The present invention relates to a connector including a male terminal and a female terminal that are fitted and connected to each other.
Conventionally, to connect electronic devices installed inside an automobile or the like, a connector is used that causes a male terminal and a female terminal to be fitted to each other to connect the devices via wires or the like. In the connector including the male terminal and the female terminal, the male terminal and the female terminal can be fitted to each other and electrical connection is enabled by bringing lead wires or electrodes in the terminals into contact with each other.
Meanwhile, in the connector described above, it is necessary to maintain the fitted state of the male terminal and the female terminal in order to continue the electrical connection between the electronic devices. In particular, for use as a connector to be mounted on a product, such as an automobile, that is likely to vibrate, there is a demand for a connector that can maintain the fitted state to prevent the male terminal and the female terminal from being disconnected due to the vibration.
As a connector that meets the demand, for example, there is a known connector that locks the male terminal and the female terminal by engaging a locking arm, a locking projection, and a locking surface while an elastic force is applied by an elastic body (see, for example, Patent Literature 1). Furthermore, there is a known connector that locks the male terminal and the female terminal by locking an engagement protrusion of a locking arm, to which an elastic force is applied by a repulsion spring, and an arm locking portion (see, for example, Patent Literature 2).
Patent Literature 1: Japanese Patent Application Laid-open No. 8-031513
Patent Literature 2: Japanese Patent Application Laid-open No. 2001-160459
However, in the conventional connectors disclosed in Patent Literatures 1 and 2, the fitted state of the male terminal and the female terminal may be released due to the action of the elastic body or due to the elastic force of the arm depending on a force applied in a direction in which the fitted state of the terminals is released.
The present invention has been made in view of the above, and an object thereof is to provide a connector capable of maintaining the fitted state of a male terminal and a female terminal with a simple structure.
To solve the problem described above and achieve the object, a connector according to the present invention is interposed between two connection objects to enable electrical continuity between the connection objects, the connector including: a male terminal which has a conductive property and a tip of which is formed in a bar shape; and a female terminal formed of a conductive wire rod that is wound with an inner diameter smaller than a diameter of the male terminal, the wire rod linearly extending at an end portion of the female terminal at which the male terminal is to be inserted, wherein the male terminal is inserted into the female terminal while a force that expands an inner diameter of at least a vicinity of the end portion is applied to the linearly extending portion, and thereafter fitted to the female terminal by releasing the force.
In the connector according to the present invention as set forth in the invention described above, at least a vicinity of another end portion of the female terminal is tightly wound.
In the connector according to the present invention as set forth in the invention described above, a male terminal bracket that holds the male terminal; and a female terminal bracket that holds the female terminal and that is connectable to the male terminal bracket are further provided, wherein the male terminal bracket includes a diameter expanding unit that expands a diameter of at least the linearly extending portion of the female terminal along with insertion of the male terminal into the female terminal.
In the connector according to the present invention as set forth in the invention described above, an end portion of the female terminal, the end portion being different from the linearly extending portion, is fixed to the female terminal bracket.
In the connector according to the present invention as set forth in the invention described above, the female terminal bracket includes a diameter changing unit that holds the linearly extending portion of the female terminal and moves the linearly extending portion on a plane orthogonal to a longitudinal direction of the female terminal to thereby expand the diameter of the female terminal.
In the connector according to the present invention as set forth in the invention described above, the male terminal bracket includes a guide pin that extends parallel to the male terminal and that protrudes from a tip of the male terminal in an extending direction, and the female terminal bracket includes a hole in which the guide pin is insertable.
The connector according to the present invention expands the diameter of the coil spring whose diameter in the natural state is smaller than the diameter of the male terminal, inserts the male terminal into the coil spring with the expanded diameter, and returns the coil spring to the natural state to tighten and lock the male terminal. Therefore, it is possible to maintain the fitted state of the male terminal and the female terminal with a simple structure.
Exemplary embodiments of the present invention will be explained in detail below with reference to the drawings. The present invention is not limited by the embodiments below. Each drawing referred to in the following explanation only schematically illustrates the shape, the size, and the positional relationship to be able to understand the content of the present invention, and therefore, the present invention is not limited to only the shape, the size, and the positional relationship illustrated in each drawing.
