Connector and wire harness

Information

  • Patent Grant
  • 9306332
  • Patent Number
    9,306,332
  • Date Filed
    Wednesday, April 23, 2014
    10 years ago
  • Date Issued
    Tuesday, April 5, 2016
    8 years ago
Abstract
A connector includes a first terminal housing that houses a first connecting terminal, and a second terminal housing that houses at least a portion of a cable including a second connecting terminal at an end portion thereof. The first and second connecting terminals contact with each other and form a contact point when the first and second terminal housings are fitted each other. The two terminal housings are fitted in a direction intersecting with an extending direction of the cable. The first and second terminal housings include a first fitting portion and a second fitting portion, respectively. The connector further includes a fitted-state maintaining member that is configured so as to be fitted to both the first and second fitting portions by being slid along a direction perpendicular to the fitting direction of the two terminal housings after the two terminal housings are fitted to each other.
Description

The present application is based on Japanese patent application No. 2013-091499 filed on Apr. 24, 2013, the entire contents of which are incorporated herein by reference.


BACKGROUND OF THE INVENTION

1. Field of the Invention


The invention relates to a connector potentially employed for a power harness used in eco-friendly cars such as hybrid cars and electric cars especially to transmit a large amount of power, as well as a wire harness using the connector.


2. Description of the Related Art


A power harness is used for connecting between devices such as between a motor and an inverter or between an inverter and a battery in, e.g., a hybrid car or an electric car, which has made significant progress in recent years, to transmit a large amount of power, and a connector in a two-divided structure composed of, e.g., a first connector portion provided with a first connecting terminal(s) as well as a first terminal housing for housing the first connecting terminal(s) and a second connector portion provided with a second connecting terminal(s) connected to the first connecting terminal(s) as well as a second terminal housing for housing the second connecting terminal(s) is provided to one end of the power harness.


For example, the first connector portion provided on a device is connected to the second connector portion connected to a cable, thereby electrically connecting the device to the cable.


A so-called L-shaped connector is known as this type of connector, in which cables extends in a direction orthogonal to a fitting direction of two terminal housings.


JP-A-2010-211935 discloses a connector in which two terminal housings are fixed by a bolt.


The related art of the invention may include JP-B-4905608 as well as JP-A-2010-211935.


SUMMARY OF THE INVENTION

Since the connector is provided on the assumption that it is removable (i.e., connectors are less required at portions where it need not be removed), the use of bolts for fixing two terminal housings 5 and 7 as is in the connector of JP-A-2010-211935 causes the problem that it takes time and efforts to attach and detach.


Furthermore, when the two terminal housings 5 and 7 are fixed by bolts, it is necessary to provide a working space for fixing a bolt, i.e., a space allowing a tool and a worker's hand to get in to tighten a bolt. Thus, even if a connector is downsized (reduced in height), it is essential to provide a working space in order to attach the connector and, as a result, a wide space is required when using such a connector.


It is an object of the invention to provide a connector that facilitates the attaching and detaching work and is to be attached in a narrow space, as well as a wire harness using the connector.


(1) According to one embodiment of the invention, a connector comprises:


a first terminal housing that houses a first connecting terminal; and


a second terminal housing that houses at least a portion of a cable comprising a second connecting terminal at an end portion thereof,


wherein the first connecting terminal and the second connecting terminal come into contact with each other and form a contact point when the first terminal housing is fitted to the second terminal housing,


wherein the two terminal housings are fitted in a direction intersecting with an extending direction of the cable that extends from the second terminal housing,


wherein the first terminal housing comprises a first fitting portion,


wherein the second terminal housing comprises a second fitting portion, and


wherein the connector further comprises a fitted-state maintaining member that is configured so as to be fitted to both the first and second fitting portions by being slid along a direction perpendicular to the fitting direction of the two terminal housings after the two terminal housings are fitted to each other such that the two terminal housings are held as-fitted.


In the above embodiment (1) of the invention, the following modifications and changes can be made.


(i) The fitted-state maintaining member is formed so as to sandwich the two terminal housings at least from the both sides and comprises a groove or a protrusion formed along the sliding direction of the fitted-state maintaining member inside of both side portions thereof, and


wherein the second fitting portion is formed linearly on both side surfaces of the second terminal housing along the sliding direction of the fitted-state maintaining member and comprises a protrusion or a groove to be slidably fitted to the groove or protrusion of the fitted-state maintaining member.


(ii) The first terminal housing further comprises a flange that protrudes from the second terminal housing in a direction perpendicular to the fitting direction of the two terminal housings when the two terminal housings are fitted to each other,


wherein the fitted-state maintaining member comprises a protrusion or a protrusion-holding portion to house and hold a protrusion formed outside of the both side portions of the fitted-state maintaining member, and


wherein the first fitting portion is formed on the flange and comprises a protrusion-holding portion or a protrusion corresponding to the protrusion or the protrusion-holding portion of the fitted-state maintaining member.


(iii) The fitted-state maintaining member comprises the protrusion formed outside of the both side portions and the first fitting portion comprises the protrusion-holding portion,


wherein the protrusion-holding portion as the first fitting portion comprises a vertical portion protruding from the flange toward the second terminal housing and a horizontal portion extending along the sliding direction from a tip portion of the vertical portion toward the fitted-state maintaining member insertion side such that the protrusion formed on the fitted-state maintaining member is guided between the horizontal portion and the flange, and


wherein a surface of the horizontal portion facing the flange is tapered such that an opening between the horizontal portion and the flange is gradually enlarged toward the fitted-state maintaining member insertion side.


(iv) The fitted-state maintaining member comprises a rear portion on a back side in the sliding direction so as to integrally connect the both side portions, and


wherein the flange comprises a fixing claw to lock the rear portion so as to fix the fitted-state maintaining member on the back side in the sliding direction of the fitted-state maintaining member.


(v) The fitted-state maintaining member is configured so as to be fitted to the both fitting portions by being slid from the cable side toward two terminal housings along the extending direction of the cable.


(vi) A plurality of ones of the first connecting terminal aligned are housed in the first terminal housing,


wherein a plurality of ones of the second connecting terminal aligned and a plurality of insulating members aligned are housed in the second terminal housing,


wherein a laminated structure is formed such that the first connecting terminals and the second connecting terminals are alternately arranged so that a surface of the first connecting terminals faces a surface of the second connecting terminals to form a pair and to form a plurality of contact points sandwiched between the insulating members when the first terminal housing is fitted to the second terminal housing, and


wherein the connector further comprises a connecting member to collectively fix and electrically connect the first connecting terminals and the second connecting terminals at each contact point by pressing the insulating members adjacent thereto.


(vii) The connecting member comprises a tool fitting hole for fitting a tool such that the connecting member is rotated by the tool fitted to the tool fitting hole to press the insulating members adjacent thereto,


wherein the fitted-state maintaining member is configured to cover the connecting member with one of the both side portions when the fitted-state maintaining member is fitted to the first and second fitting portions, and


wherein the one of the both side portions comprises a tool insertion holes configured to expose the tool fitting hole when the fitted-state maintaining member is completely fitted to the first and second fitting portions, and to allow the tool to rotate the connecting member.


(viii) The connector further comprises a tail plate having a two-divided structure to sandwich and hold the cable, and


wherein the cable is fixed to the second terminal housing by fixing the tail plate to the second terminal housing.


(2) According to another embodiment of the invention, a wire harness comprises:


a cable;


a second connecting terminal at an end portion of the cable; and a second terminal housing that houses at least a portion of the cable,


wherein the first connecting terminal and the second connecting terminal come into contact with each other and form a contact point when the second terminal housing is fitted to a first terminal housing that is configured to be fitted to the second terminal housing, to house the first connecting terminal and to be attached to a device as an attached object,


wherein the two terminal housings are fitted in a direction intersecting with an extending direction of the cable that extends from the second terminal housing,


wherein the first terminal housing comprises a first fitting portion,


wherein the second terminal housing comprises a second fitting portion, and


wherein the wire harness further comprises a fitted-state maintaining member that is configured so as to be fitted to both the first and second fitting portions by being slid along a direction perpendicular to the fitting direction of the two terminal housings after the two terminal housings are fitted to each other such that the two terminal housings are held as-fitted.


EFFECTS OF THE INVENTION

According to one embodiment of the invention, a connector can be provided that facilitates the attaching and detaching work and is to be attached in a narrow space, as well as a wire harness using the connector.





