JP6286189B2 - Connector unit and wiring structure - Google Patents

Description

  The present invention relates to a connector unit and a wiring structure including the connector unit.

  Conventionally, electric wires for transmitting electric power from a battery and a control signal from a control device to an electronic device are routed in the vehicle. When routing these wires, it is necessary to properly regulate the routing route and protect the wires. For example, Patent Documents 1 and 2 disclose a connector including a cover for realizing protection and path regulation of an electric wire drawn out from the connector to the outside.

  Patent Document 3 discloses an example in which an electric wire is routed inside a transmission to perform signal transmission between electronic components and signal transmission with the outside. This type of conventional transmission is necessary for controlling the transmission gear mechanism in the transmission case and changing the rotation of the input shaft to the desired rotational speed and transmitting it to the output shaft side. Electronic components such as various sensors and solenoids, a substrate for holding these electronic components, and electric wires for signal transmission between the electronic components and signal transmission with the outside.

JP2013-105524A JP-A-7-153521 JP 2004-028590 A

  FIG. 7 is a plan view schematically showing an example of a wiring form of a wire inside a conventional mission case. In the example shown in FIG. 7, a base member 160 for fixing electronic components and the like in a rectangular mission case 170 and a plurality of (seven in the example of FIG. 7) fixed to the base member 160. The solenoid 150, a mating connector 140 (for example, a male connector) fixed to each side of the solenoid 150, a connector 120 (for example, a female connector) that fits the mating connector 140, and the connector 120 are led out and guided. An electric wire 180 extended to the outlet 171 and led out to the outside from the outlet 171 is accommodated. The electric wire 180 includes a branch line 181 drawn out from the connector 120 and a trunk line 182 in which the branch lines 181 are bundled. The mission case 170 is liquid-tightly covered with a separate cover (not shown). Then, oil is filled in the internal space surrounded by the mission case 170 and the cover.

  In such a conventional wiring form, as shown in FIG. 7, since the electric wires 180 led out from the connector 120 are led out toward the outlet 171 respectively, it is difficult to regulate the wiring route of the electric wires 180. It was. For this reason, the wiring route of the electric wire 180 may be disturbed as indicated by reference numeral 185 in FIG. In this case, there is a possibility that the electric wire 180 is sandwiched between the mission case 170 and the cover during the sealing operation, and the liquid tightness inside the mission case 170 cannot be maintained.

  In order to prevent such pinching, it is conceivable to use a connector as shown in Patent Documents 1 and 2, but since the connector is a large molded product, a relatively wide mounting space is required. The case 170 becomes large. In this case, the transmission case 170 is enlarged because a fixing mechanism for attaching the connector is required. Furthermore, when the connector is used, the routing route is fixed, so that the flexibility in changing the design is poor and it is difficult to divert the parts.

  Further, although it is conceivable to bundle the main line 182 portion of the electric wire 180 with a binder (not shown), it is difficult to attach the electric wire 180 so that the routing route of the electric wire 180 is appropriately regulated, and the cost is high. Moreover, in order to prevent pinching, it is possible to make wide the space between the connector 120 and the side surface of the mission case 170, but the mission case 170 will be enlarged. Moreover, in the conventional wiring form, since the electric wire 180 is directly pulled out from the connector 120, when a tensile force acts on the electric wire 180, a force is easy to act on the terminal accommodated in the connector 120, and a connection failure etc. are caused. there is a possibility. Furthermore, in the conventional wiring form, since the drawing surface side of the branch line 181 of the connector 120 is opened, there is a possibility that fine metal fragments (contamination) may enter the connector 120 from the opening, causing a short circuit. There was a possibility.

  On the other hand, the present applicant devised a connector unit as shown in FIGS. 8 and 9 as a prior invention of the present invention. FIG. 8 is a plan view showing an example of a wiring arrangement in a mission case when the connector unit according to the prior invention is used, and FIG. 9 is an electric wire when the connector unit according to the prior invention is used. It is a perspective view which shows the arrangement | positioning form. The connector unit according to the prior invention is the same as the insertion type connector unit 30C (see FIGS. 1 and 6) of the embodiment described later. Further, the connector unit (insertion type connector unit 30C) according to the preceding invention is common to the connector units (first binding type connector unit 30A and second binding type connector unit 30B described later) according to the embodiment as will be described later. The connector 20 is provided.