The connector 1 includes a male terminal 11 that is connected to a lead 12 to be connected to a connection object and that has a conductive property, and a coil spring 21 serving as a female terminal that is connected to a lead 22 to be connected to a connection object via a lead terminal 22a and that has a conductive property.
The male terminal 11 is made of a conductive material, and includes a tip portion 11a which is formed in a bar shape with an approximately spherical tip, a lead terminal 11b which holds the lead 12, and a flange portion 11c which has a diameter greater than the diameter of the tip portion 11a.
A wire rod of the coil spring 21 has a circular cross-section, and the coil spring is wound such that the inner diameter thereof becomes smaller than the diameter of the tip portion 11a of the male terminal 11. Both end portions of the coil spring 21 are tightly wound. At an end of the coil spring 21 on the side opposite the lead terminal 22a, a linear extending portion 21a is provided that extends in a direction orthogonal to the extending direction of the coil spring 21. At an end of the coil spring 21 on the lead terminal 22a side, a fixation portion 21b is provided that extends in a direction orthogonal to the extending direction of the coil spring 21. The extending portion 21a may be formed in an arc shape with a diameter greater than the diameter of the coil spring 21.
The coil spring 21 is formed with a wire rod which is formed of a core made of SUS or beryllium copper and outer coating made of a low-resistance copper-based metal. A clad metal material or an alloy material having appropriate elasticity or thermal resistance is also applicable.
In this case, because the inner diameter of the coil spring 21 is smaller than the diameter of the male terminal 11, the tip portion 11a of the male terminal 11 is tightened by a winding force of the spring, and therefore, the fitted state is maintained. Besides, the coil spring 21 is joined to a support 23, which projects from the end of the lead terminal 22a on the side opposite the lead 22, with the winding force of the spring and/or a solder C. To ensure the winding force of the coil spring 21 against the male terminal 11, it is preferable that the diameter of the support 23 is equal to or smaller than the diameter of the tip portion 11a.
With the application of the force F, the extending portion 21a moves to the position illustrated in
With the operation of the coil spring 21 illustrated in
With the connector according to the first embodiment described above, it becomes possible to maintain the fitted state of the male terminal 11 and the coil spring 21 with a simple structure. Therefore, it becomes possible to stably maintain the fitted state of the male terminal and the female terminal (the coil spring) and realize electrical continuity. Besides, when a force in a direction in which the male terminal 11 and the coil spring 21 are separated from each other is applied to the connector 1 in the fitted state, the coil spring 21 is elastically deformed in the extending direction. With this extension, the coil spring 21 is elastically deformed in a direction in which the inner diameter thereof is reduced, so that a greater winding force is applied to the male terminal 11. Therefore, it becomes possible to more reliably prevent the male terminal 11 from coming off from the coil spring 21.
While it is explained that the both terminals in the above connector are connected to the leads, it may be possible to employ a structure in which one of the terminals is connected to the lead and the other is directly connected to a substrate.
In the coil spring 21, as long as the winding force against the lead terminal 22a and the support 23 is ensured or as long as the connection between the coil spring 21 at the support 23 (or the lead terminal 22a) and the support 23 (or the lead terminal 22a) with the solder C is ensured, the fixation portion 21b may be removed. Besides, it is sufficient that at least the lead terminal 22a side of the coil spring 21 is tightly wound. It may be possible to tightly wind the whole coil spring 21.
It is preferable that the lead terminal 22b according to the first modification is formed such that the inner diameter of at least a part of a portion formed by the abovementioned claws is approximately the same or slightly smaller than the outer diameter of the coil spring 21. With the lead terminal 22b, because the lead terminal 22b is press fitted and connected to the coil spring 21, it becomes possible to reliably connect the coil spring 21 to enable electrical continuity. Furthermore, it becomes possible to connect the lead terminal 22b and the coil spring 21 regardless of the diameter of the coil spring 21.
A second embodiment of the present invention will be explained below with reference to
The connector illustrated in
The male terminal bracket 3 includes diameter expanding cams 31 as a diameter expanding means disposed on the upper portions of the male terminals 11, guide pins 32 formed in an approximately columnar shape and extending parallel to the male terminals 11 from the both ends of the male terminals 11, and lock bars 33 disposed on the upper portions of the guide pins 32, extending parallel to the guide pins 32, and having projections projecting from the tip portions thereof in a vertically downward direction with respect to the extending direction.