BRIEF DESCRIPTION OF THE DRAWINGS

Next, the present invention will be explained in more detail in conjunction with appended drawings, wherein:



FIGS. 1A and 1B are diagrams illustrating a connector in the present embodiment, wherein FIG. 1A is a cross sectional view and FIG. 1B is a perspective view showing only first and second connecting terminals and an insulating member assembly;



FIG. 2A is an exploded perspective view showing the connector of FIG. 1;



FIG. 2B is a perspective view showing the connector of FIG. 1;



FIGS. 3A and 3B are perspective views showing a first connector portion of the connector of FIG. 1;



FIGS. 4A and 4B are diagrams illustrating the first connecting terminals of the first connector portion of FIGS. 3A and 3B, wherein FIG. 4A is a perspective view and FIG. 4B is a plan view showing the first connecting terminals as viewed from the back side in an insertion direction thereof;



FIG. 5 is a perspective view showing a first terminal housing and a first inner housing of the first connector portion of FIGS. 3A and 3B;



FIGS. 6A and 6B are perspective views showing a second connector portion of the connector of FIG. 1;



FIG. 7A is a perspective view showing the second connector portion of FIG. 6 where the second terminal housing is removed;



FIG. 7B is a perspective view where the second inner housing is further removed;



FIG. 8 is a perspective view showing second connecting terminals of the second connector portion and cables of FIG. 6;



FIGS. 9A and 9B are perspective views showing the second inner housing of the second connector portion of FIG. 6;



FIGS. 10A and 10B are perspective views showing the second terminal housing of the second connector portion of FIG. 6;



FIG. 11 is a perspective view showing the state in which the second inner housing of FIGS. 9A and 9B is attached to the second terminal housing of FIGS. 10A and 10B;



FIGS. 12A to 12D are diagrams illustrating a connecting member of the second connector portion of FIG. 6, wherein FIG. 12A is a perspective view, FIG. 12B is a cross sectional view, FIG. 12C is a perspective view showing a cam and FIG. 12D is a perspective view showing a bolt;



FIGS. 13A and 13B are diagrams illustrating the connector of FIG. 1 when a fitted-state maintaining member is attached, wherein FIG. 13A is a perspective view and FIG. 13B is a side view as viewed from the cable side;



FIGS. 14A to 14C are explanatory diagrams illustrating that the fitted-state maintaining member is slidably attached;



FIGS. 15A and 15B are perspective views showing the fitted-state maintaining member;



FIG. 16A is a perspective view showing the insulating member assembly of the second connector portion of FIG. 6;



FIGS. 16B and 16C are perspective views showing a first insulating member;



FIG. 17A is a perspective view showing the first insulating member and a second connecting terminal;



FIG. 17B is a perspective view showing the first insulating member, the second connecting terminal and the first connecting terminal; and



FIG. 18 is a side view showing a connector in a modification of the invention.





DETAILED DESCRIPTION OF THE EMBODIMENTS

An embodiment of the invention will be described below in conjunction with the appended drawings.



FIGS. 1A to 2B are diagrams illustrating a connector in the present embodiment, wherein FIG. 1A is a cross sectional view, FIG. 1B is a perspective view showing only first and second connecting terminals and an insulating member assembly, FIG. 2A is an exploded perspective view and FIG. 2B is a perspective view thereof.


As shown in FIGS. 1A to 2B, a connector 1 in the present embodiment is composed of a first connector portion 2 and a second connector portion 3, and plural power lines are connected at a time by fitting the connector portions 2 and 3 together.


More specifically, the connector 1 is provided with the first connector portion 2 having a first terminal housing (male terminal housing) 5 housing plural (three) aligned first connecting terminals (male terminals) 4a to 4c, the second connector portion 3 having a second terminal housing (female terminal housing) 7 housing plural (three) aligned second connecting terminals (female terminals) 6a to 6c, and plural (four) insulating members 8a to 8d aligned and housed in the second terminal housing 7 for insulating the second connecting terminals 6a to 6c from each other.


The connector 1 is configured that, inside the first terminal housing 5 of the first connector portion 2 and the second terminal housing 7 of the second connector portion 3 which are fitted to each other, the first connecting terminals 4a to 4c and the second connecting terminals 6a to 6c are alternately arranged to form a laminated structure in which surfaces of the plural first connecting terminals 4a to 4c on one side face surfaces of the plural second connecting terminals 6a to 6c on one side to form respective pairs (a pair of the first connecting terminal 4a and the second connecting terminal 6a, that of the first connecting terminal 4b and the second connecting terminal 6b, and that of the first connecting terminal 4c and the second connecting terminal 6c) and to form plural contact points therebetween, and each contact point is sandwiched by two of the insulating members 8a to 8d.


In the connector 1, the first connector portion 2 is attached to a shielding case of a device such as inverter or motor so that the length direction of the first connecting terminals 4a to 4c is perpendicular to a surface of the device (including the shielding case), and the externally exposed first connecting terminals 4a to 4c are electrically connected to the power lines of the device. Cables 61a to 61c are connected to the second connector portion 3, and are respectively electrically connected to the power lines of the device by connecting the first connector portion 2 to the second connector portion 3. In the present embodiment, the second terminal housing 7 of the second connector portion 3 is configured such that the cables 61a to 61c extend in the length direction of the second connecting terminals 6a to 6c. Note that, although the second connecting terminals 6a to 6c are entirely housed in the second terminal housing 7 in the present embodiment, the second connecting terminals 6a to 6c may be exposed from the second terminal housing 7 as long as at least a portion of the cables 61a to 61c having the second connecting terminals 6a to 6c at end portions thereof is housed in the second terminal housing 7.


The connector 1 is configured that the two terminal housings 5 and 7 are fitted so that a length direction of the first connecting terminals 4a to 4c crosses that of the second connecting terminals 6a to 6c. In the present embodiment, the connector 1 is configured that the two terminal housings 5 and 7 are fitted so that the length direction of the first connecting terminals 4a to 4c is orthogonal to that of the second connecting terminals 6a to 6c. In other words, the connector 1 is configured that the two terminal housings 5 and 7 are fitted in a direction crossing the extending direction of the cables 61a to 61c which extend from the second terminal housing 7. Therefore, in the connector 1, when the two terminal housings 5 and 7 are fitted to each other, the cables 61a to 61c extend in a direction parallel to a surface of the device to which the first terminal housing 5 is attached.


The wire harness of the present embodiment is the cables 61a to 61c with the connector 1 (the second connector portion 3) provided at an end portion thereof.


Each configuration of the connector portions 2 and 3 will be described in detail below.


First Connector Portion


Firstly, the first connector portion 2 will be described.


As shown in FIGS. 1A to 5, the first connector portion 2 is provided mainly with the first connecting terminals 4a to 4c, the first terminal housing 5 and a first inner housing 10.


Electricity of different voltage and/or current is transmitted to each of the first connecting terminals 4a to 4c. For example, the present embodiment assumes the use of a three-phase AC power line between a motor and an inverter, and alternate current having a phase difference of 120° is transmitted to each of the first connecting terminals 4a to 4c. Each of the first connecting terminals 4a to 4c should be formed of a highly conductive metal such as silver, copper or aluminum to reduce transmission loss, etc., in the connector


1. In addition, each of the first connecting terminals 4a to 4c has little flexibility.


For shielding performance, heat dissipation and weight saving of the connector 1, the first terminal housing 5 is preferably formed of light metal having high electrical and thermal conductivity such as aluminum, but may be formed of resin, etc. In the present embodiment, the first terminal housing 5 is formed of aluminum.


The first inner housing 10 is formed of an insulating resin (e.g., PPS (polyphenylene sulfide) resin, PPA (polyphthalamide) resin, PA (polyamide) resin, PBT (polybutylene terephthalate) and epoxy-based resin), etc.


The first connecting terminals 4a to 4c are respectively inserted into through-holes 10a formed on the first inner housing 10 and are then fixed. The first inner housing 10 is attached to the first terminal housing 5 so as to cover a terminal-attaching hole 5a formed on the first terminal housing 5, and the first connecting terminals 4a to 4c are thereby fixed to the first terminal housing 5 via the first inner housing 10 and are held in the first terminal housing 5 in the state of being aligned at predetermined intervals. Protruding portions 10b are provided on the first inner housing 10 so as to protrude outward from rims of the through-holes 10a. This increases a contact area of the first inner housing 10 with the first connecting terminals 4a to 4c and it is thus possible to firmly hold the first connecting terminals 4a to 4c.


The first terminal housing 5 is composed of a hollow cylindrical body 20 having a substantially rectangular horizontal cross-section and a lid portion 24 which is provided integrally with the cylindrical body 20 so as to cover one of openings of the cylindrical body 20 and has the terminal-attaching hole 5a formed thereon. The lid portion 24 is a portion to be in contact with a surface of the shielding case when the first connector portion 2 is attached to the shielding case of the device and a flange 25 is integrally formed at a rim of the lid portion 24 and protrudes beyond the second terminal housing 7 in the directions perpendicular to the fitting direction of the two terminal housings 5 and 7 in the state that the two terminal housings 5 and 7 are fitted to each other.


Note that, the first terminal housing 5 may be a portion of the shielding case (a portion of the device as an attachment target). In other words, the structure may be such that a housing provided on the cables 61a to 61c is fitted to an insertion hole formed on the shielding case of the device. In this case, such a portion of the shielding case serves as the first terminal housing 5 and the housing provided on the cables 61a to 61c to be fitted to the insertion hole serves as the second terminal housing 7.


The cylindrical body 20 is housed in the second terminal housing 7 when the two terminal housings 5 and 7 are fitted to each other. A groove 22 is formed on the outer periphery of the cylindrical body 20 along a circumferential direction and a packing (not shown) such as O-ring is placed in the groove 22 to make watertight between the second terminal housing 7 and the cylindrical body 20 when the two terminal housings 5 and 7 are fitted to each other. At an end portion of the cylindrical body 20 opposite to the lid portion 24, an edge on the outer peripheral side is formed in a tapered shape in light of fitting properties to the second terminal housing 7.


A first fitting portion 31 for fitting a below-described fitted-state maintaining member 70 is provided on the first terminal housing 5. The first fitting portion 31 will be described in detail later.


In the first terminal housing 5, the first connecting terminals 4a to 4c are arranged so as to be aligned in the thickness direction thereof. In the present embodiment, the first connecting terminals 4a and 4c are shaped into a crank shape so that the first connecting terminals 4a to 4c at a portion exposed to the outside from the first terminal housing 5 are aligned in a width direction.


