. As a result, the joint box 1 can improve the handleability.

After that, the operator electrically connects the pin 4 and the terminal 7 by welding, fixes the terminal 7 to the pin 4, and electrically connects the plurality of terminals 7 to each other. The different cables 5 are electrically connected to each other.

After that, the operator attaches the cover 30 to the case body 20 by fitting the claw portion 27 and the fitting hole 36, and completes the assembling work of the housing 2.

As shown in FIG. 6, the joint box 1 has a terminal 7d located at the terminal of the unit configuration cable 51a of the first cable unit 61 assembled to the pin 4d and a terminal located at the terminal of the unit configuration cable 51b. 7e is attached to pin 4e.

In the joint box 1, the terminal 7f located at the terminal of the unit configuration cable 52a of the second cable unit 62 is assembled to the pin 4e, and the terminal 7g located at the terminal of the unit configuration cable 52b is assembled to the pin 4f. is there.

In the joint box 1, unit configuration cables 51b and 52a of different cable units 61 and 62 are electrically connected via terminals 7e and 7f.

In the joint box 1, the terminal 7a located at the terminal of the unit configuration cable 53a of the third cable unit 63 is assembled to the pin 4a, and the terminal 7b located at the terminal of the unit configuration cable 53b is assembled to the pin 4b. There is, and the terminal 7c located at the terminal of the unit configuration cable 53c is assembled to the pin 4c.

In the joint box 1, the terminal 7j located at one terminal of the first connection cable 54a is assembled to the pin 4d, and the terminal 7i located at the other terminal is assembled to the pin 4c. The pin 4d in the present embodiment corresponds to the first pin of the pair of pins to which the pair of terminals 7i and 7j of the connection cable 54a are assembled, and the pin 4c corresponds to the second pin of the pair of pins. Equivalent to.

In the connection cable 54a, one terminal 7j is assembled to the pin 4d, the other terminal 7i is assembled to the pin 4c, and the unit configuration cable 51a is assembled to the pin 4d via the one terminal 7j and the other terminal 7i. (Other cable 5) and the unit configuration cable 53c (other cable 5) assembled to the pin 4c are electrically connected.

Further, in the joint box 1, the terminal 7k located at one terminal of the connection cable 54b is assembled to the pin 4f, and the terminal 7h located at the other terminal is assembled to the pin 4b. The pin 4f in the present embodiment corresponds to the first pin of the pair of pins to which the pair of terminals 7h and 7k of the connection cable 54b are assembled, and the pin 4b becomes the second pin of the pair of pins. Equivalent to.

In the connection cable 54b, one terminal 7k is assembled to the pin 4f, the other terminal 7h is assembled to the pin 4b, and the unit configuration cable 52b is assembled to the pin 4f via the one terminal 7k and the other terminal 7h. (Other cable 5) and the unit configuration cable 53b (other cable 5) assembled to the pin 4b are electrically connected.

Further, in the joint box 1, the cable 5 is not connected to the pin 4g and the pin 4h.

Further, in the state where the housing 2 is assembled, a plurality of unit configuration cables 50 are inserted into the housing 2 through the insertion port 28 of the housing 2. In addition, the space portion 32 of the housing 2 is formed with an open space portion 32b that is adjacent to the pin holding space portion 32a and is located on one side of the length direction X and includes the insertion port 28. Further, the space portion 32 of the housing 2 is located on the other side in the length direction X, and the closed space portion 32c is formed by the bottom wall 21, the side walls 22, 23, the one end wall 24, and the cover body 31. .. The closed space portion 32c is located on the side opposite to the open space portion 32b with the terminal 7 and the pin 4 housed in the pin holding space portion 32a interposed therebetween in the length direction X. The plurality of unit configuration cables 51a, 51b, 52a, 52b, 53a, 53b, and 53c are provided in the open space portion 32b. The connection cable 54a and the connection cable 54b are provided in the closed space portion 32c.