  The insertion-type connector unit 30C is formed in a bottomed cylindrical shape having a connector 20 from which a branch line 81 branched from a trunk line 82 is drawn, and a bottom surface and a side surface, and is assembled to a drawing surface side of the branch line 81 of the connector 20 10C, and is accommodated in the mission case 70. The connector 20 accommodates a terminal (for example, a female terminal, not shown) that is electrically connected to the tip of the branch wire 81, and fits with the mating connector 40 fixed to the side surface of the solenoid 50. The mating connector 40 contains a plurality of mating terminals (for example, male terminals, not shown) that are electrically connected to the terminals. When the connector 20 and the mating connector 40 are fitted together, both ends thereof are accommodated. The child is electrically connected.

  A wire insertion port 16 is formed on the opposing side surface of the connector cover 10, and as shown in FIG. 9, a trunk line 82 is inserted into the wire insertion port 16 and a branch line 81 is drawn from the wire insertion port 16. As shown in FIG. 9, the trunk line 82 from the adjacent insertion-type connector unit 30C is inserted into the wire insertion port 16 and passes through the inside of the connector cover 10C, and the trunk line 82 and the drawn branch line 81 merge. The main line 82 is routed to the next insertion type connector unit 30C side. That is, the connector cover 10 </ b> C is an insertion type connector cover in which the branch line 81 and the trunk line 82 are inserted into the wire insertion port 16. Thus, in the insertion type connector unit 30C, the wiring direction of the branch line 81 and the trunk line 82 is guided by the connector cover 10C. Thus, according to the insertion type connector unit 30C, the routing direction can be regulated by appropriately guiding the routing direction of the branch line 81 and the trunk line 82 by the connector cover 10C.

  According to the routing form shown in FIG. 8 using such a prior invention, the wires can be concentrated and routed by the connector cover 10C, so that space saving can be realized. Moreover, since the connector 20 can be directed in the same direction at the time of a fitting operation with the mating connector 40 by the connector cover 10C, the fitting operation becomes easy. Moreover, although the details will be described later, since the drawing direction of the electric wire 80 can be changed in accordance with the change of the routing route, the flexibility with respect to the design change is improved.

  Moreover, according to the routing form shown in FIG. 8 using the prior invention, the routing route can be regulated by the connector cover 10C, so that the binding by the binder can be omitted. Further, the mission case 70 can be reduced in size. Moreover, since the electric wire 80 is pulled out via the connector cover 10 </ b> C, even if a tensile force acts on the electric wire 80, the force hardly acts on the terminals accommodated in the connector 20. Further, since the lead-out surface side of the connector 20 is covered with the connector cover 10C, it is difficult for contaminants to enter from the opening.

  Thus, according to the routing form using the insertion type connector unit 30C according to the prior invention, the problems of the prior art can be solved. However, in the insertion-type connector unit 30C according to the prior invention, the connector cover 10C is an insertion-type connector cover in which the branch line 81 and the trunk line 82 are inserted into the electric wire insertion port 16, and is configured to be rotatable with respect to the trunk line 82. ing. For this reason, the entire insertion-type connector unit 30C rotates with respect to the main line, and the orientation of the plurality of connectors 20 may not be aligned (see FIG. 7A described later). Thereby, there was a possibility that the workability of attachment to the counterpart connector 40 may not be good.

  This invention is made | formed in view of the situation mentioned above, The objective is to provide the connector unit and wiring structure which can improve attachment workability | operativity.

In order to achieve the above-described object, the connector unit and the wiring structure according to the present invention are characterized by the following points.
(1) a connector that accommodates a terminal electrically connected to the tip of a branch line branched from the trunk line;
A connector cover that is formed into a bottomed cylindrical shape having a side surface and a bottom surface and is assembled from the opening side to the branch wire drawing surface side of the connector, and a connector cover having a branch wire outlet formed on the side surface ;
A wiring direction of the branch line and the trunk line by the connector cover such that the branch line is drawn out from the branch line outlet and the trunk line extends along the bottom surface outside the bottom surface Is a connector unit that is guided,
A binding band attached to the connector cover for binding the trunk line;
Is provided.

  According to the connector unit (1), the trunk line is bound to the connector cover by the binding band, and the connector unit and the trunk line are firmly fixed. That is, the connector unit according to the above-described prior invention is an insertion-type connector unit, and the connector cover is an insertion-type connector cover, whereas the connector unit (1) is a bundling-type connector unit, and its connector The cover is a bundling connector cover that firmly binds the trunk line. For this reason, it can prevent that the whole connector unit rotates with respect to a trunk line, and can improve the attachment workability | operativity at the time of attaching a connector with respect to the other party connector.