As shown in FIGS. 4A and 4B, an S-shaped connecting portion 60b connects between side faces of end portions of two parallel plate-like members 60a, and the first connecting terminals 4a and 4c are thereby formed in a crank shape as viewed from any of the thickness direction, the width direction and the length direction. The first connecting terminals 4a and 4c are formed in the same shape and are arranged symmetric about the center of the first connecting terminal 4b in the thickness and width directions (180° rotational symmetry). Such a configuration allows an arrangement direction of terminals to be changed without impairing symmetric properties of the power lines, hence, easy connection to the power lines of the device. Note that, the shape of the first connecting terminals 4a to 4c at the portion exposed to the outside from the first terminal housing 5 is not limited thereto and can be appropriately changed according to requirements on the device side. The tip portions of the first connecting terminals 4a to 4c are chamfered (or rounded) for easy insertion into a below-described insulating member assembly 100.


Second Connector Portion


Next, the second connector portion 3 will be described.


As shown in FIGS. 1A to 2B and 6A to 7B, the second connector portion 3 holds, inside thereof, three second connecting terminals 6a to 6c aligned at predetermined intervals, and is provided with the second terminal housing 7 housing the three aligned second connecting terminals 6a to 6c, plural insulating members 8a to 8d in a substantially rectangular parallelepiped shape which are provided in the second terminal housing 7 for insulating the second connecting terminals 6a to 6c from each other, and a connecting member 9 for collectively fixing and electrically connecting the plural first connecting terminals 4a to 4c to the plural second connecting terminals 6a to 6c at respective contact points by pressing the adjacent insulating member 8a.


The cables 61a to 61c extending from a motor are respectively connected to the second connecting terminals 6a to 6c on one side. The cables 61a to 61c are each composed of a conductor 62 and an insulation layer 63 formed on the outer periphery thereof. The conductor 62 having a cross-sectional area of 20 mm2 is used in the present embodiment.


Each of the second connecting terminals 6a to 6c should be formed of a highly conductive metal such as silver, copper or aluminum to reduce transmission loss, etc., in the connector 1. In addition, each of the second connecting terminals 6a to 6c has little flexibility.


As shown in FIG. 8, each of the second connecting terminals 6a to 6c has a crimping portion 45 for crimping the conductor 62 exposed at a tip portion of each of the cables 61a to 61c and a plate-like member 46 integrally formed with the crimping portion 45, and is formed in a crank shape by bending the plate-like member 46 at the base end portion (a connecting portion with the crimping portion 45) into an S-shape. Protrusions 27a are formed on the plate-like member 46 so as to protrude upward (downward) from both widthwise edges at the base end portion of the plate-like member 46. The protrusions 27a constitute a below-described slip-off prevention mechanism 27. The tip portions of the second connecting terminals 6a to 6c are chamfered (or rounded) for easy insertion into the insulating members 8b to 8d.


As shown in FIGS. 6A to 7B, a second inner housing 30, which is constructed from a resin molded article and has a multi-cylindrical shape (a shape formed of contiguous plural cylinders), holds the cables 61a to 61c aligned at predetermined intervals. The second connecting terminals 6a to 6c are fixed to the second terminal housing 7 via the cables 61a to 61c and the second inner housing 30. At this time, the second connecting terminals 6a to 6c are positioned and held respectively under (on the opposite side to the connecting member 9) the first connecting terminals 4a to 4c (i.e., connection targets) which respectively face and are paired with the second connecting terminals 6a to 6c when the first connector portion 2 is fitted to the second connector portion 3.


The second inner housing 30 is formed of an insulating resin (e.g., PPS (polyphenylene sulfide) resin, PPA (polyphthalamide) resin, PA (polyamide) resin, PBT (polybutylene terephthalate) and epoxy-based resin), etc., to prevent short circuit by insulating the second connecting terminals 6a to 6c from each other. The second inner housing 30 allows the second connecting terminals 6a to 6c to be held at respective predetermined positions even when each of the cables 61a to 61c respectively connected to the second connecting terminals 6a to 6c is very flexible. In other words, since a cable excellent in flexibility can be used as the cables 61a to 61c in the present embodiment, it is possible to improve the wiring flexibility for laying the cables 61a to 61c.


As shown in FIGS. 9A and 9B, the second inner housing 30 is formed in a multi-cylindrical shape composed of three contiguous square cylinders each opened on one side, has a main body 30a formed in a rectangular parallelepiped shape as a whole, a plate-like parallel portion 30b extending from a side edge portion of the main body 30a in an insertion direction of the cables 61a to 61c and a plate-like vertical portion 30c orthogonally extending from the front edge of the parallel portion 30b, and is configured that the insulating members 8a to 8d are housed in a space 30d which is surrounded by the parallel portion 30b, the vertical portion 30c and a surface of the main body 30a on the front side in the insertion direction of the cables 61a to 61c.


Positioning protrusions 30h are formed at the lower edge portion of the parallel portion 30b, in more detail, at corners located at the lower edge portion of the parallel portion 30b and respectively at an intersection of the parallel portion 30b and the surface of the main body 30a on the front side in the insertion direction of the cables 61a to 61c and an intersection of the vertical portion 30c and the parallel portion 30b. The positioning protrusions 30h are inserted into connecting grooves 82 of the outermost first insulating member 8d (described later) to position the insulating member assembly 100 (described later) with respect to the second terminal housing 7.


Terminal insertion holes 30e for inserting the second connecting terminals 6a to 6c (for exposing the tip portions of the second connecting terminals 6a to 6c from the main body 30a) are formed on the surface of the main body 30a on the front side in the insertion direction of the cables 61a to 61c. In addition, locking protrusions 30f for locking and fixing the second inner housing 30 to the second terminal housing 7 are formed on upper and lower surfaces of the main body 30a (both side surfaces in the arrangement direction of the cables 61a to 61c).


Although the second connecting terminals 6a to 6c in the present embodiment are inserted into the terminal insertion holes 30e so that the second connecting terminals 6a to 6c are directly held by the second inner housing 30 and are positioned, it is not limited thereto. It is also possible to position the second connecting terminals 6a to 6c by holding the cables 61a to 61c (in more detail, by holding the end portion of the cables 61a to 61c at a position close to the second connecting terminals 6a to 6c). Note that, it is preferable that the terminal insertion hole 30e be formed slightly larger than the second connecting terminals 6a to 6c so that deformation of the second connecting terminals 6a to 6c is suppressed when pressed by the connecting member 9.


The second connector portion 3 is provided with the slip-off prevention mechanism 27 so that the cables 61a to 61c are not pulled out from the second inner housing 30 even when the cables 61a to 61c are pulled. The slip-off prevention mechanism 27 is composed of the protrusions 27a formed at the respective base end portions of the second connecting terminals 6a to 6c (in the vicinity of the cables 61a to 61c; in the present embodiment, at an end portion of the plate-like member 46 on the crimping portion 45 side), and an inner plate 27b for locking the protrusions 27a to restrict the protrusions 27a from moving backward (toward the cables 61a to 61c) (see FIG. 1A). An inner plate insertion hole 30g is formed on a side surface of the main body 30a (a side surface facing the opening of the second terminal housing 7) and the inner plate 27b is inserted therethrough so as to protrude into each of the multiple cylinders after the cables 61a to 61c and the second connecting terminals 6a to 6c are inserted into the main body 30a of the second inner housing 30, thereby providing the inner plate 27b. Note that, the structure of the inner plate 27b is not limited in the present embodiment and any structure is acceptable as long as the protrusions 27a of the three second connecting terminals 6a to 6c are locked and movement of the protrusions 27a is restricted.


As shown in FIGS. 1A, 1B, 6A, 6B, 10A and 10B, the second terminal housing 7 is constructed from a hollow cylindrical body 36 opening on one side and having a substantially rectangular cross section, and is configured that the first terminal housing 5 is inserted and fitted to the opening of the cylindrical body 36. A cylindrical cable insertion portion 36a for inserting the cables 61a to 61c is formed integrally on the lateral side of the cylindrical body 36 (the side surface on the right side in 10A and 10B). A hollow portion in the cylindrical body 36 is in communication with that in the cable insertion portion 36a via three rectangular insertion holes 36f for passing the cables 61a to 61c, and the cables 61a to 61c pass through the hollow portion in the cable insertion portion 36a and the insertion holes 36f and are then inserted into the cylindrical body 36. The insertion direction of the first terminal housing 5 is orthogonal to the insertion direction of the cables 61a to 61c.


A braided shield may be wound around the cables 61a to 61c led out of the second terminal housing 7 in order to improve the shielding performance even though it is not illustrated. For example, the braided shield is electrically connected to the first terminal housing 5 via the second terminal housing 7 and is kept at ground potential.


Furthermore, the outer periphery of the cable insertion portion 36a from where the cables 61a to 61c are led out is covered by a rubber boot for preventing water from entering into the cable insertion portion 36a or the cylindrical body 36, even though it is not illustrated.


Meanwhile, a connecting member insertion hole 26 for inserting the connecting member 9 is formed on an upper portion of the cylindrical body 36 (on the upper side in FIGS. 10A and 10B). The second terminal housing 7 is formed to have a cylindrical shape (hollow cylinder) at the rim of the connecting member insertion hole 26.


A rectangular parallelepiped-shaped pedestal 87 protruding toward the connecting member insertion hole 26 is provided on an inner peripheral surface of the cylindrical body 36 at a position facing the connecting member insertion hole 26. In the connector 1, the laminated structure is sandwiched and held between the connecting member 9 and the pedestal 87, and a pressing force is applied to the laminated structure by pressing the connecting member 9 toward the pedestal 87 and is thereby applied to each contact point. In addition, locking grooves 36c are provided on the inner peripheral surface of the cylindrical body 36. The locking grooves 36c are locked to the locking protrusions 30f of the second inner housing 30, thereby fixing the second inner housing 30 to the cylindrical body 36.


