JP2011134571A - Stacked connector - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a stacked connector having simpler construction for achieving double lock of terminals. <P>SOLUTION: The stacked connector includes terminals T to be fixed to cables C, and sub housings S1, S2 for holding the terminals T. It is joined to another connector in a state that the sub housings are stacked one on top of another. The upper two-layer sub housings S1 out of the sub housings each include: a plurality of terminal storage chambers 10 lined in the direction perpendicular to a housing stacking direction and opened at their upper sides; restricting portions 16c (first restricting portions) each protruded into the terminal storage chambers 10, for constraining the terminals T at their rear sides; and retainers 16a (second restricting portions), protruded to sides opposite to the restricting portions 16c and inserted into the terminal storage chambers 10 of the sub housing adjacent thereto, for constraining from their rear sides the terminals T stored in the terminal storage chambers 10. <P>COPYRIGHT: (C)2011,JPO&amp;INPIT

Description

  The present invention includes a plurality of terminals that are respectively fixed to ends of a plurality of electric wires, and a plurality of sub-housings for holding these terminals, and the sub-housings are coupled to a mating connector in a state where these sub-housings are stacked on each other. The present invention relates to a laminated connector.

  Conventionally, in order to efficiently perform assembly work of a vehicle wire harness, the wire harness is divided into a plurality of small wire harnesses, and each small wire harness is manufactured individually, and then the final wire harness is combined. The method of building is used.

  According to this manufacturing method, simple and frequent processes such as wire adjustment, terminal crimping, and terminal insertion are performed for each small harness for automation and efficiency, and finally the simple process is simply to combine the small harnesses. There is an advantage that a large-sized wire harness can be constructed. However, on the other hand, with the division of the wire harness, it is necessary to divide the connector provided at the end of the wire harness, which increases the number of times of connecting the connectors.

  Therefore, in recent years, various types of laminated connectors have been proposed in which the divided connector housings (called sub-housings) can be joined together in a laminated state and can be coupled to the mating connector at the same time in the laminated state ( For example, Patent Document 1).

  On the other hand, conventionally, a connector provided with a double locking mechanism is generally known in order to prevent a rear end of a connector terminal (hereinafter simply referred to as a terminal) accommodated in a connector housing. For example, Patent Document 2 includes a connector housing including a housing main body having a terminal accommodating chamber and a spacer attached thereto, and the terminal is provided along the axial direction of the terminal with the spacer temporarily attached to the housing main body. By first inserting the terminal into a flexible locking lance formed on the housing body to insert the terminal into the terminal accommodating chamber from the rear side (the side opposite to the mating connector), A device is disclosed in which a terminal in a temporarily mounted state is pushed into a connector housing to be brought into a fully mounted state so that the terminal is engaged with a locking portion formed in the spacer and the terminal is secondarily locked.

JP 2009-43642 A Japanese Patent Laid-Open No. 9-245874

  As for the laminated connectors, those used for applications requiring higher connection reliability are provided with a double locking mechanism as disclosed in Patent Document 2 for each sub-housing so that the rear end of the terminal is removed. It is desirable to prevent this.

  However, if each sub-housing is configured so that the sub-housings can be combined with each other, and a structure for attaching a secondary locking spacer to each sub-housing, the structure of the sub-housing becomes complicated. This is one of the factors leading to high costs. In recent years, the multilayer connector has been miniaturized and multipolarized. In this type of small multilayer connector, a flexible locking lance for primary locking is formed in each sub-housing, and the engaged portion of the lance is not provided. It is technically difficult to form the terminal itself, and it is difficult to apply the conventional double locking mechanism.

  The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a laminated connector that can double-lock connector terminals with a simpler housing structure.

  The present invention for solving the above-described problems includes a plurality of connector terminals fixed to the ends of a plurality of electric wires, and a plurality of sub-housings for holding these connector terminals, and these sub-housings are mutually connected. A laminated connector coupled with a mating connector including mating terminals in a stacked state, wherein the sub-housings are arranged in a direction perpendicular to the laminating direction of the sub-housings, and the connector terminals are perpendicular to the connection direction. A plurality of terminal accommodating chambers that are open on one side in the stacking direction so that they can be inserted from the direction, and connector terminals that protrude into the terminal accommodating chambers and are accommodated in the terminal accommodating chambers from the side opposite to the counterpart connector A first restricting portion that projects to the opposite side of the first restricting portion, and the adjacent sub-chambers in a state where the sub-housings are stacked. They are respectively inserted into the terminal accommodating chambers of managing in which and a second regulating portion for restraining the connector terminal to be accommodated in the terminal accommodating chamber from the side opposite to the mating connector.