  In the connector unit (1), any type of binding band can be attached to the connector cover as long as it can be attached to the connector cover. For example, a plurality of types of bundling bands having different band lengths for bundling trunk lines are prepared, and a bundling band of a type suitable for the number of trunk lines to be bundled (that is, the thickness of the trunk line) is selected and used. Is assumed. By using a binding band suitable for the number of wires, the wires can be bound without any gaps regardless of the number of wires. Alternatively, it is assumed that a plurality of types of binding bands formed of synthetic resins having different heat resistance characteristics are prepared, and the types of binding bands suitable for the use environment are selected and used. For example, when the connector unit is used in a mission case, depending on the specifications of the mission case, heat resistance to a relatively high temperature range of about 150 ° C. to 160 ° C. may be required. In some cases, heat resistance for only a relatively low temperature range of about ° C to 90 ° C may be sufficient. In such a case, it is conceivable to use a binding band having high heat resistance that can cope with any use environment, but using a synthetic resin with good heat resistance increases the cost. On the other hand, if high heat resistance is not required, cost can be reduced if a binding band that can be used only in a low temperature range is selected and used.

  Further, in the connector unit (1) above, when the binding is not necessary, the binding band can be removed and used. Therefore, whether or not the binding band is attached can be changed according to the application.

(2) The connector unit of (1) above,
The connector cover has a locked portion formed on the side surface or the bottom surface,
The binding band has a locking portion,
The binding band is attached to the connector cover by engaging the locking portion and the locked portion.

  In the connector unit of (2), the connector cover and the binding band can be easily assembled by the engagement between the locking portion of the connector cover and the locked portion of the binding band.

(3) The connector unit of (1) above,
The binding band has a clamping part,
The binding band is attached to the connector cover by the sandwiching portion sandwiching the connector cover.

  According to the connector unit (3) above, since the binding band is attached to the connector cover by the clamping portion provided in the binding band, it is not necessary to provide a special structure for the attachment on the connector cover side. Therefore, the shape of the connector cover can be made common regardless of whether the binding band is attached or not, and the cost can be reduced.

(4) a connector for accommodating a terminal electrically connected to the tip of a branch line branched from the trunk line;
A connector cover that is formed in a bottomed cylindrical shape having a side surface and a bottom surface and is assembled to a drawing surface side of the branch line of the connector, thereby guiding a wiring direction of the branch line and the trunk line;
A branch wire outlet formed on the side surface through which the branch wire is drawn;
A binding band attached to the connector cover and binding the trunk line;
With
The binding band has a clamping part,
When the clamping part clamps the connector cover, the binding band is attached to the connector cover,
The clamping portion includes a claw portion that is engaged with the branch wire outlet of the connector cover.

  According to the connector unit of (4) above, the binding band can be firmly attached to the connector cover using the branch wire outlet of the connector cover formed to draw out the branch wire.

(5) A bundling type connector unit that is any one of the above (1) to (4), and an insertion type connector unit, and guides the trunk line and the branch line through a predetermined routing route. A routing structure,
The insertion-type connector unit includes the connector common to the bundling-type connector unit, and an insertion-type connector cover that is formed in a bottomed cylindrical shape having a bottom surface and a side surface and is assembled to the pull-out surface side of the connector. The wire insertion port is formed in the opposing side surface of the insertion type connector cover, the trunk line is inserted into the wire insertion port, and the branch line is drawn out from the wire insertion port.

As described above, in the insertion-type connector unit 30C according to the prior invention, the entire insertion-type connector unit 30C may be rotated with respect to the main line. On the other hand, rotation of the connector unit with respect to the main line can be prevented by using the bundled connector unit which is any one of the connector units (1) to (4).
Here, as shown in FIG. 7 and FIG. 8, when restricting the routing route of the electric wires (trunk line and branch line) using a plurality of connector units, rotation with respect to the trunk line is not necessarily prevented in all the connector units. There is no need. Therefore, as a configuration including both the bundling connector unit and the insertion type connector unit as in the wiring structure of the above (5), the bundling type connector unit is disposed at a location where rotation is to be prevented, and the other locations. It can be set as the structure which arrange | positions an insertion-type connector unit. With such a configuration, it is possible to reduce the number of bundling connector units that require a bundling operation of bundling bands and are expensive in product cost.
Moreover, when using the connector unit of said (1)-(4) as a binding type connector unit, comparatively many trunk lines can be bound by changing the kind of binding band attached as mentioned above. Therefore, as a configuration including both the bundling connector unit and the insertion type connector unit as in the wiring structure of (5) above, the bundling type connector unit is arranged at a place where a relatively large number of trunk lines are wired, It can be set as the structure which arrange | positions an insertion-type connector unit in a location other than that.