As shown in FIG. 11, the second inner housing 30 is arranged so that the main body 30a is arranged next to the pedestal 87 on the cable insertion portion 36a side, the parallel portion 30b extends over the pedestal 87 and the vertical portion 30c is located on a side of the pedestal 87 opposite to the cable insertion portion 36a. Once the second inner housing 30 is attached to the second terminal housing 7, the positioning protrusions 30h of the second inner housing 30 are placed on the pedestal 87.


For shielding performance, heat dissipation and weight saving of the connector 1, the second terminal housing 7 is preferably formed of light metal having high electrical and thermal conductivity such as aluminum, but may be formed of resin, etc. In the present embodiment, the cylindrical body 36 is formed of aluminum.


A second fitting portion 41 for fitting the below-described fitted-state maintaining member 70 is provided on the second terminal housing 7. The second fitting portion 41 will be described in detail later.


In the present embodiment, the two terminal housings 5 and 7 are fixed by the fitted-state maintaining member 70 (the details thereof will be described later). However, even if the two terminal housings 5 and 7 are fixed, vibration of the cables 61a to 61c in the second terminal housing 7 still may be transmitted and may cause frictional wear of the connecting terminals 4a to 4c and 6a to 6c. Thus, in the present embodiment, the cables 61a to 61c are fixed to the second terminal housing 7 to prevent oscillation of the cables 61a to 61c from being transmitted and causing frictional wear of the first connecting terminals 4a to 4c and the second connecting terminals 6a to 6c.


In detail, as shown in FIGS. 7A and 7B, the cables 61a to 61c are sandwiched by a tail plate(s) 50 having a two-divided structure provided with holes 50a for sandwiching and holding the cables 61a to 61c, claws 50b provided on the tail plate 50 are locked to grooves 36d (see FIGS. 10A and 10B) of the cable insertion portion 36a to fix the tail plate 50 to the cable insertion portion 36a, and the cables 61a to 61c are thereby fixed to the cable insertion portion 36a via the tail plate 50. Two tail plates 50 are used to fix the cables 61a to 61c more firmly in the present embodiment but the number of the tail plates 50 may be one. The tail plate 50 is restricted from moving to the inside of the cylindrical body 36 by the wall in the periphery of the insertion holes 36f (see FIG. 10A) and thereby serves to prevent the cables 61a to 61c from being forcibly pushed in the cylindrical body 36. Furthermore, the tail plate 50 serves to prevent water from entering the second terminal housing 7 along the cables 61a to 61c.


As shown in FIGS. 1A, 1B and 6A to 7B, among the plural insulating members 8a to 8d, the plural first insulating members 8b to 8d are aligned and housed in the second terminal housing 7 and are also provided integrally with the respective surfaces of the plural second connecting terminals 6a to 6c on another side (surfaces opposite to the surfaces connected to the first connecting terminals 4a to 4c), and a second insulating member 8a is provided so as to face the surface of the outermost first connecting terminal 4a (the uppermost side in FIGS. 1A, 1B and 6A to 7B) on another side (a surface opposite to the surface connected to the second connecting terminal 6a) when the plural first connecting terminals 4a to 4c and the plural second connecting terminals 6a to 6c form a laminated state.


In the connector 1 of the present embodiment, the insulating member assembly 100, which has an insulating member restricting means 101 for restricting movement of the insulating members 8a to 8d in a direction perpendicular to a lamination direction of the laminated structure, is formed by connecting the insulating members 8a to 8d to each other. The insulating member restricting means 101 is configured to restrict movement of the insulating members 8a to 8d in the x-y plane of the orthogonal coordinate system in which the lamination direction of the laminated structure is the z-axis.


Holes for inserting the connecting terminals 4a to 4c and 6a to 6c to be inserted orthogonal to each other, i.e., first terminal insertion holes 102 for inserting the first connecting terminals 4a to 4c and second terminal insertion holes 103 for inserting the second connecting terminals 6a to 6c, are provided on the insulating member assembly 100. The first terminal insertion hole 102 is formed between adjacent two of the insulating members 8a to 8d and the second terminal insertion hole 103 is formed on each of the first insulating members 8b to 8d. The insulating member assembly 100 will be described in detail later.


As shown in FIGS. 12A to 12D, the connecting member 9 is composed of the cam 9a and a bolt 9b. The cam 9a is formed in a cylindrical shape opening only on the lower side and has an irregular-shaped tool fitting hole 9c (in the present embodiment, a star shape) formed on an upper surface so that a tool such as wrench can be fitted to the tool fitting hole 9c to rotate the cam 9a. On the side surface of the cam 9a, a groove 9h is formed to house a packing 14 (see FIG. 1A) such as O-ring which is provided to keep water from entering the second terminal housing 7. The lower portion of the cam 9a (including a position for forming the groove 9h) has an enlarged diameter having a flange shape. When inserting the cam 9a into the connecting member insertion hole 26 of the second terminal housing 7 and fitting and fixing a ring-shaped fixing member 26b into a groove 26a formed on the inner peripheral surface of the connecting member insertion hole 26 as shown in FIG. 1A, the flange portion which comes into contact with the fixing member 26b restricts movement of the cam 9a toward the outside and the cam 9a is thus rotatably held between the second terminal housing 7 and the fixing member 26b.


An upper portion of the bolt 9b is inserted into the hollow portion in the cam 9a. The bolt 9b is formed in a cylindrical shape opening only on the lower side and has raised portions 9d which are formed at circumferentially opposite positions so as to protrude outward (see FIG. 12D). The bolt 9b has a flange-like enlarged diameter at the lower portion thereof. Notches 9e formed on the flange portion are slidably engaged with linear protrusions 36e (see FIG. 10A) formed on the second terminal housing 7 so as to extend vertically, which allows the bolt 9b to slide in a vertical direction without rotating together with the cam 9a.


Slopes 9f gradually protruding downward along the circumferential direction are formed at a rim of the upper surface of the cam 9a inside the hollow portion. Two slopes 9f are formed at 180° rotationally symmetric positions around a rotational axis of the cam 9a so as to correspond to the two raised portions 9d of the bolt 9b. A stopper 9g which comes into contact with the raised portion 9d of the bolt 9b to prevent excessive rotation of the cam 9a is provided at an end portion of each slope 9f on the downwardly protruding side.


The connecting member 9 is configured that, when the cam 9a is rotated, the slopes 9f come into contact with the raised portions 9d of the bolt 9b and move the bolt 9b toward the second insulating member 8a and the second insulating member 8a is thereby pressed. Due to such a configuration, the cam 9a to be rotated by a worker is always located at a certain position and does not move vertically, which improves workability.


The cam 9a and the bolt 9b which are formed of a metal such as SUS, iron or copper alloy are used. The cam 9a and the bolt 9b may be formed of a resin but are preferably formed of metal from the viewpoint of strength.


Meanwhile, an elastic member 15 for applying a predetermined pressing force to the second insulating member 8a is provided between the bolt 9b of the connecting member 9 and the upper surface of the second insulating member 8a immediately therebelow. In the present embodiment, the upper portion of the elastic member 15 is housed in the hollow portion in the bolt 9b. This is an idea to reduce a distance between the bolt 9b and the second insulating member 8a and to downsize the connector 1 even when the elastic member 15 is long to some extent. The elastic member 15 is constructed from a spring formed of metal (e.g., SUS, etc.). Note that, the elastic member 15 is regarded as a portion of the connecting member 9 in the present embodiment.


A concave portion 16 covering (housing) a lower portion of the elastic member 15 is formed on the upper surface of the second insulating member 8a with which the lower portion of the elastic member 15 is in contact, and a receiving member 17 formed of metal (e.g., SUS, etc.) for preventing the second insulating member 8a formed of an insulating resin from being damaged by receiving the elastic member 15 is provided on a bottom of the concave portion 16 (i.e., a seat portion with which the lower portion of the elastic member 15 is in contact).


The receiving member 17 is to prevent damage on the second insulating member 8a by dispersing stress applied from the elastic member 15 to the upper surface of the second insulating member 8a. Therefore, a contact area between the receiving member 17 and the second insulating member 8a is preferably as large as possible. The receiving member 17 having a shape in contact throughout the entire bottom surface of the concave portion 16 is provided in the present embodiment in order to increase the contact area between the receiving member 17 and the second insulating member 8a.


Connection Between First Connector Portion and Second Connector Portion


When the two terminal housings 5 and 7 are fitted to each other, the first connecting terminals 4a to 4c are respectively inserted into the first terminal insertion holes 102 and are then inserted into respective gaps between the second connecting terminals 6a to 6c to be respectively paired therewith and the insulating members 8a to 8d. This insertion provides a laminated structure in which the surfaces of the plural first connecting terminals 4a to 4c on the one side face the surfaces of the plural second connecting terminals 6a to 6c on the one side to form the respective pairs, and the first connecting terminals 4a to 4c, the second connecting terminals 6a to 6c and the insulating members 8a to 8d are alternately arranged, i.e., the insulating members 8a to 8d are arranged so as to sandwich the pairs of the first connecting terminals 4a to 4c and the second connecting terminals 6a to 6c.


At this time, in the second connector portion 3, since the first insulating members 8b to 8d are respectively provided at the tips of the second connecting terminals 6a to 6c aligned and held at predetermined intervals, each gap between the insulating members 8b to 8d can be kept without additionally providing a retaining jig for keeping respective gaps between the insulating members 8b to 8d. This makes easy to insert the first connecting terminals 4a to 4c into the respective gaps between the second connecting terminals 6a to 6c to be respectively paired therewith and the insulating members 8a to 8d. In other words, the insertion and extraction properties of the first connecting terminals 4a to 4c are not degraded. In addition, it is very effective in that it is possible to realize further downsizing as compared to the conventional art since it is not necessary to provide a retaining jig for keeping the gaps between the insulating members 8b to 8d.