  In this laminated connector, the connector terminals accommodated in each terminal accommodating chamber of the sub-housing are restrained by a first restricting portion provided in the terminal accommodating chamber (referred to as primary locking), and are further adjacent in the housing laminated state. When the second restricting portion of the sub-housing is inserted into each terminal accommodating chamber, it is restrained by the second restricting portion (referred to as secondary locking). According to this configuration, it is possible to doubly lock the terminals with respect to these sub-housings only by overlapping the sub-housings without providing conventional spacers on the sub-housings. Moreover, in this laminated connector, the terminal accommodating chamber is opened on one side in the laminating direction of the housing and is accommodated in the terminal accommodating chamber so that the connector terminal can be inserted from the direction orthogonal to the connection direction. Since the first restricting portion for primary locking protrudes into the terminal accommodating chamber so as to constrain the connector terminal from the side opposite to the mating connector, it has a special shape like a conventional flexible locking lance. Therefore, the primary locking of the connector terminals can be satisfactorily achieved simply by providing the first convex-shaped first restricting portion in the terminal accommodating chamber.

  In this laminated connector, the first restricting portion and the second restricting portion are formed by the first restricting portion of one sub housing and the second restricting portion of the other sub housing in a state where two adjacent sub housings are laminated. 2 restricting portions are formed at positions facing each other in the stacking direction of these sub-housings, and the connector terminal is constrained to be commonly restrained by both the first restricting portion and the second restricting portion. It is preferred to have

  In this way, according to the configuration in which the constrained portion on the connector terminal side is made common, the structure of the connector terminal can be simplified as compared with the case where the constrained portion is provided individually for the first and second restricting portions.

  More specifically, the connector terminal has a box-shaped terminal connection portion that contacts the counterpart terminal and is accommodated in the terminal accommodating chamber in a posture in which the rear side of the terminal connection portion in the terminal connection direction is opened, The first restricting portion and the second restricting portion are formed so as to protrude to a position on the rear side of the terminal connecting portion of the connector terminal so as to restrict the terminal connecting portion as the restricted portion. Is.

  According to this configuration, since the terminal connection portion of the connector terminal is used as the restrained portion as it is, there is no need to separately form a dedicated restrained portion on the connector terminal, and a rational locking structure is obtained.

  In this case, the connector terminal has a shape having a belt-like body extending in the terminal connection direction, the terminal connection portion at the front end of the belt-like body in the terminal connection direction, and a barrel portion for holding the electric wire on the rear side. Each of the terminal housing chambers of the sub-housing has a shape for holding the connector terminal in a posture in which the belt-like body faces a direction parallel to the stacking direction of the sub-housing, and the first restricting portion and the second restricting portion It is preferable that the restricting portion is formed so as to protrude to a position between the terminal connecting portion and the barrel portion of the connector terminal accommodated in the terminal accommodating chamber in the terminal accommodating chamber.

  Thus, according to the structure which restrains the said connector terminal by the 1st, 2nd control part in the position between a terminal connection part and a barrel part among connector terminals, it is few, without enlarging a terminal storage chamber unnecessarily. The connector terminal can be double-locked in space.

  Each of the stacked connectors described above further includes a holder housing that holds the sub-housing in a state in which the sub-housings are stacked on each other, and the holder housing is the uppermost sub-housing among the stacked sub-housings. And a pair of holding portions that hang down from both sides of the top plate portion in the arrangement direction of the terminal accommodating chambers and hold the sub-housing from the outside thereof, It has a shape that holds the sub-housing in a posture in which the second restricting portion protrudes on the side opposite to the top plate portion, and protrudes downward from each of the top plate portions to each terminal receiving chamber of the uppermost sub-housing. A third restricting portion for restraining the connector terminal inserted and accommodated in the terminal accommodating chamber from the side opposite to the counterpart connector; It is preferred that those are example.

  In this configuration, the third restricting portion of the holder housing is inserted into each terminal accommodating chamber of the uppermost sub-housing, and each connector terminal accommodated in the uppermost sub-housing is restrained by the third restricting portion. The connector terminal is secondarily locked. As a result, the connector terminals can be double-locked in the uppermost sub-housing as in the other sub-housings.

  According to the multilayer connector of the present invention as described above, the connector terminal can be double-locked to the sub housing without providing a separate spacer or the like for each sub housing. Moreover, there is no need for a specially shaped locking portion such as a conventional flexible locking lance as a locking portion for primary locking, and a connector is provided by simply providing a first convex-shaped first restricting portion in the terminal accommodating chamber. The primary locking of the terminal can be achieved satisfactorily. Therefore, double locking of the connector terminals in the laminated connector can be achieved with a simple housing structure.