  ADVANTAGE OF THE INVENTION According to this invention, the connector unit which can improve attachment workability | operativity can be provided.

  The present invention has been briefly described above. Furthermore, the details of the present invention will be further clarified by reading through a mode for carrying out the invention described below (hereinafter referred to as an embodiment) with reference to the accompanying drawings.

FIG. 1 is a plan view schematically showing an example of a wiring form of an electric wire in a mission case when the wiring structure according to the embodiment is used. FIG. 2 is an exploded perspective view showing the first binding type connector unit and the male housing. FIG. 3A is a perspective view showing the first bundling type connector unit in a state where the main wires are bound, and FIG. 3B is a connection portion between the bundling band and the connector cover in the state of FIG. FIG. FIG. 4A is a perspective view showing the second binding type connector unit with the connector cover removed, and FIG. 4B shows the second binding with the connector cover attached and the trunk line bound. It is a perspective view which shows a type | mold connector unit. FIG. 5 is a plan view showing a wiring form of the electric wire using the wiring structure according to the embodiment. FIG. 6 is a view for explaining the function and effect of the connector unit according to the embodiment, and FIG. 6A is a perspective view showing an example of a wiring form when the connector unit according to the prior invention is used. FIG. 6B is a perspective view showing an example of a wiring form when the connector unit according to the embodiment is used. FIG. 7 is a plan view schematically showing an example of a wiring form of a wire inside a conventional mission case. FIG. 8 is a plan view showing an example of an arrangement form of electric wires in the mission case when the connector unit (insertion type connector unit) according to the prior invention is used. FIG. 9 is a perspective view showing an arrangement of electric wires when the connector unit according to the prior invention is used.

  Hereinafter, an embodiment of the present invention will be described with reference to FIGS.

FIG. 1 is a plan view showing an example of a wiring form of an electric wire in a mission case when the wiring structure according to the embodiment is used. In this embodiment, as shown in FIG. 1, a base member 60 for fixing an electronic component or the like in a rectangular mission case 70 and a plurality of (in this embodiment, 7.) From the solenoid 50, a mating connector 40 (for example, a male connector) fixed to the side surface of each solenoid 50, a connector 20 (for example, a female connector) that fits the mating connector 40, and the connector 20 An electric wire 80 that is drawn out and extends to the outlet 71 and is led out to the outside from the outlet 71 is accommodated. The electric wire 80 includes a branch line 81 drawn from each connector 20 and a trunk line 82 in which the branch lines 81 are bundled (see FIGS. 3B, 5B, and 9 described later). ). The branch line 81 and the trunk line 82 are arranged in the first binding type connector unit 30A including the connector 20 and the connector cover 10A, the second binding type connector unit 30B including the connector 20 and the connector cover 10B, and the connector 20. It is guided by an insertion-type connector unit 30C having a connector cover 10C. The mission case 70 is liquid-tightly covered by a separate cover (not shown). Then, oil is filled in the internal space surrounded by the mission case 70 and the cover.
The insertion type connector unit 30C is the connector unit according to the above-described prior invention shown in FIGS. The first binding type connector unit 30A and the second binding type connector unit 30B have a common connector 20, and the connector 20 is also common to the connector 20 of the insertion type connector unit 30C.

  First, the first binding type connector unit 30A will be described. FIG. 2 is an exploded perspective view showing the first binding type connector unit and the male housing, and FIG. 3A is a perspective view showing the first binding type connector unit in a state in which the trunk lines are bound, and FIG. These are sectional drawings which show the connection part of the binding band and connector cover in the state of Fig.3 (a).

  As shown in FIG. 2, the first united connector unit 30A is attached to the connector 20 from which the branch line 81 is drawn, the connector cover 10A assembled to the drawing surface 25 side of the branch line 81 of the connector 20, and the connector cover 10A. And a binding band 91 </ b> A for binding the trunk line 82. All of these members are formed of a synthetic resin. However, it is not necessary that all these members are made of the same synthetic resin. In particular, as will be described later, the binding band 91A may be formed of a synthetic resin having a different material.

