The present invention relates to an electric connector, and specifically relates to an electric connector to which a shield-equipped multicore cable is connected.
For example, an electric connector for a shield-equipped multicore cable is used for electrically connecting signal lines to each other through a cable in various electronic devices such as a DVD device, an AV amplifier, a digital high-definition television, and a personal computer. Examples of the technique of the electric connector for the shield-equipped multicore cable include a technique described in Patent Literature 1 (JP-A-2011-60425). An electric connector described in Patent Literature 1 is a shield connector attached to a terminal of a multicore shield cable. In the multicore shield cable, multiple electric wires are covered with a braid, and the braid is covered with a sheath.
As a result of study conducted by the inventor(s) of the present invention, the following findings regarding the above-described electric connector technique have been obtained.
For example, even in the case of the same electric connector, the number of core wires of the multicore cable is not always the same. All pins are used in some cases, and only some of these pins are used in other cases. In these cases, a cable outer diameter size also changes according to a change in the number of core wires. Moreover, the thickness of the cable itself might change according to a cable to be used. Thus, an electric connector which can be reliably connected even if the number of core wires of a cable or the thickness of a cable is changed is necessary.
There is also a case where the process of connecting an electric connector and a cable to each other is performed on site. In this case, an electric connector accepting cables with various thicknesses is necessary. Moreover, it is also necessary to improve quality, reliability, and working efficiency in connection. That is, it is necessary to reliably fix the cable to the electric connector even if the entire thickness of the cable is changed and to avoid easy detachment of the cable even if tensile stress is applied to the cable. Further, an electric connector configured so that the connection process can be easily performed on site is necessary.
In the case of a shield-equipped multicore cable, the outer diameter of an external conductor (a braid) changes in association with a change in the number of core wires of a cable. Thus, an electric connector which can be reliably shield-connected even if the outer diameter of the external conductor is changed is necessary.
The present invention has been made for solving the above-described problems. One object of the present invention is to provide the technique of reliably easily making connection even in a case where the thickness of a cable is changed in an electric connector for a shield-equipped multicore cable.
The above-described object, other objects, and new features of the present invention will be apparent from description of the present specification and the attached drawings.
A brief summary of representative aspects of the invention disclosed in the present application is as follows.
That is, an electric connector according to the present invention is an electric connector to which a cable is connected, including: a housing configured to hold multiple terminals; a conductive shell provided outside the housing to cover at least part of the housing; an insulating first cover provided outside the shell to cover at least part of the shell; and a turnable insulating second cover coupled to the first cover through a rotary shaft, in which the first cover has a first locking piece on a cable side, the second cover has a second locking piece to be engaged with the first locking piece, at least one of the first locking piece or the second locking piece includes multiple locking pieces arranged along a circumferential direction of a circle about the rotary shaft, the first locking piece and the second locking piece have such a structure that the first locking piece and the second locking piece are movable in an approaching direction and movement in a separation direction is restricted in a state in which the first locking piece and the second locking piece are engaged with each other, the shell has, on the cable side, a first contact piece and a second contact piece for sandwiching an external conductor of the cable from both sides to contact the external conductor, and the second contact piece is positioned on a second cover side, and is deformable in a center axis direction of the cable to contact an inner wall surface of the second cover.
Further, each of the first locking piece and the second locking piece is configured such that a tip end portion thereof has a sawtooth shape facing an outside.
Moreover, a coupling portion is provided between the first locking piece and the first cover, and each of the first locking piece and the second locking piece is configured such that a tip end portion thereof has a sawtooth shape facing an outside in an X-Z plane.
Further, the second contact piece is configured such that a portion extending from the shell and positioned in a vicinity of the rotary shaft has a dented shape.
Moreover, each of the first contact piece and the second contact piece has a contact surface along a tangent line of an outer circumferential circle of the external conductor, and the contact surface is formed in such a manner that an end portion of the first contact piece or the second contact piece is bent.
Still further, on the cable side, each of the first cover and the second cover has, on an inner wall surface thereof, a protrusion for biting an external insulator of the cable to fix the cable.
A brief summary of advantageous effects obtained by the representative aspects of the invention disclosed in the present application is as follows.