It is a perspective view which shows the laminated connector which concerns on this invention. It is a disassembled perspective view of a laminated connector (a figure disassembled into a sub housing and a holder housing in a laminated state). It is a perspective view which shows each subhousing contained in a laminated connector. It is a top view which shows a 1st subhousing. It is a longitudinal cross-sectional view which shows a 1st subhousing (It is the VV sectional view taken on the line of FIG. 4, (a)-(c) is code | symbol (a)-(c) among the VV lines of FIG. ) Shows a cross section of the line portion indicated by). It is a front view (VI arrow line view of FIG. 4) which shows a 1st subhousing. It is a longitudinal cross-sectional view which shows a 1st subhousing (the VII-VII sectional view taken on the line of Fig.5 (a), (a) shows a terminal uninserted state, (b) shows a terminal insertion state, respectively). It is a top view which shows the state by which the terminal was inserted in the 1st subhousing (terminal storage chamber) (it is a VIII arrow line view of FIG.7 (b)). It is a front view which shows a 2nd subhousing. It is a longitudinal cross-sectional view which shows a 2nd subhousing (XX sectional view taken on the line of FIG. 9). It is a figure which shows the terminal of the state crimped | bonded to the electric wire ((a) is a top view, (b) shows a terminal with a side view, respectively). It is a rear view (XII arrow view of FIG. 13) which shows a holder housing. FIG. 3 is an exploded cross-sectional view of the laminated connector (decomposed into a laminated sub-housing and a holder housing: a longitudinal sectional view of FIG. 2). It is a longitudinal cross-sectional view of a laminated connector (vertical cross-sectional view of FIG. 1). It is a rear view (XV arrow line view of FIG. 14) which shows a laminated connector.

  Hereinafter, a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

  FIG. 1 is a perspective view of a laminated connector according to the present invention. The laminated connector shown in this figure has a male housing structure in which a female terminal is accommodated, and is coupled to an unillustrated counterpart connector having a female housing structure in which a male terminal is accommodated. is there.

  As shown in exploded perspective views in FIGS. 2 and 3, the laminated connector holds a plurality of connector terminals T (hereinafter referred to as terminals T) fixed to the ends of the plurality of electric wires C, and these terminals T. A plurality of sub-housings, specifically, two sub-housings S1 having the same structure that can be stacked in an unspecified order (referred to as first sub-housing S1) and a dedicated sub-housing for stacking as a lowermost layer S2 (referred to as a first sub-housing S2) and a holder housing H for holding the sub-housings S1 and S2, and the sub-housings S1 and S2 are laminated together by the holder housing H. It is configured to be held and coupled with the mating connector in this state.

  Each of the sub-housings S1 and S2 is flat in the housing stacking direction and has a substantially rectangular shape in plan view, and holds the plurality of terminals T in a state of being arranged in a direction orthogonal to the axial direction. And it is comprised so that it can mutually laminate in the direction orthogonal to the arrangement direction.

  4 to 7 show a specific configuration of the first sub-housing S1. As shown in the figure, the first sub-housing S1 extends in the connecting direction with the mating connector (vertical direction in FIG. 4, horizontal direction in FIG. 7; hereinafter, this direction is referred to as the front-rear direction), and the housing stacking direction A plurality of (10 in the illustrated example) terminal accommodating chambers 10 arranged in a direction orthogonal to the horizontal direction (FIG. 4 left-right direction, FIG. 7 orthogonal to the paper surface; hereinafter, this direction is referred to as the width direction). Yes.

  As shown in FIGS. 4 and 7 (a), each terminal accommodating chamber 10 is formed in a groove shape with both front and rear ends open and opened upward substantially over the entire front and rear direction, and only the front end is upper. Covered by the wall 14. Thereby, each terminal accommodating chamber 10 has each terminal T from the direction orthogonal to the axial direction (terminal connection direction), that is, from the upper side of the first sub-housing S1, as indicated by phantom lines in FIG. It is configured to be inserted into the terminal accommodating chamber 10.

  Here, as shown in FIGS. 11A and 11B, the terminal T is a female type (box type in the illustrated example) at the front end of the strip 1 extending in the terminal connection direction (left and right direction in FIG. 11). A terminal connecting portion 2 is provided, and a plurality of barrels for holding an electric wire on the rear side, specifically, a conductor holding barrel 4 for holding an exposed portion of the conductor of the end of the electric wire C and a covering portion are held. And a covering portion holding barrel 5. And the terminal T is mounted | worn with the terminal of the electric wire C by hold | maintaining the terminal part of the electric wire C with each barrel 4 and 5. FIG.