As described above, the joint box 1 according to the present embodiment has the following configuration. The terminal 7 has a terminal body 70, an insertion hole 71 formed in the terminal body 70 into which the pin 4 is inserted, and a protruding portion 74 formed in the terminal body 70 so as to project toward the insertion hole 71 and deformable by the pin 4. Have. With this configuration, when the pin 4 is inserted into the insertion hole 71 of the terminal 7, the protruding portion 74 in contact with the pin 4 is deformed, and the terminal 7 can be temporarily fixed to the pin 4. Therefore, in the joint box 1, if the position of the pin 4 temporarily fixing the terminal 7 is incorrect, the terminal 7 is removed from the pin 4 without cutting the cable 5, and then the terminal 7 is properly fixed. Can be temporarily fixed to the pin 4 of. As a result, the joint box 1 can improve the handleability. In addition, the joint box 1 of the present embodiment does not need to secure a part of the unit configuration cable 50 to be cut when a connection error is found, so that the unit configuration cable 50 can be shortened and the material is wasted. It can be suppressed from being used.

In addition, the joint box 1 according to the present embodiment has the following configuration. The plurality of cables 5 include a unit configuration cable 50 in which a terminal 7 is attached to one end and a plurality of cables are bundled to form a cable unit 6, and unit configuration cables 50 between different cable units 6 are electrically connected via the terminal 7. Be connected. Therefore, the joint box 1 can directly join the unit configuration cables 50 of different cable units 6 to each other via the pin 4 via the terminal 7. The handleability can be further improved.

Further, the joint box 1 according to the present embodiment has the following configuration. In the connection cable 54, one terminal 7 is assembled to the first pin 4, the other terminal 7 is assembled to the second pin 4, and the first pin is passed through the one terminal 7 and the other terminal 7. The other cable 5 assembled to the 4 and the other cable 5 attached to the second pin 4 are electrically connected. Therefore, since the joint box 1 can electrically connect different cables 5 to each other via the connection cable 54, it is possible to prevent the plurality of cables 5 from crossing each other, and the plurality of cables 5 can be prevented from crossing each other. The connection status can be easily seen. As a result, the joint box 1 can be further improved in handleability.

Further, the joint box 1 according to the present embodiment has the following configuration. The connection cable 54 is provided in the closed space 32c. Therefore, the joint box 1 can be effectively used without wasting the space 32. Further, in the joint box 1, since the plurality of unit configuration cables 50 are provided in the open space portion 32b and the connection cable 54 is provided in the closed space portion 32c, the unit configuration cable 50 and the connection cable 54 intersect in the intersecting direction. Can be suppressed and the connection state of the plurality of cables 5 can be easily seen. As a result, the joint box 1 can be further improved in handleability.

Further, the joint box 1 according to the present embodiment has the following configuration. The housing is provided with a pair of movement restricting members 29a and 29b arranged so as to have a separation distance corresponding to the thickness dimension of the unit constituent cable 50. Therefore, in the state where the terminal 7 is assembled to the pin 4, the movement restricting members 29a and 29b restrict the unit constituent cable 50 from moving in the width direction Y of the housing 2. As a result, the joint box 1 restricts the movement of the unit constituent cable 50 in the width direction Y by a pair of movement restricting members 29a and 29b, and when the cover 30 is attached to the case body 20, the case body 20 and the cover 30 It is possible to prevent the unit configuration cable 50 from being caught between them.

Further, the joint box 1 according to the present embodiment has the following configuration. The housing 2 is provided with electrically insulating partition walls 39 at intermediate positions between two adjacent pins 4 in the width direction Y. Therefore, the joint box 1 can reduce the arrangement interval between the pins 4 and the terminals 7 in the width direction Y while maintaining the electrical insulation between the adjacent pins 4 and the terminals 7. The joint box 1 can be miniaturized. Further, since the joint box 1 of the present embodiment is provided with the partition wall portion 39 between the pin 4 and the pin 4 in the width direction Y, the joint box 1 is adjacent to the width direction Y from one arbitrarily selected terminal 7. The creepage distance to the other terminal 7 can be increased. Therefore, the joint box 1 does not need to be provided with the insulating member by filling the space 32 of the housing 2 with an electrically insulating resin or the like.