Meanwhile, a contact point between the first connecting terminal 4a and the second connecting terminal 6a is sandwiched between the second insulating member 8a and the first insulating member 8b attached to the second connecting terminal 6a constituting the contact point. Likewise, a contact point between the first connecting terminal 4b (or 4c) and the second connecting terminal 6b (or 6c) is sandwiched between the first insulating member 8c (or 8d) attached to the second connecting terminal 6b (or 6c) constituting the contact point and the first insulating member 8b (or 8c) attached to the second connecting terminal 6a (or 6b) constituting another contact point.


When the cam 9a of the connecting member 9 is turned by a tool such as wrench in this state so as to be pressed downward, the second insulating member 8a, the first insulating member 8b, the first insulating member 8c and the first insulating member 8d are pressed in this order by the elastic member 15, a pressing force is applied to each contact point by any two of the insulating members 8a to 8d sandwiching and pressing each contact point, causing contact in a state that the contact points are insulated from each other. At this time, the first connecting terminals 4a to 4c and the second connecting terminals 6a to 6c are bent in some degree due to pressure from the insulating members 8a to 8d and respectively make contact in a large area. This makes strong contact and fixation of each contact point even under the environment in which vibration occurs, such as in a vehicle.


Fitted-State Maintaining Member


Next, the fitted-state maintaining member which is an essential part of the invention will be described.


As shown in FIGS. 13A to 15B, the connector 1 in the present embodiment is provided with the fitted-state maintaining member 70 which holds two terminal housings 5 and 7 as-fitted. After the two terminal housings 5 and 7 are fitted to each other, the fitted-state maintaining member 70 slides along a direction perpendicular to a fitting direction of the two terminal housings 5 and 7 and is fitted to both of the first fitting portions 31 provided on the first terminal housing 5 and the second fitting portions 41 provided on the second terminal housing 7. The fitted-state maintaining member 70 may be formed of a resin or a metal. The fitted-state maintaining member 70 formed of a resin is used in the present embodiment.


In the present embodiment, the fitted-state maintaining member 70 slides from the cables 61a to 61c side toward the two terminal housings 5 and 7 along the extending direction of the cables 61a to 61c and is then fitted to the both fitting portions 31 and 41. Such a configuration to fit the fitted-state maintaining member 70 by sliding from the cables 61a to 61c side toward the two terminal housings 5 and 7 allows the fitted-state maintaining member 70 to be attached even when there is no working space around the connector 1 on the lateral sides of the cables 61a to 61c (lateral sides in the lamination direction of the laminated structure) or the opposite side to the cables 61a to 61c, and it is thereby possible to easily fix the two terminal housings 5 and 7 even in a very narrow space.


The fitted-state maintaining member 70 is formed to sandwich the two terminal housings 5 and 7 at least from the both sides and the two terminal housings 5 and 7 are thus fixed on both sides thereof. In the present embodiment, the fitted-state maintaining member 70 is composed of lateral portions 71, a rear portion 72 and an upper portion 73. The lateral portions 71 are formed so as to respectively cover both sides of the second terminal housing 7 (lateral sides in the lamination direction of the laminated structure). The rear portion 72 covers the second terminal housing 7 on the cables 61a to 61-extending side and is integrally connected to the two lateral portions 71 on the backward in the sliding direction thereof. The upper portion 73 covers a side of the second terminal housing 7 opposite to the first terminal housing 5 and is integrally connected to end portions of the both lateral portions 71 and of the rear portion 72 opposite to the first terminal housing 5. An insertion hole 72a through which the cables 61a to 61c and the cable insertion portion 36a are inserted is formed on the rear portion 72. On the lateral portion 71 located on the side facing the connecting member 9, a portion on the front side in the sliding direction protrudes laterally and thereby forms a raised portion 71a to avoid contact with the second terminal housing 7 around the connecting member insertion hole 26.


In the present embodiment, grooves 74 (FIGS. 15A and 15B) formed along the sliding direction are provided on the inner side (on the inner walls) of the two lateral portions 71 of the fitted-state maintaining member 70 while the second fitting portions 41 each constructed from a protrusion 42 to be slidably fitted to the groove 74 of the fitted-state maintaining member 70 are formed linearly on the both side surfaces of the second terminal housing 7 along the sliding direction of the fitted-state maintaining member 70. The protrusions 42 are inserted into the grooves 74 and the fitted-state maintaining member 70 then slides while the protrusions 42 is guided by the grooves 74. Note that, although the grooves 74 are formed on the fitted-state maintaining member 70 and the protrusions 42 on the second terminal housing 7 in the present embodiment, the positions of the groove and the protrusion may be reversed.


In the present embodiment, it is necessary to form the fitted-state maintaining member 70 to be thick to some extent in order to provide the groove 74 on the lateral portion 71. In this regard, holes 71b are formed inside the lateral portion 71 so that the weight can be reduced as much as possible even when the lateral portion 71 is formed thick.


Furthermore, in the present embodiment, a second protrusion 42a (see FIG. 6B) is formed to protrude from the upper surface (the surface opposite to the first terminal housing 5) of the protrusion 42 of the second fitting portion 41 and a second groove 74a (see FIGS. 15A and 15B) is formed on the upper surface (the surface opposite to the first terminal housing 5) of the groove 74 of the fitted-state maintaining member 70 so as to slidably house the second protrusion 42a. The second protrusion 42a and the second groove 74a serve as a guide at the time of fitting the fitted-state maintaining member 70, serve to prevent excessive insertion of the fitted-state maintaining member 70 and serve as a stopper for locking the fitted-state maintaining member 70.


In addition, protrusions 75 protruding outward are formed on the outer side (on the outer walls) of the two lateral portions 71 of the fitted-state maintaining member 70, while the first fitting portions 31 each constructed from a protrusion-holding portion 32 for housing and holding the protrusion 75 are formed on the flange 25 of the first terminal housing 5 so as to correspond to the protrusions 75 of the fitted-state maintaining member 70. Note that, although the protrusions 75 are formed on the fitted-state maintaining member 70 and the protrusion-holding portion 32 on the first terminal housing 5, the positions of the protrusion and the protrusion-holding portion may be reversed.


In addition, guide grooves 25a (see FIG. 3) are formed on the flange 25. By inserting the lower end portions of the lateral portions 71 of the fitted-state maintaining member 70 (end portions opposite to the upper portion 73) into the guide grooves 25a, the lateral portions 71 are guided and the fitted-state maintaining member 70 is thus guided to slide.


In the present embodiment, the fitted-state maintaining member 70 is configured to fit to the second fitting portions 41 on the inner side of the lateral portions 71 and to the first fitting portions 31 on the outer side of the lateral portions 71. This is because a pressing force when the connecting member 9 presses the adjacent insulating member 8a acts to laterally stretch the second terminal housing 7 and, if, for example, it is configured to fit to both of the fitting portions 31 and 41 on the inner side of the lateral portions 71, the fitted-state maintaining member 70 is also stretched together with lateral stretch of the second terminal housing 7 and it may not be possible to maintain the fitted state of the two terminal housings 5 and 7. When providing the fitting portions 31 and 41 on both sides in the lamination direction, the fitted-state maintaining member 70 is desirably configured to fit to the second fitting portions 41 on the inner side of the lateral portions 71 and to the first fitting portions 31 on the outer side of the lateral portions 71 so that the fitted state of the two terminal housings 5 and 7 can be maintained even when the second terminal housing 7 is laterally stretched.


In addition, a fixing claw 33 is provided on the flange 25 on the backward in the sliding direction of the fitted-state maintaining member 70 (on the cables 61a to 61c side) and locks the rear portion 72 of the fitted-state maintaining member 70 to fix the fitted-state maintaining member 70. In the present embodiment, the protrusions 75 and the protrusion-holding portions 32 are provided at positions on the front side in the sliding direction with respect to the center portion as viewed from the lateral side of the second terminal housing 7 (the center portion in the longitudinal direction of the cables 61a to 61c or the extending direction of the cables 61a to 61c or the sliding direction of the fitted-state maintaining member 70), i.e., at positions only on the opposite side to the cables 61a to 61c. The first terminal housing 5 and the fitted-state maintaining member 70 are thus fixed at three points in total. Here, it is configured that the lower end portion of the rear portion 72 is formed to extend forward in the sliding direction and the fitted-state maintaining member 70 is fixed to the flange 25 by locking the Γ-shaped fixing claw 33 to a front end portion of the lower end portion of the rear portion 72. However, a locking structure is not limited thereto and can be appropriately changed.


Furthermore, the fitted-state maintaining member 70 is formed to cover the connecting member 9 with one of the lateral portions 71 (on the connecting member 9 side) when the fitted-state maintaining member 70 is fitted to the both fitting portions 31 and 41, to expose the tool fitting hole 9c when the fitted-state maintaining member 70 is perfectly fitted to the both fitting portions 31 and 41 and to have a tool insertion hole 71c allowing the tool to rotate the connecting member 9 (the cam 9a).


That is, the connector 1 is configured such that the tool fitting hole 9c is covered with the lateral portion 71 so as not to allow the cam 9a of the connecting member 9 to be rotated when the fitted-state maintaining member 70 is imperfectly fitted and the tool fitting hole 9c is exposed from the tool insertion hole 71c to allow a tool to be inserted into the tool fitting hole 9c through the tool insertion hole 71c to operate the connecting member 9 only when the fitted-state maintaining member 70 is perfectly fitted to the both fitting portions 31 and 41. It should be noted that, in FIG. 13A, the tool fitting hole 9c is not exposed from the tool insertion hole 71c since the fitted-state maintaining member 70 is not perfectly fitted to the both fitting portions 31 and 41. By such a configuration, it is possible to reliably fit the fitted-state maintaining member 70 during the fitting work of the two connector portions 2 and 3 and this allows a worker to carry out reliable work.