  As shown in FIG. 7, the terminal T has a lateral orientation in which the strip 1 faces in a direction parallel to the partition wall (partition wall) of the terminal accommodation chamber 10 (an orientation in a direction parallel to the housing lamination direction). 10 and is restrained from the upper and rear sides of the housing. That is, each partition wall that partitions adjacent terminal accommodating chambers 10 is composed of four unit partition walls 22a to 22d that are arranged in the front-rear direction and separated from each other, and among these unit partition walls 22a to 22d, the inner two unit partitions As shown in FIGS. 5 and 7A, the walls 22 b and 22 c are each configured with a locking piece having a locking claw 23 at its tip (upper end) and capable of bending and displacing in the direction in which the terminal accommodating chambers 10 are arranged. Has been. Thereby, in the state where the terminal T is inserted into the terminal accommodating chamber 10, as shown in FIGS. 7B and 8, the terminal T is restrained from above by the respective locking claws 23 of the unit partition walls 22b and 22c. The terminal T is locked to the second sub-housing S2. In FIG. 8, the terminals T are shaded in order to clarify the relationship between the terminals T and the unit partition walls 22 b and 22 c.

  Each terminal accommodating chamber 10 is provided with a restricting portion 16c (corresponding to the first restricting portion of the present invention) including a convex portion protruding upward from the inner bottom surface (lower partition 16). In a state where T is inserted into the terminal accommodating chamber 10, the restricting portion 16c is inserted between the terminal connecting portion 2 of the terminal T and the conductor holding barrel 4, and the terminal connecting portion 2 is restrained from the rear side. As a result, the terminal T is locked to the first sub-housing S1.

  On the upper surface of the upper partition 14 at the front end of each terminal accommodating chamber 10, a convex portion 14 b projects upward. In addition, a notch portion 16b corresponding to the convex portion 14b is formed at a position on the lower surface of the first sub-housing S1 and at the front end of each terminal accommodating chamber 10 (long hole portion 10a). The convex portions 14b and the cutout portions 16b are for positioning the terminal housing chambers of the upper and lower sub-housings in the width direction in the housing laminated state.

  A retainer 16a (corresponding to a second restricting portion of the present invention) composed of a convex portion projecting downward is provided at a position on the lower surface of the first sub-housing S1 and substantially in the middle of each terminal accommodating chamber 10 in the front-rear direction. Is provided. These retainers 16a are inserted into the terminal housing chambers of the sub-housing adjacent to the lower side in the housing laminated state, and restrain the terminals T accommodated in the terminal housing chambers from the rear side. Each retainer 16a is formed at a position directly below the restricting portion 16c of each terminal accommodating chamber 10, and, for this reason, in a state where two first sub-housings S1 are stacked, Each retainer 16a is inserted into the terminal accommodating chamber 10 of the lower first sub-housing S1 so as to be close to and opposed to the restriction portion 16c.

  In addition, the first sub-housing S1 includes a stacked portion for stacking the sub-housings at positions on both outer sides in the width direction with respect to the region where the terminal accommodating chambers 10 are arranged in parallel. Specifically, a substantially flat laminated surface is formed on the upper surface of the first sub-housing S1 outside the region where the terminal accommodating chambers 10 are juxtaposed, and the front and rear directions for positioning are formed on these laminated surfaces. 3c and 4c, and the side surfaces of the first sub-housing S1 are recessed inward in the width direction so as to correspond to the two ridges 14c. An L-shaped step 18 is formed. The stepped portion 18 also serves as a portion to be locked of a later-described locking plate 37 of the holder housing H.

  In addition, two large and small bosses 15a and 15b projecting forward from the front end surface are located at positions on both outer sides in the width direction of the front end surface of the first sub-housing S1 and the region where the terminal accommodating chambers 10 are arranged in parallel. Is formed. These bosses 15a and 15b are for positioning the first sub-housing S1 with respect to the holder housing H.

  9 and 10 show a specific configuration of the second sub-housing S2. As described above, the second sub-housing S2 is a dedicated sub-housing for stacking on the lowermost layer. The second sub-housing S2 has the same basic configuration as the first sub-housing S1 described above, but differs from the first sub-housing S1 only in the following points.

  That is, the notch 16 b is not formed on the lower surface of the second sub-housing S 2, and the entire lower surface is continuously covered with the lower partition wall 16. Further, the retainer 16a is not provided, and instead, a knob 16d that hangs downward is provided at the rear end of the lower surface of the second sub-housing S2. The knob 16d is for an operator to put his / her finger on when the connector is joined.

  The configuration of the second sub housing S2 other than the above items is the same as that of the first sub housing S1. Accordingly, the second sub-housing S2 can be stacked adjacent to the lower portion of the first sub-housing S1, and in this stacked state, each retainer 16a of the upper-side first sub-housing S1 is connected to the second sub-housing S2. It is inserted into the terminal accommodating chamber 10 of the sub-housing S2 and is close to and opposed to the restriction portion 16c. However, with respect to the second sub-housing S2, the first sub-housing S1 cannot be laminated adjacently below the second sub-housing S2 as a result of the knob 16d being formed.