In addition, in the thickness direction Z of the pin 4 of the above-described embodiment, the diameters with respect to the axial centers X3 and X4 between the columnar portion 41 and the proximal end side of the tapered portion 42 in the direction opposite to the insertion direction W. An enlarged diameter portion (not shown) may be provided in which the dimension in the direction gradually increases. The enlarged diameter portion of the pin 4 makes it easy to remove the terminal 7 from the pin 4.

[Modification 1]
Next, a modification of the joint box 1A will be described with reference to FIGS. 7 to 9. In the joint box 1A of the modified example 1, the same components and parts as those of the joint box 1 of the embodiment are designated by the same reference numerals, the description thereof will be omitted, and only the different components and parts will be described.

The joint box 1A of the first modification has a terminal 700a and a pin 400a. The terminal 700a has a terminal body 70a, an insertion hole 71a, a wire caulking portion 72, a connecting portion 73, and a protruding portion 175.

The terminal body 70a is, for example, flat and formed in a rectangular frame shape. The terminal body 70a has an inner edge 47 located on the insertion hole 71a side and an outer edge 48 located on the side opposite to the insertion hole 71a side. The insertion hole 71a has a first portion 170, a second portion 171 and a third portion 172. The first portion 170 extends in the longitudinal direction X. The second portion 171 extends from one end of the first portion 170 in the length direction X in the width direction Y. The third portion 172 extends in the width direction Y from the other end of the first portion 270 in the length direction X.

The protruding portion 175 is formed so as to project toward the insertion hole 71a side of the terminal body 70a and can be deformed by the pin 400a. The protrusion 175 is composed of two protrusions 175a and 175b that face each other in the width direction Y. Each protruding portion 175a and 175 has a base end portion 174b located on the terminal body 70a side and a tip end portion 174a relatively separated from the terminal body 70a with respect to the base end portion 174b.

The terminal body 70a further has a notch 179 extending from the inner edge 47 toward the outer edge 48 side of the base end portion 174b of the protrusions 175a and 175b. Notches 179 are arranged at both ends of each of the protrusions 175a and 175b in the width direction. The notch 179 is formed so as to extend from the inner edge 47 (that is, the insertion hole 71a) of the terminal body 70a to the middle of the terminal body 70a.

The pin 400a has a columnar portion 41, a tapered portion 141, and a gap portion 49 located between the tapered portion 141 and the columnar portion 41. The tapered portion 141 is formed, for example, in a hemispherical shape having a constant plate thickness, has the smallest radial dimension of the first portion 142a located on the most tip side, and is located on the base end side in the thickness direction Z. As the distance increases, the radial dimension with respect to the axis X4 gradually increases. Therefore, in the tapered portion 141, the dimension of the second portion 142b located closest to the proximal end side in the radial direction with respect to the axial center X4 is the largest.

More specifically, the gap portion 49 is located between the proximal end side of the tapered portion 141 and the distal end side of the columnar portion 41. The columnar portion 41 is cylindrical, while the tapered portion 141 is a hemispherical shape having a constant plate thickness. Therefore, the gap portion 49 is in the thickness direction Z, and the dimension of the space portion located on the base end side of the tapered portion 141 is the largest, and the dimension of the space portion becomes smaller toward the tip end side of the tapered portion 141. The size of the space located on the most tip side is the smallest (see FIG. 9). The gap portion 49 can insert the tip portion 174a of the protruding portion 175a and 175b.

FIG. 8 is a perspective view of the joint box 1A of the modified example 1 in a state where the pin 400a is inserted into the insertion hole 71a of the terminal 700a, and FIG. 9 is a cross-sectional view of the state. In this joint box 1A, when the pin 400a is inserted into the insertion hole 71a of the terminal 700a, the tip portion 174a of the protruding portion 175a and 175b is in contact with the peripheral surface of the columnar portion 41.