  The connector 20 (for example, a female connector) includes a box-shaped housing 21 having a terminal housing chamber 22 formed therein, and a plurality of terminals (for example, female terminals) that are electrically connected to the distal ends of the branch lines 81. (Not shown) is accommodated in the terminal accommodating chamber 22. The connector 20 has a locking projection 23 that is locked to a locking portion 41 of a counterpart connector 40 (for example, a male connector) on the outer surface of the housing 21, and is fitted to the counterpart connector 40. The mating connector 40 contains a plurality of mating terminals (for example, male terminals, not shown) that are electrically connected to the terminals. When the connector 20 and the mating connector 40 are fitted together, both ends thereof are accommodated. The child is electrically connected.

  Further, on the outer surface of the housing 21 on the side of the lead-out surface 25, four locking protrusions 24 that are locked in locking holes 15 of the connector cover 10A described later are formed. The locking protrusions 24 are formed in the same shape at each of the four corners on the drawing surface 25 side. These four locking projections 24 can be locked in any of the four locking holes 15 of the connector cover 10 </ b> A, whereby the mounting angle of the connector cover 10 </ b> A with respect to the connector 20 can be changed. That is, the connector cover 10 can be attached to the connector 20 in a state rotated by 90 ° from the attachment angle (that is, both in the vertical and horizontal directions) other than the attachment angle shown in FIG. Can do. By changing the attachment angle in this manner, the direction in which the electric wire 80 is guided by the connector cover 10A can be changed.

  As shown in FIG. 2, the connector cover 10 </ b> A is formed in a bottomed cylindrical shape having a bottom surface 12 and four side surfaces and has an opening 11. As shown in FIG. 3A, the connector cover 10A is assembled from the opening 11 side to the drawing surface 25 side of the housing 21. Locking holes 15 that are locked to the locking protrusions 24 described above are formed at the four corners on the opening 11 side of the connector cover 10A. Further, the connector cover 10A has a branch wire outlet 17 formed on each of the opposing side surfaces, and a branch wire 81 is drawn from the branch wire outlet 17 as shown in FIG.

  Further, the connector cover 10 </ b> A has a locking recess 19 (locked portion) formed on the outer surface of the bottom surface 12. The locking recess 19 engages with a locking protrusion 95 of a binding band 91A described later, whereby the binding band 91A is attached to the connector cover 10A.

  The binding band 91 </ b> A includes a rectangular main body 92, a band 93 having a base end connected to the main body 92 and extending long, a band insertion hole 94 formed through the main body 92, and a main body 92. And a protruding projection 95 (locking portion). The band portion 93 is a member that is wound around the outer periphery of the trunk line 82, and is inserted into the band insertion hole 94 from the front end side, and is removed by a known retaining structure (not shown) formed inside the band insertion hole 94. Stopped. When the trunk line 82 is bundled, as shown in FIG. 3A, the band part 93 is wound around the trunk line 82 without a gap, and in this state, the band part 93 is prevented from being detached by the band insertion hole 94. Further, the locking projection 95 is inserted into the locking recess 19 and engaged with the locking recess 19 as shown in FIG. As a result, the binding band 91A is attached to the connector cover 10A.

  That is, as shown in FIG. 3A, the binding band 91A is attached to the connector cover 10A and firmly binds the trunk line 82. Either attachment to the connector cover 10A or bundling of the trunk line 82 may be performed first. As described above, the connector cover 10A is a bundling connector cover that binds the trunk line 82, and is different from the connector cover 10C according to the prior invention that is an insertion type connector cover.

  Next, the second binding type connector unit 30B will be described. FIG. 4A is a perspective view showing the second binding type connector unit with the connector cover removed, and FIG. 4B shows the second binding with the connector cover attached and the trunk line bound. It is a perspective view which shows a type | mold connector unit. The same components as those of the first binding connector unit 30A described above are denoted by the same reference numerals, and description thereof is omitted.

  As shown in FIGS. 4A and 4B, the second binding type connector unit 30B includes a connector 20 that is common to the first binding type connector unit 30A, and a connector that is assembled to the drawing surface 25 side of the connector 20. A cover 10B and a binding band 91B that is attached to the connector cover 10B and binds the trunk line 82 are provided. All of these members are formed of a synthetic resin. However, it is not necessary that all these members are made of the same synthetic resin. In particular, as will be described later, the binding band 91B may be formed of different synthetic resins.

  The connector cover 10B is the same as the connector cover 10A except that the connector cover 10B does not have the locking recess 19.