  On the other hand, as shown in FIG. 2, FIG. 12 and FIG. 13, the holder housing H has the front end surfaces of the laminated sub-housings S1 and S2 collectively in front (side facing the mating connector; right side in FIG. 13). ) And a holding portion for holding the stacked sub-housings S1 and S2 at a position on the rear side of the front mask portion 30, and these are integrated by a resin material. It is molded into.

  The front mask portion 30 is formed with a plurality of through holes 31 that allow insertion of male terminals of the mating connector into the terminal accommodating chambers 10 of the sub-housings S1 and S2 held in a stacked state. Specifically, a set of ten through holes 31 arranged in a horizontal row at intervals corresponding to the terminal accommodating chambers 10 are formed in three upper and lower stages corresponding to the sub-housings S1 and S2. A chamfered portion 31a is formed at the periphery of each through-hole 31 in the front surface of the front mask portion 30, so that the male terminal is penetrated when the laminated connector and the mating connector are coupled. It is designed to be guided into the hole 31.

  In addition, in the front mask portion 30, at positions on both outer sides of the set of ten through holes 31 corresponding to the sub-housings S <b> 1 and S <b> 2, separately from the through holes 31, two kinds of large and small through holes 32 a, 32b is respectively drilled. These through holes 32a and 32b correspond to the bosses 15a and 15b formed on the front end surfaces of the sub-housings S1 and S2. The bosses 15a and 15b of the sub-housings S1 and S2 are respectively connected to the through-holes 32a and 32b. The sub-housings S1 and S2 are positioned with respect to the front mask portion 30 by fitting (inserting) into 32b.

  The holding portion includes a top plate portion 34 that covers the uppermost sub-housing of the stacked sub-housings S1 and S2 from above (a direction parallel to the stacking direction), and both ends in the width direction of the top plate portion 34 (FIG. 12). Then, it includes a pair of holding portions 35 that hang down from both ends in the left and right direction and hold the sub-housings S1 and S2 from the outside in the width direction. Each of the top plate portion 34 and each holding portion 35 has a front end connected to the front mask portion 30.

  Each holding portion 35 includes a restriction plate 36 connected to the front mask portion 30 and extending in the front-rear direction, and a locking plate 37 extending in the front-rear direction alongside the restriction plate 36.

  The restricting plate 36 restricts the positions of the sub-housings S1 and S2 in the width direction with respect to the front mask portion 30 by contacting the sub-housings S1 and S2 from the outside in the width direction. 37 is for locking the sub-housings S1 and S2.

  Each locking plate 37 is separated from the restriction plate 36 and is connected only to the top plate portion 34. Therefore, the lower end portion of the locking plate 37 is a free end portion that can be bent and displaced in the width direction. Each locking plate 37 is provided with a locking portion that protrudes inward. Specifically, three locking portions 37a to 37c for locking the stacked sub-housings S1 and S2 respectively. Is provided on each locking plate 37, and a locking portion 37 c for locking the second housing S <b> 2 is provided on the lower end portion of the locking plate 37.

  As shown in FIG. 12, the top plate portion 34 includes a retainer 34a that protrudes downward and a concave portion 34b that is recessed upward at a position facing the terminal receiving chambers of the uppermost sub-housing on the lower surface thereof. It has. These retainers 34a correspond to the retainers 16a provided on the lower surfaces of the sub-housings S1 and S2, and are inserted into the terminal housing chambers of the uppermost sub-housing among the sub-housings S1 and S2 held by the holder housing H. The terminal T accommodated in the terminal accommodating chamber is restrained from the rear side. Accordingly, the retainers 34a are provided at positions corresponding to the retainers 16a and the restricting portions 16c of the sub-housings S1 and S2 held by the holder housing H on the lower surface of the top plate portion 34, respectively. On the other hand, the concave portion 34b corresponds to a cutout portion 16b formed on the lower surface of the first sub-housing S1 and the like, and fits the convex portion 14b of the uppermost first sub-housing S1.

  The top plate portion 34 further includes guide portions 39a and 39b for guiding the laminated connector with respect to the housing of the mating connector when the laminated connector and the mating connector are coupled, and the mating connector. And a lock arm 38 (corresponding to the lock portion according to the present invention) having a locking portion 38a for engaging with the housing and locking the engaged state.

Next, assembly of the above-described laminated connector will be described.
<Insert terminal>
First, the terminals T fixed to the ends of the plurality of electric wires C are inserted into the terminal accommodating chambers 10 of the sub-housings S1 and S2, respectively.