(1) Even if the thickness of the cable is changed according to the number of core wires, connection is reliably easily made by the same electric connector.
(2) The electric connector accepting various cables with different cable thicknesses can be provided.
(3) the process of connecting the electric connector and the cable to each other on site is reliably easily performed.
Hereinafter, an embodiment of the present invention will be described in detail based on the attached drawings. Note that in all figures for describing the embodiment, the same reference numerals are used to represent the same members in principle, and repeated description thereof will be omitted.
For the sake of convenience, in the embodiment described below, multiple divided sections or embodiments will be described as needed. Unless otherwise clearly specified, these sections or embodiments are not unrelated to each other. There is a relationship in which one of the section or the embodiment is a variation, detailed description, supplemental description or the like of part or the entirety of the other one of the section or the embodiment. In a case where the number of elements or the like (including a number, a numerical value, an amount, a range or the like) are described in the embodiment described below, the number of elements is not limited to a particular number, unless otherwise clearly specified or clearly limited to the particular number in principle. The number of elements may be equal to or greater than or equal to or less than the particular number.
First, one example of the configuration of the electric connector according to one embodiment of the present invention will be described with reference to
As illustrated in
The multiple terminals 10 are each electrically connected to terminals of a partner connector (not shown) in contact with these terminals upon fitting to the partner connector. The multiple terminals 10 are made of conductive metal.
The housing 20 is formed of an insulating member such as resin. The housing 20 includes grooves and holes to which the multiple terminals 10 are fixed. Moreover, the housing 20 includes a fitting recessed portion 21 to be fitted to the partner connector.
The shell 30 covers the outside of the housing 20, and as clearly illustrated in
The lower contact piece 33 is provided on a cover 40 side (the Z2 direction), and is positioned between the cover 40 and the braid 3. The lower contact piece 33 is formed integrally with the shell 30. The lower contact piece 33 has such a shape that the lower contact piece 33 extends from the shell 30 to the cable side (the X1 direction), is separated toward both sides in a transverse direction (the Y1Y2 direction), and is bent (in a heart shape) with a curvature toward the upper side (a Z1 direction). Two right and left slits 84 are provided at such a bent portion, and accordingly, the elasticity of the lower contact piece 33 is adjusted. As clearly illustrated in
The upper contact piece 34 is provided on a movable cover 60 side (the Z1 direction), and is positioned between the movable cover 60 and the braid 3. The upper contact piece 34 is formed integrally with the shell 30. The upper contact piece 34 has such a shape that the upper contact piece 34 extends from the shell 30 to the cable side, has a dented middle portion 85 in the vicinity of the rotary shaft 63, further extends and branches into two portions bent in the center axis direction (the Z2 direction) of the cable at a bent surface 83, and is further bent in a shell-30-side direction (the X2 direction). A slit 82 is provided further ahead of the bent portion (the bent surface 83). The elasticity of the upper contact piece 34 can be adjusted in such a manner that the dimensions of the slit 82 are changed. Moreover, the upper contact piece 34 has, at a tip end portion thereof, two right and left contact surfaces 37 along the tangent line of the outer circumferential circle of the braid 3. The contact surface 37 is formed in such a manner that an end portion of the upper contact piece 34 is bent. The contact surface 37 is provided along a circumferential direction of the cable 2. With the contact surfaces 37, the area of contact with the surface of the braid 3 is increased, and biting of the surface of the braid 3 with the upper contact piece 34 is prevented. Thus, electric connection is reliably made, and damage of the braid 3 is prevented. Moreover, two cutout portions 81 are provided on both sides of a joint portion between the body shell 32 and the upper contact piece 34, and by changing the lengths of these cutout portions 81, the elasticity of the upper contact piece 34 can be adjusted.