  The binding band 91 </ b> B is different from the binding band 91 </ b> A in that it has a clamping portion 96 instead of the locking projection 95. In other words, the binding band 91 </ b> B has a pair of sandwiching portions 96 that protrude from the left and right side surfaces of the main body 92 and bend forward. The sandwiching portion 96 has a pair of claw portions 97 formed by bending forward end portions further inward (that is, approaching each other).

  As shown in FIG. 4B, the binding band 91B is attached to the connector cover 10B when the clamping portion 96 clamps the side surface (bottom surface 12) of the connector cover 10B. At the time of attachment, the claw portion 97 is hooked (locked) to the branch wire outlet 17 of the connector cover 10B. Thereby, the binding band 91B is firmly attached to the connector cover 10B.

  Next, a routing method using the above-described first binding type connector unit 30A, the second binding type connector unit 30B, and the insertion type connector unit 30C will be described. FIG. 5 is a plan view showing a wiring form of the electric wire using the wiring structure according to the embodiment. FIG. 6 is a view for explaining the function and effect of the connector unit according to the embodiment, and FIG. 6A is a perspective view showing an example of a wiring form when the connector unit according to the prior invention is used. FIG. 6B is a perspective view showing an example of a wiring form when the connector unit according to the embodiment is used.

  In the present embodiment, as shown in FIG. 5, the electric wires 80 are used by using the seven connector units 30 </ b> A to 30 </ b> C so that the mating connectors 40 can be sequentially fitted to the counterpart connectors 40 fixed to the seven solenoids 50 shown in FIG. 1. An example of regulating the routing route will be described. The arrangement order and ratio of the connector units 30A to 30C shown in FIG. 1 are merely examples, and any connector unit selected from the connector units 30A to 30C can be arranged for each counterpart connector 40.

  As described with reference to FIG. 3A for the first binding type connector unit 30A, FIG. 4B for the second binding type connector unit 30B, and FIG. 9 for the insertion type connector unit 30C. When using 30A to 30C, the trunk line 82 from the adjacent connector units 30A to 30C is bound by the binding band 91A or the binding band 91B, or is inserted into the wire insertion port 16 and passes through the connector cover 10C. The trunk line 82 and the drawn branch line 81 merge to form the trunk line 82 routed on the next connector unit 30A to 30C side. As described above, in the connector units 30A to 30C, the routing directions of the branch lines 81 and the trunk lines 82 are guided by the connector covers 10A to 10C.

  By sequentially routing the electric wires 80 in this manner, for example, as shown in FIG. 5, the routing directions of the branch lines 81 and the trunk lines 82 can be appropriately guided to regulate the routing path.

  In particular, in the example of the routing form shown in FIG. 5, the first binding type connector unit 30A and the second binding type connector unit 30B are used as connector units. According to the first binding type connector unit 30A and the second binding type connector unit 30B, the trunk line 82 is bound by the binding band 91A or the binding band 91B as described above, and the binding type connector units 30A, 30B and the trunk line 82 are firmly connected. Fixed to. For this reason, it is possible to prevent the entire bundling connector units 30 </ b> A and 30 </ b> B from rotating with respect to the main line 82, and to improve attachment workability when attaching the connector 20 to the mating connector 40.

  Further description will be made with reference to FIG. 6. In the case of a wiring configuration using only the insertion type connector unit 30 </ b> C (in the case of the wiring configuration of FIG. 8 described above), in the insertion type connector unit 30 </ b> C, the main line is connected to the wire insertion port 16. Since only 82 is inserted, the connector unit 30C may rotate with respect to the electric wire 80 as shown in FIG. 6A, and the orientations of the plurality of connectors 20 may not be aligned. Thus, if the orientation of the connector 20 is difficult to align, the workability of attaching the connector 20 to the mating connector 40 is not good. On the other hand, in the routing form of the present embodiment, the entire bundling connector units 30A and 30B are prevented from rotating with respect to the main line 82 as described above, and is shown in FIG. 6 (b). As described above, the orientation of the plurality of connectors 20 can be easily aligned, so that the mounting workability is improved.

  As described above, the arrangement order and ratio of the connector units 30A to 30C shown in FIGS. 1 and 5 are examples, and for example, the first binding connector unit 30A is fitted to all the mating connectors 40. It is good also as a structure. However, when the routing route of the electric wire 80 is regulated using the plurality of connector units 30A to 30C, it is not always necessary to prevent the rotation with respect to the main line 82 in all the connector units 30A to 30C.