In this case, as shown in FIGS. 7 and 10, the terminal T is inserted into the terminal accommodating chamber 10 from the upper side of the sub-housing in a lateral orientation. When the terminal accommodating chamber 10 is inserted into the terminal T in this way, the terminal T is restrained from the upper side by the locking claws 23 of the partition walls 22a and 22b and the restricting portion 16c formed on the inner bottom surface of each terminal accommodating chamber 10. Is restrained from the rear side. Accordingly, the terminal T is locked in the pulling direction (rear) by the restricting portion 16c while being accommodated in the terminal accommodating chamber 10 (hereinafter, the locking of the terminal T by the restricting portion 16c is referred to as primary locking). .
<Housing lamination>
Next, the sub-housings S1 and S2 in which the terminals T are accommodated are stacked on each other.

  Specifically, as shown in FIGS. 2 and 3, the first sub-housing S1 is arranged on the second sub-housing S2 so that the front end surfaces are flush with each other, and the protrusions of the second sub-housing S2 are arranged. The first sub-housing S1 is overlaid on the second sub-housing S2 so that the stepped portion 18 is fitted between the four sub-housings 14c. At this time, each convex portion 14b of the second sub-housing S2 is inserted into each notch portion 16b of the first sub-housing S1. Then, the first sub-housing S1 is overlaid in the same manner on the first sub-housing S1 overlaid on the second sub-housing S2.

  In the state where the sub-housings S1 and S2 are stacked in this way, as shown in FIG. 13, each retainer 16a of the first sub-housing S1 adjacent to the second sub-housing S2 in the lowermost layer is connected to each terminal of the second sub-housing S2. The retainers 16a are inserted into the accommodating chambers 10 respectively, and the retainers 16a are interposed between the terminal connection portions 2 of the terminals T accommodated in the terminal accommodating chambers 10 and the conductor holding barrels 4 so as to face the restricting portions 16c. To do. Thereby, each terminal T (terminal connection part 2) accommodated in 2nd subhousing S2 is restrained from the rear side by the retainer 16a of 1st subhousing S1. That is, each terminal T accommodated in the second sub-housing S2 is primarily locked by the restricting portion 16c in the terminal accommodating chamber 10, and locked in the pulling direction by the retainer 16a of the adjacent first sub-housing S1. (Hereinafter, the locking of the terminal T by the retainers 16a and 34a is referred to as secondary locking), whereby the terminal T is double-locked to the housing of the laminated connector.

Similarly, the retainers 16a of the upper first sub-housing S1 are inserted into the terminal accommodating chambers 10 of the lower first sub-housing S1 in the two first sub-housings S1. Each terminal T accommodated in one sub-housing S1 is restrained from the rear side by the retainer 16a of the upper-layer first sub-housing S1. As a result, the terminals T accommodated in the first sub-housing S1 in the lower layer are primarily locked by the restricting portion 16c in the terminal accommodating chamber 10, and are secondarily engaged by the retainer 16a of the first sub-housing S1 in the upper layer. The terminal T is doubly locked with respect to the housing of the laminated connector.
<Combination with holder housing>
Next, the sub housings S1 and S2 in the stacked state are combined with the holder housing H. As shown in FIG. 13, the uniting is performed by inserting the stacked sub housings S <b> 1 and S <b> 2 between the holding portions 35 from the lower side of the holder housing H.

  Specifically, the uppermost first sub-housing S1 contacts the lower surface of the top plate portion 34 while the front end surfaces of the stacked sub-housings S1 and S2 are along the front mask portion 30 and the same side surfaces are along the regulating plate 36. The sub-housings S1 and S2 are integrally inserted to the position. In this state where the sub-housings S1 and S2 are inserted between the holding portions 35, as shown in FIG. 15, the locking portions 37a to 37c of the locking plates 37 respectively correspond to the corresponding sub-housings S1 and S2. The sub-housings S1 and S2 are respectively held by the holder housing H in a state in which they are stacked.

  In this state, the sub-housings S1 and S2 are pressed toward the front mask portion 30 and the bosses 15a and 15b of the sub-housings S1 and S2 are fitted into the corresponding through holes 32a and 32b of the front mask portion 30 ( The front end surfaces of the sub-housings S1 and S2 are positioned with respect to the front mask portion 30. Thereby, the assembly of the laminated connector is completed.