The joint box 1A according to the first modification has the following configuration. The pin 400a has a columnar portion 41 located on the proximal end side of the tapered portion 141, and a gap portion 49 located between the tapered portion 141 and the columnar portion 41. The tip portion 174a of the protruding portion 175a and 175b can be inserted into the gap portion 49. Therefore, in the joint box 1A, when the terminal 700a moves to the tip end side of the pin 400a, the tip portion 174a of the protruding portion 175a and 175b is located between the columnar portion 41 and the tapered portion 141. Enter part 49. As a result, the joint box 1A can prevent the terminal 700a from falling off from the pin 400a.

The joint box 1A according to the first modification has the following configuration. The terminal body 70a has an inner edge 47 located on the insertion hole 71a side, an outer edge 48 located on the opposite side of the insertion hole 71a, and the protrusion 175a and 175b from the inner edge 47 to the outer edge 48 side at the base end portion 174b. It has an extending notch 179. Therefore, the joint box 1A can easily deform the protruding portion 175 when the terminal 700a is assembled to the pin 400a.

[Modification 2]
Next, a modification 2 of the joint box 1B will be described with reference to FIG. In the joint box 1B of the second modification, the same components and parts as those of the joint box 1 of the embodiment are designated by the same reference numerals and the description thereof will be omitted, and only different components and parts will be described.

The joint box 1B of the second modification has a terminal 7 and a pin 400b. The pin 400b has a columnar portion 41, a tapered portion 402, and a diameter-expanded portion 43. The diameter-expanded portion 43 is located on the proximal end side of the tapered portion 402 in the thickness direction Z, and the radial dimension gradually increases from the proximal end side to the distal end side.

The diameter-expanded portion 43 has a length dimension L2 in the thickness direction Z smaller than the length dimension L1 in the thickness direction Z of the tapered portion 402.

The joint box 1B according to the second modification has the following configuration. The pin 400b has a diameter-expanded portion 43 that is located on the proximal end side of the tapered portion 402 and whose radial dimension gradually increases from the proximal end side to the distal end side. Therefore, in the joint box 1B, it is easy to remove the terminal 7 from the pin 400b by the enlarged diameter portion 43 in the state where the terminal 7 is assembled to the pin 400b.

In addition, the joint box 1B according to the second modification has the following configuration. The diameter-expanded portion 43 has a length dimension L2 in the thickness direction Z smaller than the length dimension L1 in the thickness direction Z of the tapered portion 402. Therefore, in the joint box 1B, it is easy to remove the terminal 7 from the pin 400b, and it is possible to prevent the pin 400b from becoming long in the thickness direction Z. As a result, the joint box 1B can prevent the housing 2 from becoming large.

[Modification 3]
Next, a modification 3 of the joint box 1C will be described with reference to FIG. In the joint box 1C of the modified example 3, the same components and parts as those of the joint box 1 of the embodiment are designated by the same reference numerals, the description thereof will be omitted, and only different components and parts will be described.

The joint box 1C of the modification 3 has a terminal 700c and a pin 4. The terminal 700c has a terminal body 70b, an insertion hole 71b, a wire caulking portion 72, a connecting portion 73, and a protruding portion 274. The same pin 4 as in the first embodiment is inserted into the insertion hole 71b of the terminal 700c.

The terminal body 70b is, for example, flat and has an annular shape. The insertion hole 71b has a first portion 270, a second portion 271, and a third portion 272. The first portion 270 extends in the longitudinal direction X. The second portion 271 extends from one end of the first portion 270 in the length direction X in the width direction Y. The third portion 272 extends in the width direction Y from the other end of the first portion 270 in the length direction X.

The projecting portion 275 is formed, for example, in a flat plate shape and a rectangular shape, and is formed so as to project toward the insertion hole 71b side of the terminal body 70b so as to be deformable by the pin 4. The protrusion 275 is composed of two protrusions 275 and 275b that face each other in the width direction Y. Each of the protruding portions 275a and 275b has a base end portion 274b located on the terminal body 70b side and a tip end portion 274a relatively separated from the terminal body 70b with respect to the base end portion 274b.