  Therefore, as in the arrangement structure shown in FIGS. 1 and 5, the configuration includes both the bundled connector units 30A and 30B and the insertion type connector unit 30C. , 30B, and the insertion type connector unit 30C can be arranged at other locations. With such a configuration, it is possible to reduce the number of bundling connector units 30A and 30B that require bundling work and are expensive in product cost.

  The binding type connector units 30A and 30B can be used by attaching arbitrary types of binding bands 91A and 91B to the connector covers 10A and 10B as long as they can be attached to the connector cover 10A. For example, a plurality of types of binding bands 91A and 91B having different lengths of the band portion 93 are prepared, and the types of binding bands 91A and 91B that are suitable for the number of trunk lines 82 to be bound (that is, the thickness of the trunk line 82) are prepared. It is assumed that it will be selected and used.

  In addition, since the bundling connector units 30A and 30B have a relatively large number and can bind the trunk wires 82 of a relatively thick portion, as shown in FIGS. 1 and 5, the insertion type connector unit 30C. It can arrange | position in the thick site | part in the trunk line 82 rather than. In FIGS. 1 and 5, since the number of trunk lines 82 increases and becomes thicker toward the left side in the drawing, the connector units 30A and 30B are arranged on the left side of the insertion type connector unit 30C. That is, as the wiring structure shown in FIGS. 1 and 5, the configuration includes both the binding type connector unit (the first binding type connector unit 30A or the second binding type connector unit 30B) and the insertion type connector unit 30C. The bundling connector units 30A and 30B can be arranged at locations where a relatively large number of trunk lines 82 are routed, and the insertion type connector unit 30C can be arranged at other locations.

  Alternatively, it is assumed that a plurality of types of binding bands 91A and 91B formed of synthetic resins having different heat resistance characteristics are prepared, and the types of binding bands 91A and 91B suitable for the use environment are selected and used. For example, when the bundled connector units 30A and 30B are used in the mission case 70, depending on the specifications of the mission case 70, heat resistance to a relatively high temperature range of about 150 ° C. to 160 ° C. is required. In some cases, heat resistance for only a relatively low temperature range of about 80 ° C. to 90 ° C. may be sufficient. In such a case, it is conceivable to use binding bands 91A and 91B having high heat resistance characteristics that can cope with any use environment, but using synthetic resin with good heat resistance increases the cost. On the other hand, if high heat resistance is not required, cost can be reduced if binding bands 91A and 91B that can be used only in a low temperature range are selected and used.

  Further, with respect to the first binding type connector unit 30A, the engagement of the locked portion (locking recess 19) of the connector cover 10A and the locking portion (locking protrusion 95) of the binding band 91A causes the connector cover 10A to The binding band 91A can be easily assembled.

  Further, for the second binding type connector unit 30B, the binding band 91B is attached to the connector cover 10B by the clamping portion 96 provided in the binding band 91B. Therefore, a special structure for the attachment is provided on the connector cover 10B side. There is no need. Therefore, the shape of the connector cover 10B can be made common regardless of whether the binding band 91B is attached or not, and cost reduction can be realized. Moreover, since the clamping part 96 has the nail | claw part 97 latched to the branch line drawing outlet 17, the binding band 91B can be firmly attached to the connector cover 10B using the branch line drawing outlet 17. FIG.

Below, the connector unit and wiring structure which concern on embodiment are summarized.
(1) Connector unit 30A, 30B which concerns on embodiment is the bottomed cylindrical shape which has the connector 20 which accommodates the terminal electrically connected to the front-end | tip of the branch line 81 branched from the trunk line 82, the bottom face 12, and the side surface. The connector covers 10A and 10B that guide the routing direction of the branch line 81 and the trunk line 82 are formed by being assembled to the drawing surface 25 side of the branch line 81 of the connector 20. The connector units 30A and 30B include a branch wire outlet 17 formed on the side surface through which the branch wire 81 is drawn, and a binding band 91A that is attached to the connector covers 10A and 10B and binds the trunk wire 82. 91B is provided.
(2) In the connector unit 30A according to the embodiment, the connector cover 10A has a locked portion (locking recess 19) formed on the side surface or the bottom surface 12, and the binding band 91A is locked Part (locking protrusion 95). The binding band 91A is attached to the connector cover 10A by the engagement of the locking portion and the locked portion.
(3) In the connector unit 30B according to the embodiment, the binding band 91B has a clamping part 96, and the clamping part 96 clamps the connector cover 10B, whereby the binding band 91B is attached to the connector cover 10B. It is attached.
(4) In the connector unit 30B according to the embodiment, the clamping portion 96 has a claw portion 97 that is engaged with the branch wire outlet 17 of the connector cover 10B.
(5) The routing structure according to the embodiment includes a bundled connector unit 30A, 30B, which is any one of the connector units (1) to (4), and an insertion type connector unit 30C, and the trunk line 82 and the branch line 81 are guided by a predetermined routing route. The insertion-type connector unit 30C is formed in a bottomed cylindrical shape having the connector 20 common to the bundling-type connector units 30A and 30B, a bottom surface 12 and side surfaces, and is assembled to the drawing surface 25 side of the connector 20. An insertion-type connector cover (10C), and an electric wire insertion port 16 is formed in the opposite side surface of the insertion-type connector cover, and the trunk line 82 is inserted into the electric wire insertion port 16 and the electric wire insertion. The branch line 81 is drawn from the mouth 16.