  In such an assembled state of the laminated connector, as shown in FIG. 14, each retainer 34a formed on the lower surface of the top plate portion 34 of the holder housing H is placed in each terminal accommodating chamber 10 of the uppermost first sub-housing S1. Each is inserted and interposed between the terminal connection portion 2 of the terminal T accommodated in each terminal accommodating chamber 10 and the conductor holding barrel 4. As a result, the terminals T accommodated in the uppermost first sub-housing S1 are restrained from the rear side by the retainer 34a. That is, the terminal T accommodated in the uppermost first sub-housing S1 is primarily latched by the restricting portion 16c in the terminal accommodating chamber 10 and secondarily latched by the retainer 34a of the holder housing H, thereby stacking It will be doubly locked to the housing of the connector.

  Here, in the assembled state of the laminated connector, the lower surface of the lowermost second sub-housing S2 faces downward from between the holding portions 35. As described above, the second sub-housing S2 has the entire lower surface. Is continuously covered by the lower partition 16. Therefore, the terminal T accommodated in the terminal accommodating chamber 10 and the conductor portion of the electric wire C fixed to the terminal T are not exposed to the outside, thereby causing a trouble such as a short circuit of the terminal T in the second sub-housing S2. Is prevented in advance.

  In the above description, the sub-housings S1 and S2 are first stacked, and then the stacked sub-housings S1 and S2 are united into the holder housing H. However, as described above, the holder housing H ( Since the holding portion 35) is provided with locking portions 37a to 37c for individually locking the sub-housings S1 and S2, the sub-housings S1 and S2 are individually connected in order from the uppermost first sub-housing S1. You may make it laminate | stack sequentially, uniting with the holder housing H. FIG.

  According to the multilayer connector according to the present invention as described above, the terminals T accommodated in the sub-housings S1 and S2 can be pulled out with a relatively simple configuration without attaching dedicated parts such as spacers to the sub-housings. Can be double-locked in the direction. Therefore, it is possible to provide a laminated connector having a double locking function of the terminal T while suppressing the manufacturing cost.

  In particular, in this laminated connector, the sub-housings S1 and S2 are shaped so that the terminal housing chamber 10 is opened upward so that the terminals T can be inserted from the direction orthogonal to the axial direction. A restricting portion 16c is provided on the inner bottom surface of each terminal accommodating chamber 10, the terminal T is accommodated in the terminal accommodating chamber 10 in a lateral orientation, and the terminal connecting portion 2 is restrained from the rear side by the restricting portion 16c. The primary locking is achieved. That is, in this laminated connector, since the existing terminal connection portion 2 formed on the terminal T is a restrained portion for primary locking, it is necessary to separately form a restrained portion for primary locking on the terminal T. Further, there is no need to provide a special locking portion such as a flexible locking lance for primary locking in the sub-housings S1 and S2. Therefore, the primary locking of the terminal T can be achieved while simplifying the structures of the sub-housings S1 and S2 and the terminal T, and the manufacturing cost can be suppressed in this respect as well.

  Further, in this multilayer connector, the retainer 16a is provided at a position facing the restriction portion 16c of the sub-housings S1 and S2 in the lower layer in the housing laminated state, so that the terminal connection portion of the terminal T is the same as the restriction portion 16c. The secondary locking of the terminal T is achieved by restraining 2 from the rear side. In other words, the terminal connection portion 2 of the terminal T is configured to be used as a constrained portion for primary locking and secondary locking. For this reason, it is not necessary to separately form the constrained portion for secondary locking on the terminal T. Therefore, according to the laminated connector, the manufacturing cost can be suppressed in this respect as well.

  In this laminated connector, the laminated sub housings S1 and S2 are held by the holder housing H. As described above, the retainer 34a is provided on the top plate portion 34 of the holder housing H, and the retainer of the first sub housing S1 is provided. Similarly to 16a, since the terminal T accommodated in the uppermost first sub-housing S1 is restrained from the rear side by the retainer 34a, secondary locking of the terminal T is achieved. The sub-housing S1 has an advantage that the terminal T can be double-locked similarly to the other sub-housings S1 and S2.

  By the way, the above-mentioned laminated connector is an example of a preferred embodiment of the laminated connector according to the present invention, and the specific configuration thereof can be appropriately changed without departing from the gist of the present invention. For example, the following configuration can be applied.

  In the embodiment, the laminated connector having the three-layer structure has been described. Needless to say, it may have a two-layer structure or a structure having four or more layers.

  In addition, the laminated connector of the embodiment has a configuration in which the first and second types of sub-housings S1 and S2 are stacked. Of course, the stacked connector has a configuration in which a plurality of first sub-housings S1 are stacked. May be.

  Moreover, although the laminated connector of the embodiment is configured to integrally hold the sub housings S1 and S2 in a stacked state by the holder housing H, the holder housing H may be omitted. For example, on both outer sides of the terminal housing chamber 10 in the sub-housings S1 and S2, a locking portion and a locked portion having a shape capable of locking the sub-housings S1 and S2 are provided, thereby providing the holder housing H. It is good also as a structure which can integrate sub-housing S1, S2 only by them.