A protrusion 34 protruding outward is formed on the second terminal housing 7 opposite to the side to which the first terminal housing 5 is fitted. Meanwhile, a tongue-like locking portion 76 having a locking hole 76a to lock the protrusion 34 is formed on the fitted-state maintaining member 70. A stopper 78 for fixing the fitted-state maintaining member 70 to the second terminal housing 7 is composed of the protrusion 34 and the locking portion 76 which are locked to each other when the fitted-state maintaining member 70 is perfectly fitted to the both fitting portions 31 and 41. The tip portion of the protrusion 34 is tapered so as to be easily locked to the locking portion 76 at the time of fitting the fitted-state maintaining member 70.


Note that, the position and the specific structure of the stopper 78 are not limited thereto. However, the stopper 78 is desirably configured to allow a worker to attach/detach the fitted-state maintaining member 70 with one hand. In the present embodiment, a worker can unlock the protrusion 34 from the locking portion 76 with one hand and thus can easily detach the fitted-state maintaining member 70, hence, excellent in workability.


Insulating Member Assembly


Next, the insulating member assembly 100 will be described in detail.


As shown in FIGS. 1A, 1B, 7A, 7B and 16A to 16C, the insulating member assembly 100 is formed by sequentially connecting the insulating members 8a to 8d in the lamination direction. That is, the insulating member assembly 100 is formed by respectively connecting the second insulating member 8a to the first insulating member 8b, the first insulating member 8b to the first insulating member 8c, and the first insulating member 8c to the first insulating member 8d.


In the insulating member assembly 100, the insulating member restricting means 101 restricts the insulating members 8a to 8d from moving in a direction perpendicular to the lamination direction when the insulating members 8a to 8d are connected to each other. In the insulating member assembly 100, the insulating members 8a to 8d are connected to be relatively movable in the lamination direction in order to transfer a pressing force of the connecting member 9 to each contact point.


The insulating member restricting means 101 is provided with plural connecting pieces 81 and plural connecting grooves 82. The connecting pieces 81 are provided on one of the two insulating members 8a, 8b, 8c or 8d adjacent in the lamination direction and protrude toward the other adjacent insulating member 8a, 8b, 8c or 8d. The connecting grooves 82 are provided on the other adjacent insulating member 8a, 8b, 8c or 8d so as to correspond to the plural connecting pieces 81 and receive the plural connecting pieces 81 so as to be slidable in the lamination direction.


In the present embodiment, the insulating members 8a to 8d are formed in a substantially rectangular shape as viewed from the lamination direction thereof and one or both of the connecting piece 81 and the connecting groove 82 are formed at least at two of four corners of the insulating members 8a to 8d. Here, the case where one or both of the connecting piece 81 and the connecting groove 82 are formed at four corners of the insulating members 8a to 8d will be described.


In insulating member assembly 100, the connecting pieces 81 are integrally formed on the first insulating members 8b to 8d so as to extend from four corners in the width direction of the first insulating members 8b to 8d toward the opposite insulating members 8a to 8c (toward the second insulating member 8a from the first insulating member 8b, toward the first insulating member 8b from the first insulating member 8c and toward the first insulating member 8c from the first insulating member 8d) with interposition of the second connecting terminals 6a to 6c to which the first insulating members 8b to 8d are attached.


In addition, the connecting grooves 82 for receiving the connecting pieces 81 so as to be slidable in the lamination direction are respectively formed on the both side surfaces of the insulating members 8a to 8c opposite to the first insulating members 8b to 8d (facing with interposition of the second connecting terminals 6a to 6c to which the first insulating members 8b to 8d are attached). In the present embodiment, the plural first insulating members 8b to 8d are formed to have the same shape and the connecting grooves 82 are also formed on the first insulating members 8d which is located at the outermost position. In addition, in the present embodiment, the connecting piece 81 and the connecting groove 82 are formed in a substantially rectangular shape as viewed from the lamination direction.


Forming the plural first insulating members 8b to 8d into the same shape allows the number of components and the cost to be reduced and also allows the insulating member assembly 100 to be positioned with respect to the second terminal housing 7 by using the connecting grooves 82 formed on the outermost first insulating member 8d. In the present embodiment, the insulating member assembly 100 is positioned with respect to the second terminal housing 7 by inserting the positioning protrusions 30h provided inside the second terminal housing 7 (see FIGS. 9A, 9B and 11) into the connecting grooves 82 of the first insulating member 8d. Note that, although the positioning protrusions 30h are formed on the second inner housing 30 in the present embodiment, it is obviously possible to form the positioning protrusions 30h directly on the second terminal housing 7.


The insulating members 8a to 8d are connected to be relatively movable in the lamination direction by respectively receiving the connecting pieces 81 of the first insulating member 8b in the connecting grooves 82 of the second insulating member 8a, the connecting pieces 81 of the first insulating member 8c in the connecting grooves 82 of the first insulating member 8b and the connecting pieces 81 of the first insulating member 8d in the connecting grooves 82 of the first insulating member 8c, and the insulating member assembly 100 is thereby formed.


In addition, the insulating member assembly 100 is configured that, when the insulating members 8a to 8d are connected (laminated), the front edge (top edge) of the connecting piece 81 is stopped by the upper surface of the connecting groove 82 and each gap between the insulating members 8a to 8d is controlled so as not to be narrower than a predetermined gap (the minimum lamination gap).


The minimum lamination gap is adjusted to be slightly smaller than the total thickness (contact point thickness) of the first connecting terminal 4a, 4b or 4c and the second connecting terminal 6a, 6b or 6c which constitute a contact point. It is because a pressing force from the connecting member 9 is not transferred to the contact point if the minimum lamination gap is greater than the contact point thickness and if, on the other hand, the minimum lamination gap is too small, the positional misalignment of the insulating members 8a to 8d in the lamination direction become too large when the second connecting terminals 6a to 6c are deformed for some reasons and this causes defects such as deterioration in fitting properties. The minimum lamination gap can be adjusted by adjusting a difference in length in the lamination direction between the connecting piece 81 and the connecting groove 82 (for example, the minimum lamination gap is increased with increasing the length of the connecting piece 81 with respect to the length of the connecting groove 82).


As shown in FIG. 17A, the four connecting pieces 81 of the first insulating members 8b to 8d are formed in a substantially F-shape or a substantially mirror-reversed F-shape as viewed from the length direction of the second connecting terminals 6a to 6c, and a squared U-shaped fitting groove 83 opening inward is formed on each connecting piece 81. The first insulating members 8b to 8d are locked and fixed to the second connecting terminals 6a to 6c by inserting the second connecting terminals 6a to 6c into the fitting grooves 83. In other words, the connecting piece 81 has a function of connecting the insulating members 8a to 8d to each other as well as a function of locking the second connecting terminals 6a to 6c, and the fitting grooves 83 of the connecting pieces 81 serve as the second terminal insertion hole 103.


On the other hand, as shown in FIGS. 1B and 17B, the first connecting terminals 4a to 4c are inserted between the connecting pieces 81 which are formed at positions facing the opening of the second terminal housing 7 (on a side from which the first connecting terminals 4a to 4c are inserted) when the two terminal housings 5 and 7 are fitted to each other. In other words, the connecting pieces 81 formed at the positions facing the opening of the second terminal housing 7 also have a function of guiding and positioning the tip portions of the first connecting terminals 4a to 4c, and an opening sandwiched by the two connecting pieces 81 between the second connecting terminal 6a, 6b or 6c and the insulating member 8a, 8b or 8c serves as the first terminal insertion hole 102.


In the present embodiment, as shown in FIGS. 17A and 17B, a collision-prevention wall 84 is integrally formed on each of the plural first insulating members 8b to 8d. The collision-prevention wall 84 covers an end face of the second connecting terminal 6a, 6b or 6c on the side from which the first connecting terminals 4a to 4c are inserted, in order to prevent collision between the two connecting terminals 4a, 4b or 4c and 6a, 6b or 6c at the time of inserting the first connecting terminal 4a, 4b or 4c between the second connecting terminal 6a, 6b or 6c and the insulating member 8a, 8b or 8c. An edge of each collision-prevention wall 84 is chamfered (or rounded) to facilitate insertion of the first connecting terminals 4a to 4c. A portion of each of the insulating members 8a to 8c at a position facing the collision-prevention wall 84 (i.e., an edge of the each of the insulating members 8a to 8c on the opposite side to the connecting member 9 and on the side from which the first connecting terminals 4a to 4c are inserted) is also chamfered (or rounded) in the same manner. An edge of the connecting piece 81 on the first terminal insertion hole 102 side may be also chamfered or rounded to further facilitate insertion of the first connecting terminals 4a to 4c even though it is not performed in the present embodiment. The collision-prevention wall 84 is formed so that the upper surface thereof is flush with the upper surface of the second connecting terminal 6a, 6b or 6c.


Since the first insulating members 8b to 8d is attached to the second connecting terminals 6a to 6c, the first insulating members 8b to 8d are held by the second terminal housing 7 via the second connecting terminals 6a to 6c and the second inner housing 30 and are positioned with respect to the first terminal housing 5. In the state that the first insulating members 8b to 8d are positioned with respect to the first terminal housing 5, a gap is formed between the front edge of the connecting piece 81 and the upper surface of the connecting groove 82 and the first insulating members 8b to 8d are relatively movable to each other in the lamination direction. At this time, the insulating members 8a to 8d are housed in the space 30d surrounded by the main body 30a, the parallel portion 30b and the vertical portion 30c of the second inner housing 30 (see FIGS. 9A, 9B and 11).