The contact surfaces 36 of the lower contact piece 33 and the contact surfaces 37 of the upper contact piece 34 are formed along the fitting direction (the X1X2 direction), and are arranged facing each other in the upper-lower direction (a Z1Z2 direction). As illustrated in
The elastic operation pieces 35 are two elastic pieces extending from both side surfaces of the body shell 32 in the fitting direction (the X2 direction). The elastic operation pieces 35 are used for locking and unlocking upon fitting to the partner connector. Two lock protruding portions 38 elastically protruding to both sides are provided at tip end portions of the elastic operation pieces 35 on the fitting side (the X2 direction). With this configuration, a structure is formed, in which the lock protruding portions 38 protrude from lock holes 39 formed at both side surfaces of the fitting portion 31 of the shell 30. Upon fitting to the partner connector, the lock protruding portions 38 are hooked on and locked in lock holes (not shown) of the partner connector. For unlocking for cancelling fitting to the partner connector, the operation unit 70 is pushed in from both sides. Two elastic operation pieces 35 deform inwardly accordingly, and two lock protruding portions 38 are drawn into the lock holes 39. In this manner, hooking on the lock holes of the partner connector is cancelled, and unlocking is performed.
As clearly illustrated in
The movable cover 60 includes the rotary shaft 63 formed integrally with the movable cover 60 (see
As clearly illustrated in
The movable cover 60 has, on each side thereof, three locking pieces 61 (second locking pieces) to be engaged with the locking pieces 41. 3×2 locking pieces 61 are configured such that tip end portions thereof have a sawtooth shape facing the outside (the Z1 direction). 3×2 locking pieces 61 are preferably arranged along a circumferential direction of a circle about the rotary shaft 63. The locking pieces 41 and the locking pieces 61 form a ratchet mechanism. The locking pieces 41 and the locking pieces 61 have such a structure that the locking pieces 41 and the locking pieces 61 are movable in an approaching direction and movement in a separation direction is restricted in a state in which the locking pieces 41 and the locking pieces 61 are engaged with each other.
A coupling portion 43 coupling the locking piece 41 and the cover 40 has elasticity. The coupling portions 43 elastically deforms to the fitting side (an X2 side) in an X-Z plane when the locking piece 41 and the locking piece 61 are engaged with each other. Thus, the ratchet mechanism can be made. Moreover, by adjusting the thickness of the coupling portion 43, easiness of displacement of the locking piece 41 can be also adjusted. If the coupling portion 43 is too thick, the coupling portion 43 is less likely to warp, and it is difficult to engage the locking piece 41 with the locking piece 61. Conversely, if the coupling portion 43 is too thin, the coupling portion 43 easily warps, and engagement with the locking piece 61 is facilitated. Note that the locking piece 41 and the locking piece 61 engaged with each other are more likely to be separated from each other.
Note that in the present embodiment, the configuration having one locking piece 41 and three locking pieces 61 on each side is described so that adjustment can be made in three steps. However, the present invention is not limited to such a configuration, and the configuration may have one locking piece 41 and multiple (two or more) locking pieces 61, may have multiple (two or more) locking pieces 41 and one locking piece 61, or may have multiple (two or more) locking pieces 41 and multiple (two or more) locking pieces 61.
Next, the method for connecting the electric connector of the present embodiment in the case of different cable thicknesses will be described with reference to
As illustrated in
As illustrated in
As illustrated in
As described above, by rotary movement of the movable cover 60 upon connection of the cable, the cable can be reliably fixed according to the thickness of the cable (three steps in the present embodiment). That is, as illustrated in
Thus, according to the electric connector of the present embodiment, even if the thickness of the cable changes according to the number of core wires, connection is reliably easily made by the same electric connector. Moreover, according to the electric connector of the present embodiment, an electric connector accepting various cables with different cable thicknesses can be provided. Further, according to the electric connector of the present embodiment, on-site cable connection is easily made for cables with various thicknesses.
The invention made by the inventor(s) of the present invention has been specifically described above based on the embodiment thereof. Note that the present invention is not limited to the above-described embodiment, and needless to say, various changes can be made without departing from the gist of the present invention.
The present invention can be utilized for various electric connectors for coupling industrial devices to each other, such as a communication cable.
Number | Date | Country | Kind |
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2018-152298 | Aug 2018 | JP | national |
Filing Document | Filing Date | Country | Kind |
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PCT/JP2019/027752 | 7/12/2019 | WO | 00 |