  The technical scope of the present invention is not limited to the embodiment described above. The above-described embodiments can be accompanied by various modifications and improvements within the technical scope of the present invention.

  For example, in the said embodiment, although the example which regulates the wiring path | route of the electric wire 80 routed in the mission case 70 using the connector units 30A-30C was demonstrated, connector units 30A-30C are transmission case. Needless to say, the wiring can be used not only for the wiring within 70 but also for other purposes.

  In the above embodiment, the locking recess 19 is formed in the connector cover 10A as the locking portion, and the locking protrusion 95 is formed in the binding band 91A as the locked portion. An arbitrary structure can be adopted as long as the engaging portion can be engaged. Moreover, although the said embodiment demonstrated and demonstrated the latching | locking part (locking recessed part 19) in the bottom face 12 of 10 A of connector covers, the structure formed in a side surface may be sufficient.

10A, 10B: Connector cover (bundled connector cover)
10C: Connector cover (insertion type connector cover)
12: Bottom 16: Wire insertion port 17: Branch wire outlet 19: Locking recess (locked portion)
20: Connector 21: Housing 25: Leading surface 30A: First binding type connector unit 30B: Second binding type connector unit 30C: Insertion type connector unit 80: Electric wire 81: Branch line 82: Trunk line 91A, 91B: Binding band 92: Body part 93: Band part 95: Locking protrusion (locking part)
96: Clamping part 97: Claw part

Claims (5)

A connector for accommodating a terminal electrically connected to the tip of a branch line branched from the trunk line;
A connector cover that is formed into a bottomed cylindrical shape having a side surface and a bottom surface and is assembled from the opening side to the branch wire drawing surface side of the connector, and a connector cover having a branch wire outlet formed on the side surface ;
A wiring direction of the branch line and the trunk line by the connector cover such that the branch line is drawn out from the branch line outlet and the trunk line extends along the bottom surface outside the bottom surface Is a connector unit that is guided,
A binding band attached to the connector cover for binding the trunk line;
A connector unit comprising: The connector cover has a locked portion formed on the side surface or the bottom surface,
The binding band has a locking portion,
The binding band is attached to the connector cover by engaging the locking portion and the locked portion.
The connector unit according to claim 1. The binding band has a clamping part,
The binding band is attached to the connector cover by the clamping unit clamping the connector cover.
The connector unit according to claim 1. A connector for accommodating a terminal electrically connected to the tip of a branch line branched from the trunk line;
A connector cover that is formed in a bottomed cylindrical shape having a side surface and a bottom surface and is assembled to a drawing surface side of the branch line of the connector, thereby guiding a wiring direction of the branch line and the trunk line;
A branch wire outlet formed on the side surface through which the branch wire is drawn;
A binding band attached to the connector cover and binding the trunk line;
With
The binding band has a clamping part,
When the clamping part clamps the connector cover, the binding band is attached to the connector cover,
The sandwiching portion has a claw portion that engages with the branch wire outlet of the connector cover,
Features and to Turkey connector unit that. A bundling type connector unit that is any one of the connector units according to claim 1 and a insertion type connector unit, and a routing structure that guides the trunk line and the branch line through a predetermined routing path. There,
The insertion-type connector unit includes the connector common to the bundling-type connector unit, and an insertion-type connector cover that is formed in a bottomed cylindrical shape having a bottom surface and a side surface and is assembled to the pull-out surface side of the connector. A wire insertion port is formed on the opposite side surface of the insertion type connector cover, the trunk line is inserted into the wire insertion port, and the branch line is drawn out from the wire insertion port.
A routing structure characterized by that.

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