The fitting groove 83 is formed so that a width thereof in the lamination direction (a width of the squared U-shaped opening) is slightly larger than the thickness of the second connecting terminals 6a to 6c. Thus, a gap (or clearance) is formed between the fitting groove 83 and the second connecting terminal 6a, 6b or 6c when the second connecting terminal 6a, 6b or 6c is fitted to the fitting groove 83. Accordingly, the first insulating members 8b to 8d are provided having looseness with respect to the second connecting terminals 6a to 6c. Since the first insulating members 8b to 8d are provided having looseness with respect to the second connecting terminals 6a to 6c, the first insulating members 8b to 8d can flexibly move even when the first insulating members 8b to 8d are slightly out of alignment. Therefore, deterioration in fitting properties such as hitting of the first connecting terminals 4a to 4c against the first insulating members 8b to 8d can be suppressed. In addition, forming the gaps (or clearances) between the fitting grooves 83 and the second connecting terminals 6a to 6c allows the second connecting terminals 6a to 6c to be easily fitted to the fitting grooves 83. Note that, a rim of the fitting groove 83 (and an edge of the first insulating members 8b to 8d on the side from which the second connecting terminals 6a to 6c are inserted) may be chamfered or rounded in order to easily fit the second connecting terminal 6a, 6b or 6c into the fitting grooves 83 even though it is not performed in the present embodiment.


In addition, a connecting wall 85 is integrally formed on each of the first insulating members 8b to 8d so as to connect between the two connecting pieces 81 located opposite to the side from which the second connecting terminals 6a to 6c are inserted. The connecting wall 85 is provided parallel to the insertion direction of the first connecting terminals 4a to 4c so as to cover a side of the fitting groove 83 opposite to the side from which the second connecting terminals 6a to 6c are inserted, which improves mechanical strength of the connecting pieces 81. In addition, the tip portions of the second connecting terminals 6a to 6c hit against the connecting walls 85. Therefore, the connecting wall 85 serves to position the second connecting terminals 6a to 6c and to suppress excessive insertion thereof. Furthermore, the connecting wall 85 extends downward so as to cover a side of the connecting groove 82 opposite to the side from which the second connecting terminals 6a to 6c are inserted. This increases a contact area when the connecting piece 81 is inserted into the connecting groove 82. Thus, the connecting wall 85 also has a function of further stabilizing the connection between the insulating members 8b to 8d to each other. Note that, the connecting wall 85 is formed at a height that does not hit the opposite insulating member 8a, 8b or 8c when each gap between the insulating members 8a to 8d is set to the minimum lamination gap.


Furthermore, as shown in FIG. 17B, the connecting wall 85 covers the lateral side of the first connecting terminal 4a, 4b or 4c and serves to increase a creepage distance between the contact points when the two terminal housings 5 and 7 are fitted and the first connecting terminals 4a to 4c are inserted. Such a configuration is effective especially when reducing the size of the insulating members 8b to 8d to downsize the entire connector 1. Note that, in the present embodiment, a connecting wall is not formed on a side of the insulating members 8b to 8d opposite to the side from which the first connecting terminals 4a to 4c are inserted since it is configured that the first connecting terminals 4a to 4c are inserted partway without covering the entire second connecting terminals 6a to 6c when the two terminal housings 5 and 7 are fitted and this increases the creepage distance between the contact points via the side of the insulating members 8b to 8d opposite to the side from which the first connecting terminals 4a to 4c are inserted, however, it is obviously possible to further form a connecting wall on the side of the insulating members 8b to 8d opposite to the side from which the first connecting terminals 4a to 4c are inserted.


Although the connecting pieces 81 are formed on the first insulating members 8b to 8d and the connecting grooves 82 are formed on the opposite insulating members 8a to 8c in the present embodiment, it is obviously possible to reverse the positions of the connecting pieces 81 and the connecting grooves 82 in the insulating member assembly 100 (to form the connecting pieces 81 on the insulating members 8a to 8c and the connecting grooves 82 on the opposite insulating members 8b to 8d). In this case, however, it is not possible to form the fitting groove 83 on the connecting piece 81 and a mechanism for providing the first connecting terminals 4a to 4c needs to be additionally provided on the first insulating members 8b to 8d, which makes the structure of the first insulating members 8b to 8d complicated.


Effects of the Present Embodiment


The effects of the present embodiment will be described.


The connector 1 in the present embodiment is provided with the fitted-state maintaining member 70 which slides along a direction perpendicular to the fitting direction of the two terminal housings 5 and 7, is then fitted to both of the first fitting portions 31 and the second fitting portions 41 after fitting the two terminal housings 5 and 7 to each other, and thereby holds the two terminal housings 5 and 7 as-fitted.


Use of the fitted-state maintaining member 70 allows the two terminal housings 5 and 7 to be easily fixed and released only by sliding without complicated work such as conventional fixation using bolts, which facilitates attaching and detaching work.


In addition, since the fitted-state maintaining member 70 is fitted by sliding in the present embodiment, a conventionally essential wide space for rotating a bolt by a tool is not required and it is possible to attach in a narrow space.


In other words, in the present embodiment, it is possible to realize the connector 1 which facilitates attaching and detaching work and can be attached in a narrow space.


Furthermore, by holding the two terminal housings 5 and 7 as-fitted using the fitted-state maintaining member 70, it is possible to suppress transmission of vibration of the cables 61a to 61c to the contact points and thus to suppress frictional wear of the connecting terminals 4a to 4c and 6a to 6c caused by vibration even in a condition where vibration is likely to occur, such as under the in-vehicle environment.


Especially in the laminated-type connector 1 in which plural contact points are held all together by being pressed by the connecting member 9, misalignment between the both connecting terminals 4a to 4c and 6a to 6c is likely to occur when a force to rotate around the pressing direction thereof is applied. In such a case, effects obtained by applying the invention are remarkable.


Furthermore, since the connector 1 has the tail plates 50 having a two-divided structure to sandwich and hold the cables 61a to 61c and the cables 61a to 61c are fixed to the second terminal housing 7 by fixing the tail plates 50 to the second terminal housing 7, it is possible to suppress transmission of vibration to the connecting terminals 4a to 4c and 6a to 6c when the cables 61a to 61c vibrate in the second terminal housing 7 and it is thus possible to reliably suppress frictional wear of the connecting terminals 4a to 4c and 6a to 6c.


In the connector 1, since the contact points are formed in the second terminal housing 7 and outside the device, frictional wear of the connecting terminals 4a to 4c and 6a to 6c due to vibration of the second terminal housing 7 is likely to occur. The invention exerts remarkable effects especially in such a case.


Furthermore, the connector 1 has a laminated structure in which plural contact points are held all together by being pressed by the connecting member 9. Therefore, remarkable effects are obtained especially when the invention is applied to such a laminated-type connector.


In addition, in the connector 1, since the fitted-state maintaining member 70 is configured to fit to the second fitting portions 41 on the inner side of the lateral portions 71 and to the first fitting portions 31 on the outer side of the lateral portions 71, it is possible to maintain the fitted state of the two terminal housings 5 and 7 even when the second terminal housing 7 is laterally stretched.


In addition, in the connector 1, since the fixing claw 33 for locking the rear portion of the fitted-state maintaining member 70 to fix the fitted-state maintaining member 70 is provided on the flange 25 of the first terminal housing 5 on the backward in the sliding direction of the fitted-state maintaining member 70, it is possible to firmly fix the fitted-state maintaining member 70 to the first terminal housing 5.


In addition, in the connector 1, since the fitted-state maintaining member 70 slides from the cables 61a to 61c side toward the two terminal housings 5 and 7 along the extending direction of the cables 61a to 61c and is then fitted to the both fitting portions 31 and 41, it is possible to easily fit the fitted-state maintaining member 70 and thereby to fix the two terminal housings 5 and 7 even in a very narrow space, e.g., no space in all direction other than the cable extending direction.


In addition, in the connector 1, the tool insertion hole 71c is formed on one of the lateral portions of the fitted-state maintaining member 70 so that the tool fitting hole 9c is exposed to allow the tool to rotate the connecting member 9 only when the fitted-state maintaining member 70 is perfectly fitted to the both fitting portions 31 and 41. This allows a worker to reliably fit the fitted-state maintaining member 70 at the time of fitting the two connector portions 2 and 3 and it is thus possible to suppress transmission of vibration of the cables 61a to 61c to the contact points and the resulting frictional wear of the connecting terminals 4a to 4c and 6a to 6c caused by unintentional falling of the fitted-state maintaining member 70 left in the imperfect fitted state or looseness of the fitted state of the two terminal housings 5 and 7.


It should be noted that the present invention is not intended to be limited to the embodiment, and the various changes can be made without departing from the gist of the present invention.


Although the first fitting portion 31 is constructed from the protrusion-holding portion 32 (or a protrusion) and the second fitting portion 41 from the protrusion 42 (or a groove) in the embodiment, a specific structure of the first fitting portion 31 and the second fitting portion 41 can be appropriately changed depending on the intended use or the required specification, etc. For example, as is a connector 181 shown in FIG. 18, it may be configured such that the protrusion-holding portion 32 as the first fitting portion 31 is composed of a vertical portion 32a protruding from the flange 25 toward the second terminal housing 7 and a horizontal portion 32b extending along the sliding direction from a tip portion of the vertical portion 32a toward the insertion side of the fitted-state maintaining member 70 so that the protrusion 75 is guided between the horizontal portion 32b and the flange 25, and furthermore, a surface of the horizontal portion 32b on the flange 5 side is formed in a tapered shape such that an opening is gradually enlarged toward the insertion side of the fitted-state maintaining member 70 (toward the cables 61a to 61c). By configuring as such, the protrusion 75 is gradually moved toward the first terminal housing 5 by the surface of the horizontal portion 32b on the flange 25 side when fitting the fitted-state maintaining member 70 and the fitted-state maintaining member 70 is naturally pressed against the first terminal housing 5 as sliding. Therefore, even when the two terminal housings 5 and 7 are not perfectly fitted and have looseness, the second terminal housing 7 is pulled toward the first terminal housing 5 by the fitted-state maintaining member 70 and this allows the two terminal housings 5 and 7 to be perfectly fitted to each other.