The joint box 1C according to the third modification has the following configuration. The terminal body 70c is flat and formed in an annular shape, and the protrusion 275 is flat and formed in a rectangular shape. Therefore, the joint box 1C can be easily formed by punching, for example, from a flat metal, for example, by simplifying the configuration of the terminal 700c. As a result, the production of the joint box 1C can be facilitated.

[Modification example 4]
Next, a modification 4 of the joint box 1B will be described with reference to FIGS. 12 and 13. In the joint box 1D of the modified example 4, the same components and parts as those of the joint box 1 of the embodiment are designated by the same reference numerals, the description thereof will be omitted, and only different components and parts will be described.

The joint box 1D of the modified example 4 has a terminal 700d and a pin 400b. The terminal body 70b has a notch 279 and a deformation guiding portion 280. In the notch 279 and the terminal body 70b, the protrusions 175a and 175b extend radially from the inner edge 47 to the outer edge 48 of the base end portion 174b with respect to the axial center of the terminal body 70b. Notches 279 are arranged at both ends of each of the protrusions 275a and 275b in the width direction. The notch 279 is formed so as to extend from the inner edge 47 (that is, the insertion hole 71b) of the terminal body 70b to the middle of the terminal body 70b.

The deformation guiding portion 280 extends along the boundary between the protruding portions 275a and 275b and the terminal body 70b. The deformation guide portion 280 is arranged on the tip end side of the pin 400b in the thickness direction Z in a state where the terminal 700d is assembled to the pin 400b, and is arranged from the tip end side to the base end side to the middle of the thickness direction Z. .. It is formed in a groove shape. The deformation guiding portion 280 extends from the notch 279 located on one side to the notch 279 located on the other side in the length direction X.

The joint box 1D according to the fourth modification has the following configuration. The terminal body 70b has a deformation guiding portion 280 extending along the boundary between the protrusions 275a and 275b and the terminal body 70b. Therefore, in the joint box 1D, when the terminal 7 is attached to the pin 400b, the deformation guiding portion 80 makes it easier to deform the protruding portions 275a and 275b when the terminal 7 is attached to the pin 400b.

Moreover, the joint box 1D according to the modified example 4 has the following configuration. The terminal body 70b has a notch 279 and a deformation guiding portion 280, and the deformation guiding portion 280 extends from the notch 279 located on one side to the notch 279 located on the other side in the length direction X. To do. Therefore, in the joint box 1D, when the terminal 7 is assembled to the pin 400b by the notch 279 and the deformation guiding portion 280, it becomes easier to deform the protruding portions 275a and 275b.

The joint boxes 1 and 1A described above have a cable unit 61 and 62 having two cables 5 and a third cable unit having three cables 5. However, the present invention is not limited to this, and the number of cables 5 included in the cable unit 6 is not limited to two and three, and may include a plurality of four or more cables 5.

Further, the above-mentioned joint boxes 1, 1A, pins 4, 104 having a columnar portion 41 and tapered portions 42, 141 have been described. However, the present invention is not limited to this, and the pin 4 may be formed only by the columnar portion 41 without having the tapered portions 42 and 141.

Further, the columnar portions 41 of the pins 4 and 104 of the joint boxes 1 and 1A described above have been described as having a columnar shape. However, the present invention is not limited to this, and the columnar portion may have other shapes such as a square columnar portion.

Further, the tapered portion 42 of the pin 4 of the joint box 1 described above has a truncated cone shape, and the tapered portion 141 of the pin 104 of the joint box 1A has a semicircular spherical shape. However, the present invention is not limited to this, and the tapered portion may have other shapes such as a quadrangular pyramid.