The diameter expanding cams 31 come into contact with the side surfaces of the extending portions 21a at corresponding surfaces thereof, to thereby move the extending portions 21a and expand the inner diameters of the coil springs 21. The diameter expanding cams 31 have notch portions (notch surfaces) that allow the extending portions 21a to move back to the original positions (the natural state) when the wall surface of the male terminal bracket 3 and the wall surface of the female terminal bracket 4 come in contact with each other. As for the notch portion, the diameter expanding cams 31 are disposed such that an interval between each of the notch surfaces and the wall surface of the female terminal bracket 4 becomes at least equal to or greater than the diameter of the wire rod of the coil spring 21.
The female terminal bracket 4 includes housings 41 that house the coil springs 21 and that can house even the coil springs 21 with the expanded diameters, guide holes 42 in which the guide pins 32 are inserted and maintained, and lock holes 43 as recesses to be engaged with the projections of the lock bars 33. The leads 22 are housed at predetermined positions in the female terminal bracket 4 while being in contact with the lead terminals described above, and thereafter, fixed to the female terminal bracket 4 by screwing, bonding, or fitting with use of a fixing member (not illustrated) on the end portion of the female terminal bracket 4.
As illustrated in
At the same time the male terminals 11 and the coil springs 21 are fitted to each other and the male terminal bracket 3 and the female terminal bracket 4 come into contact with each other, the projections of the lock bars 33 are engaged with the recesses of the lock holes 43.
As for the extending portions 21a of the coil springs 21, as illustrated in
After the extending portion 21a comes into contact with the curved portion 31a, the diameter expanding cam 31 further moves in the direction of arrow Y along with the movement of the male terminal bracket 3 or the female terminal bracket 4 (
When the diameter expanding cam 31 further moves in the direction of arrow Y, the extending portion 21a comes into contact with a linear portion 31b (
Thereafter, when the male terminal bracket 3 and the female terminal bracket 4 come into contact with and fitted to each other, the extending portion 21a moves along the notch surface in a direction orthogonal to the moving direction of the diameter expanding cam 31 and is held by a groove 31c (
In the connector according to the second embodiment described above, the diameter expanding cam 31 expands the inner diameter of the coil spring 21 along with insertion of the male terminal 11 into the coil spring 21. Therefore, it becomes possible to expand the inner diameter of the coil spring 21 by the extending portion 21a and insert the male terminal 11 into the coil spring 21 without manually operating the extending portion 21a. Furthermore, it is advantageous in that the guide pin 32 functions to determine the position of the male terminal 11 to be inserted into the coil spring 21, and it is possible to prevent deviation of the insertion position of the male terminal due to the force applied by the diameter expanding cam 31 to the extending portion 21a.
As illustrated in
The diameter expanding cams 31 are inserted into the inner space of the knob 44 when the male terminal bracket 3 and the female terminal bracket 4 approach each other, and move the extending portions 21a by the operations illustrated in
When the male terminal bracket 3 and the female terminal bracket 4 are released from the fitted state, the knob 44 is caused to slide in the circumferential direction of the coil springs 21, so that the extending portions 21a that have been in contact with the diameter expanding cams 31 can easily be detached. If a protrusion 44a is provided, it becomes possible to more easily slide the knob 44.
In the second embodiment described above, it is explained that the two connectors each including the male terminal and the female terminal are provided. However, the number of the connectors may be one or three or more according to the leads (wiring) to be used.
As described above, the connector according to the present invention is useful for connecting electronic members to establish electrical continuity. Reference Signs List
1, 1a, 1b CONNECTOR
3 MALE TERMINAL BRACKET
4 FEMALE TERMINAL BRACKET
11 MALE TERMINAL
11
a TIP PORTION
11
b, 22a, 22b LEAD TERMINAL
12, 22 LEAD
21, 24, 25 COIL SPRING
21
a EXTENDING PORTION
21
b FIXATION PORTION
23 SUPPORT
31 DIAMETER EXPANDING CAM
32 GUIDE PIN
33 LOCK BAR
41 HOUSING
41
a HOLDING PORTION
42 GUIDE HOLE
43 LOCK HOLE
44 KNOB
Number | Date | Country | Kind |
---|---|---|---|
2010-068699 | Mar 2010 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/JP2011/057036 | 3/23/2011 | WO | 00 | 9/19/2012 |