In addition, the embodiment assumes the use of a three-phase AC power line, however, according to the technical idea of the invention, it may be, e.g., a connector for a vehicle which is configured to collectively connect lines used for different purposes such as a three-phase AC power line between a motor and an inverter and a two-phase DC power line for air conditioner. Since the configuration described above allows one connector to collectively connect power lines used for different purposes, it is not necessary to prepare different connectors for each intended purpose and it is thus possible to contribute to space saving and cost reduction.


In addition, surfaces of the first connecting terminals 4a to 4c and of the second connecting terminals 6a to 6c may be each roughened by a knurling process to increase frictional force so as to make the terminals difficult to move, thereby strengthening the fixation at each contact point.


In addition, although the case where the first connector portion 2 is attached to the device has been described in the embodiment, it is possible to configure such that the first connecting terminals 4a to 4c are provided at end portions of cables to connect the cables to each other.


Furthermore, although the first connecting terminals 4a to 4c are inserted through the through-holes 10a of the first inner housing 10 and are fixed to the first inner housing 10 in the embodiment, the first inner housing 10 may be integrally formed with the first connecting terminals 4a to 4c by insert molding.


In addition, although the case where the first insulating members 8b to 8d are attached to the second connecting terminals 6a to 6c by fitting the second connecting terminals 6a to 6c to the fitting grooves 83 has been described in the embodiment, the first insulating members 8b to 8d may be fixed to the second connecting terminals 6a to 6c by insert molding or by press-fitting the second connecting terminals 6a to 6c into the first insulating members 8b to 8d. In this regard, however, the first insulating members 8b to 8d do not have looseness with respect to the second connecting terminals 6a to 6c in case of using insert molding or press-fitting and it is therefore desirable to fit the second connecting terminals 6a to 6c to the fitting grooves 83 in view of improving fitting properties.


In addition, although a cable excellent in flexibility is used as the cables 61a to 61c in the embodiment, a rigid cable may be used.


In addition, in the embodiment, a direction of the connecting member 9 may be either substantially horizontal or substantially vertical when the connector is in use. In other words, a direction in a usage state is not a requirement in the use conditions of the connector of the present embodiment.


In addition, although the bolt 9b of the connecting member 9 presses the second insulating member 8a adjacent thereto via the elastic member 15 which is a portion of the connecting member 9 in the embodiment, the adjacent second insulating member 8a may be pressed directly by the bolt 9b, not via the elastic member 15.


In addition, although the case of providing the connecting member 9 on only one side of the first terminal housing 5 has been described in the embodiment, the connecting member 9 may be provided on both sides of the first terminal housing 5 so that a pressing force is applied to each contact point by the two connecting members 9 provided on the both sides.


Although the case where one or both of the connecting piece 81 and the connecting groove 82 are formed at four corners of the insulating members 8a to 8d has been described in the embodiment, it is not limited thereto. The connecting piece 81 and the connecting groove 82 may be formed at two or three of the four corners of the insulating members 8a to 8d.


Although, the case where the invention is applied to the laminated-type connector 1 has been described in the embodiment, the invention is also applicable to connectors other than of the laminated-type and it is obviously applicable to, e.g., a connector provided with only a pair of a first connecting terminal and a second connecting terminal.


In addition, the connector 1 may be configured not to include the first connector portion 2. In this case, the wire harness of the invention is the cables 61a to 61c with the second connector portion 3 provided at an end portion thereof.

Claims
  • 1. A connector, comprising: a first terminal housing that houses a first connecting terminal; anda second terminal housing that houses at least a portion of a cable comprising a second connecting terminal at an end portion thereof,wherein the first connecting terminal and the second connecting terminal come into contact with each other and form a contact point when the first terminal housing is fitted to the second terminal housing,wherein the two terminal housings are fitted in a direction intersecting with an extending direction of the cable that extends from the second terminal housing,wherein the first terminal housing comprises a first fitting portion,wherein the second terminal housing comprises a second fitting portion, andwherein the connector further comprises a fitted-state maintaining member that is configured so as to be fitted to both the first and second fitting portions by being slid along a direction perpendicular to the fitting direction of the two terminal housings after the two terminal housings are fitted to each other such that the two terminal housings are held as-fitted.
  • 2. The connector according to claim 1, wherein the fitted-state maintaining member is formed so as to sandwich the two terminal housings at least from the both sides and comprises a groove or a protrusion formed along the sliding direction of the fitted-state maintaining member inside of both side portions thereof, and wherein the second fitting portion is formed linearly on both side surfaces of the second terminal housing along the sliding direction of the fitted-state maintaining member and comprises a protrusion or a groove to be slidably fitted to the groove or protrusion of the fitted-state maintaining member.
  • 3. The connector according to claim 2, wherein the first terminal housing further comprises a flange that protrudes from the second terminal housing in a direction perpendicular to the fitting direction of the two terminal housings when the two terminal housings are fitted to each other, wherein the fitted-state maintaining member comprises a protrusion or a protrusion-holding portion comprising a protrusion formed on each of two sides of the fitted-state maintaining member, andwherein the first fitting portion is formed on the flange and comprises a protrusion-holding portion or a protrusion corresponding to and engaging with the protrusion or the protrusion-holding portion of the fitted-state maintaining member.
  • 4. The connector according to claim 3, wherein the fitted-state maintaining member comprises the protrusion formed outside of the both side portions and the first fitting portion comprises the protrusion-holding portion, wherein the protrusion-holding portion of the first fitting portion comprises a vertical portion protruding from the flange toward the second terminal housing and a horizontal portion extending along the sliding direction from a tip portion of the vertical portion toward the fitted-state maintaining member insertion side such that the protrusion formed on the fitted-state maintaining member is guided between the horizontal portion and the flange, andwherein a surface of the horizontal portion facing the flange is tapered such that an opening between the horizontal portion and the flange is gradually enlarged toward the fitted-state maintaining member insertion side.
  • 5. The connector according to claim 3, wherein the fitted-state maintaining member comprises a rear portion on a back side in the sliding direction so as to integrally connect the both side portions, and wherein the flange comprises a fixing claw to lock the rear portion.
  • 6. The connector according to claim 1, wherein the fitted-state maintaining member is configured so as to be fitted to the both fitting portions by being slid from the cable side toward two terminal housings along the extending direction of the cable.
  • 7. The connector according to claim 1, wherein a plurality of ones of the first connecting terminal aligned are housed in the first terminal housing, wherein a plurality of ones of the second connecting terminal aligned and a plurality of insulating members aligned are housed in the second terminal housing,wherein a laminated structure is formed such that the first connecting terminals and the second connecting terminals are alternately arranged so that a surface of the first connecting terminals faces a surface of the second connecting terminals to form a pair and to form a plurality of contact points sandwiched between the insulating members when the first terminal housing is fitted to the second terminal housing, andwherein the connector further comprises a connecting member to collectively fix and electrically connect the first connecting terminals and the second connecting terminals at each contact point by pressing the insulating members adjacent thereto.
  • 8. The connector according to claim 7, wherein the connecting member comprises a tool fitting hole for fitting a tool such that the connecting member is rotated by the tool fitted to the tool fitting hole to press the insulating members adjacent thereto, wherein the fitted-state maintaining member is configured to cover the connecting member with one of the both side portions when the fitted-state maintaining member is fitted to the first and second fitting portions, andwherein the one of the both side portions comprises a tool insertion holes configured to expose the tool fitting hole when the fitted-state maintaining member is completely fitted to the first and second fitting portions, and to allow the tool to rotate the connecting member.
  • 9. The connector according to claim 1, wherein the connector further comprises a tail plate having a two-divided structure to sandwich and hold the cable, and wherein the cable is fixed to the second terminal housing by fixing the tail plate to the second terminal housing.
  • 10. A wire harness, comprising: a cable;a second connecting terminal at an end portion of the cable; anda second terminal housing that houses at least the end portion of the cable including the second connecting terminal,wherein a first connecting terminal and the second connecting terminal come into contact with each other and form a contact point when the second terminal housing is fitted to a first terminal housing that is configured to be fitted to the second terminal housing, to house the first connecting terminal and to be attached to a device as an attached object,wherein the two terminal housings are fitted in a direction intersecting with an extending direction of the cable that extends from the second terminal housing,wherein the first terminal housing comprises a first fitting portion,wherein the second terminal housing comprises a second fitting portion, andwherein the wire harness further comprises a fitted-state maintaining member that is configured so as to be fitted to both the first and second fitting portions by being slid along a direction perpendicular to the fitting direction of the two terminal housings after the two terminal housings are fitted to each other such that the two terminal housings are held as-fitted.
Priority Claims (1)
Number Date Country Kind
2013-091499 Apr 2013 JP national
US Referenced Citations (4)
Number Name Date Kind
7892038 Kataoka et al. Feb 2011 B1
9093765 Kuji et al. Jul 2015 B2
20140322965 Kuji et al. Oct 2014 A1
20150147918 Matsuda et al. May 2015 A1
Foreign Referenced Citations (3)
Number Date Country
2010-211935 Sep 2010 JP
4905608 Mar 2012 JP
2012-134131 Jul 2012 JP
Related Publications (1)
Number Date Country
20140318860 A1 Oct 2014 US