Further, in the above-described embodiment, the pins 4 and 104 are formed of an electrically conductive metal material, and the pins 4 and 104 are welded to the terminals 7 and 7a to form the terminals 7 and 104 with respect to the pins 4 and 104. The one that permanently fixes 7a has been described. However, the present invention is not limited to this, and the pins 4 and 104 may be formed of an electrically insulating material (for example, a synthetic resin). When the pins 4 and 104 are made of an electrically insulating material, the pins 4 and 104 are finally fixed to the terminals 7 and 7a with screws and fixing brackets.

Further, in the joint boxes 1 and 1A, when the pins 4 and 104 are formed of an electrically conductive metal material, a plating layer is formed on the peripheral surfaces of the pins 4 and 104 with a metal such as copper and tin. You may. If the plating layer is formed on the peripheral surface of the pin in this way, the joint box 1 can prevent the plating layer of the pin from being scraped off and the terminal from falling off from the pin when the terminal is temporarily fixed to the pin.

Further, the joint boxes 1 and 1A are made of a synthetic resin such as ABS resin (acrylonitrile-butadiene-styrene resin), which is relatively easily deformed when the pins 4 and 104 are formed of an electrically insulating material. It is preferable to use. When such a synthetic resin is used, when the terminal is temporarily fixed to the pin, the pin is easily deformed, and the work of temporarily fixing the terminal to the pin becomes easy.

1, 1A, 1B, 1C, 1D Joint Box 2 Housing 28 Entrance 29a, 29b Movement control member 32a Pin holding space 32b Open space 32c Closed space 4, 4a, 4b, 4c, 4d, 4e, 4f, 4g, 4h, 400a, 400b Pin 49 Gap 5 Cable 50, 51a, 51b, 52a, 52b, 53a, 53b, 53c Unit configuration cable (cable)
54, 54a, 54b connection cable (cable)
61, 62, 63 Cable units 7, 7a, 7b, 7c, 7d, 7e, 7f, 7g, 7h, 7i, 7j, 7k, 700a, 700c, 700d Terminal 70, 70a, 70b, 70c Terminal bodies 71, 71a, 71b Insertion hole 74a, 174a, 274a Tip part 74b, 174b, 274b Base end part 74, 175, 175a, 175b, 275, 275a, 275b Protruding part

Claims (6)

With the housing
Pins located inside the housing and formed in columns,
It is equipped with a plurality of terminals that are attached to the terminals of a plurality of cables and are assembled to the pins and electrically connected to each other.
The pin has a tapered portion whose radial dimension gradually decreases from the proximal end side to the distal end side.
The terminal includes a terminal body, an insertion hole formed in the terminal body into which the tapered portion of the pin is inserted, and a protrusion formed in the terminal body so as to project toward the insertion hole and deformable by the pin. Characterized by having
Joint box. The plurality of cables include a unit configuration cable in which the terminal is attached to one end and a plurality of cables are bundled to form a cable unit, and the unit configuration cables of different cable units are electrically connected via the terminal. Ru,
The joint box according to claim 1. A plurality of the pins are provided in the housing.
The plurality of cables include a connection cable having the terminals attached to both ends.
The connection cable has one terminal assembled to the first pin, the other terminal assembled to the second pin, and the first terminal via the one terminal and the other terminal. Electrically connect the other cable attached to the pin to the other cable attached to the second pin.
The joint box according to claim 1 or 2. The housing is housed in the pin holding space where the terminal and the pin are located, an open space including an insertion port adjacent to the pin holding space for inserting the unit configuration cable, and the pin holding space. It has the terminal and the closed space located on the opposite side of the pin from the open space.
The connection cable is provided in the closed space.
The joint box according to claim 3. The housing is provided with a pair of movement restricting members that are arranged so as to have a separation distance corresponding to the thickness dimension of the unit configuration cable and that restrict the movement of the unit configuration cable in the width direction of the housing. It is provided,
The joint box according to claim 2. The pin has a columnar portion located on the base end side of the tapered portion and a gap portion located between the tapered portion and the columnar portion.
The tip portion of the protruding portion can be inserted into the gap portion.
The joint box according to any one of claims 1 to 5.

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