  In the laminated connector of the embodiment, the sub-housings S1 and S2 are locked to the holder housing H by the locking portions 37a to 37c formed on the holding portion 35 (locking plate 37) of the holder housing H, respectively. Thus, the stacked state of each of the sub-housings S1 and S2 is maintained. However, as described above, the locking portion and the locked portion that can lock the sub-housings S1 and S2 are provided. By providing in each sub-housing S1, S2, you may comprise so that the lamination | stacking state of each sub-housing S1, S2 can be hold | maintained only by them. In this case, the locking portions 37a and 37b corresponding to the upper two layers among the locking portions 37a to 37c provided in the holding portion 35 (locking plate 37) of the holder housing H can be omitted. It becomes.

DESCRIPTION OF SYMBOLS 1 Strip | belt-shaped body 2 Terminal connection part 2a Locking part 4 Barrel for conductor part holding 5 Barrel for covering part holding 10 Terminal housing chamber 14 Upper partition 14b Protrusion 14c Projection 16 Lower partition 16a, 34a Retainer 16b Notch 16c Control part 18 Stepped portions 22a, 22b, 22c, 22d Unit partition wall 30 Front mask portion 31 Through hole 34 Top plate portion 35 Holding portion 36 Restriction plate 37 Locking plate 37a, 37b, 37c Locking portion C Electric wire H Holder housing S1 1 sub-housing S2 2nd sub-housing T terminal

Claims (5)

A mating connector including a plurality of connector terminals fixed to the ends of a plurality of electric wires and a plurality of sub-housings for holding these connector terminals, and including the mating terminals in a state where these sub-housings are stacked on each other A laminated connector coupled with
The sub-housing is arranged in a direction orthogonal to the stacking direction of the sub-housings, and a plurality of terminal accommodating chambers open on one side in the stacking direction so that the connector terminals can be inserted from the direction orthogonal to the connection direction. A first restricting portion that protrudes into the terminal accommodating chamber and restrains the connector terminal accommodated in the terminal accommodating chamber from the side opposite to the counterpart connector, and protrudes on the opposite side of the first restricting portion, And a second restricting portion that restrains the connector terminal that is inserted into the terminal accommodating chamber of the adjacent sub-housing in a stacked state and accommodated in the terminal accommodating chamber from the side opposite to the counterpart connector. A featured laminated connector. The laminated connector according to claim 1, wherein
The first restricting portion and the second restricting portion are formed by the first restricting portion of one sub-housing and the second restricting portion of the other sub-housing in a state where two adjacent sub-housings are stacked. Are formed at positions facing each other in the stacking direction of
The connector has a constrained portion that is constrained in common by both the first restricting portion and the second restricting portion. In the laminated connector according to claim 2,
The connector terminal has a box-shaped terminal connection portion that contacts the counterpart terminal and is accommodated in the terminal accommodating chamber in a posture in which a rear side of the terminal connection portion in the terminal connection direction is opened,
The first restricting portion and the second restricting portion are formed so as to protrude to a position on the rear side of the terminal connecting portion of the connector terminal so as to restrict the terminal connecting portion as the restricted portion. A laminated connector characterized by that. In the laminated connector according to claim 3,
The connector terminal has a shape having a strip extending in the terminal connection direction, the terminal connection portion at the front end of the strip in the terminal connection direction, and a barrel portion for holding the electric wire on the rear side,
Each of the terminal housing chambers of the sub-housing has a shape for holding the connector terminal in a posture in which the belt-like body faces a direction parallel to the stacking direction of the sub-housings.
The first restricting portion and the second restricting portion are formed so as to protrude to a position between the terminal connecting portion and the barrel portion of the connector terminal accommodated in the terminal accommodating chamber of the terminal accommodating chamber. A laminated connector characterized by being made. In the multilayer connector according to any one of claims 1 to 4,
A holder housing for holding the sub-housing in a state in which the sub-housings are stacked on each other;
The holder housing is suspended from both sides of the top plate portion in the direction in which the terminal housing chambers are arranged, and a top plate portion that covers the uppermost sub-housing of the laminated sub housings from a direction parallel to the lamination direction. A pair of holding portions for holding the sub-housing from the outside, and having a shape for holding the sub-housing in a posture in which the second restricting portion protrudes on the side opposite to the top plate portion and the top plate portion And a third restricting portion for restraining a connector terminal that protrudes downward and is inserted into each terminal accommodating chamber of the uppermost sub-housing and accommodated in the terminal accommodating chamber from the side opposite to the counterpart connector. Multilayer connector characterized by.

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