JP2020009650A - Terminal connection mechanism - Google Patents

Abstract

To provide a terminal connection mechanism having an excellent reliability and safety performance, and having a high operability.SOLUTION: A terminal connection mechanism has a column plug, and a cylindrical socket attached to the plug, becomes a lock state by pressing the socket into the plug, and cancels the lock by further pressing it therein. The terminal connection mechanism comprises: a frame part that exposes the plug, and forms a penetration hole having an edge of which a distance from the plug is uneven; and a socket housing holding the socket in a state of projecting a plug attachment part. On a socket projection side of the socket housing, formed is a projection part of which contact state and non-contact state with the frame part can be switched at a rotational angle to a shaft of the plug at a pressing position in the lock state.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a terminal connection mechanism for connecting a cable to an electronic device such as a current measuring device.

  As a terminal connection mechanism for connecting a cable to an electronic device such as a current measuring device, a binding post system as shown in FIG. 9 is widely used. The binding post terminal 510 includes a metal support 511 and a cap 512 that protrude horizontally from a side surface 500 (for example, a terminal block provided on the back surface) of the electronic device. The cap 512 has a screw portion, and a screw hole is formed in the support 511. The cable is fixed to the terminal by screwing the cap 512 with the cable conductor connected to the support 511.

JP 2014-160596 A

  The binding post method is excellent in reliability and safety because the cable and terminal are firmly connected by tightening the screw, but the screw must be tightened or loosened when connecting or disconnecting, Sex is not enough.

  On the other hand, if a simple push-pull terminal connection mechanism using plugs and sockets is used, connection and disconnection can be performed by plugging and unplugging sockets, so operability is excellent, but reliability and safety are not sufficient. .

  Therefore, an object of the present invention is to provide a terminal connection mechanism which is excellent in reliability and safety and has high operability.

In order to solve the above problems, a terminal connection mechanism of the present invention has a cylindrical plug and a cylindrical socket attached to the plug, and is locked by pushing the socket into the plug, A terminal connection mechanism which is further unlocked by being pushed in, wherein the frame is formed with a through hole having an edge which exposes the plug and has an uneven distance from the plug; and A socket housing that holds the socket in a protruding state, and a contact state with the frame portion by a rotation angle with respect to a shaft of the plug at a pushing position where the locking state is provided on the socket protruding side of the socket housing. It is characterized in that a protruding portion whose contact state can be switched is formed.
The through hole may have an edge in which at least two cutouts are formed in a part of the circumference, and the socket housing may be formed with at least two protrusions.
The frame may include a moving frame that slides to hide the plug.
The frame and the socket housing may be provided with a mark as a measure of the rotation angle at which the frame and the projection form a contact body at the pressed position where the lock state is established.
The frame and the socket housing may be provided with a mark as a measure of a rotation angle at which the frame and the projection form a non-contact body at the pushed-in position where the lock state is established.

  ADVANTAGE OF THE INVENTION According to this invention, the terminal connection mechanism excellent in reliability and safety and high operability is provided.

FIG. 3 is a diagram illustrating a plug and a socket that constitute the terminal connection mechanism of the embodiment. It is a perspective view of a terminal connection mechanism including a plug and a socket. FIG. 2 is a diagram illustrating a push-pull method according to the embodiment. It is a figure explaining a lock operation. It is a figure explaining an unlock operation. It is a figure when a socket is removed from a plug. It is a figure explaining the frame part to which the whole was fixed. It is a figure showing the modification of this embodiment. It is a figure explaining the terminal connection mechanism of the conventional binding post system.

  An embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a diagram illustrating a plug 110 and a socket 120 that constitute a terminal connection mechanism 100 according to the present embodiment.

The plug 110 is formed in a cylindrical shape, and is fixed to a side surface or the like of the electronic device. The socket 120 is formed in a cylindrical shape, and is attached to the plug 110. In the example of the figure, two plugs 110 are arranged in the vertical direction (plug 110a, plug 110b).
The socket 120 is held by the socket housing 124 with the plug mounting portion protruding, and is connected to a cable (not shown) inside the socket housing 124. By attaching the socket 120 to the plug 110, the cable and the electronic device can be electrically connected.

  Around the plug 110, a frame portion 130 having a through hole 132 for exposing the plug 110 to the outside is arranged. In the present embodiment, the frame portion 130 includes a movable frame portion 130a slidable in the direction in which the plugs 110 are arranged and a fixed frame portion 130b fixed to the plug 110.

  The movable frame portion 130a can switch the exposure state of the plug 110 by sliding up and down, and functions as a shutter. When the socket 120 is not attached, the moving frame portion 130a is slid downward by its own weight, hiding the plug 110 (this drawing shows a state where the plug 110 is slid upward).

  The through hole 132a for exposing the plug 110a is a rectangular hole formed in the moving frame portion 130a, and the through hole 132b for exposing the plug 110b is formed between the lower end of the moving frame portion 130a and the upper end of the fixed frame portion 130b. It is formed in a rectangular shape between them.

  In any of the through holes 132, the distance between the edge of the plug 110 and the plug in the exposed state of the plug 110 is not uniform. That is, it has an edge that is relatively close to the plug 110 and an edge that is relatively far from the plug 110. In this embodiment, since each of the through holes 132 has a rectangular shape, the edge of the plug 110 located at an obliquely located corner is furthest from the plug 110.

  A protrusion 125 is formed on the socket housing 124 on the side of the socket 120 protruding. In the present embodiment, two projections (125a, 125b) are formed at positions sandwiching the socket 120. The direction in which the two protruding portions 125 are arranged is referred to as the up-down direction for convenience, and the cable is drawn downward in the opposite side to the protruding side of the socket 120. When the operator inserts and removes the socket 120 with a natural feeling, the socket 120 is operated in this direction (vertical direction).

  FIG. 2 is a perspective view of the terminal connection mechanism 100 including the plug 110 and the socket 120, and shows a state where the moving frame 130a functioning as a shutter is slid upward and the plug 110 is attached to the socket 120. .

  A method of attaching and detaching the socket 120 and the plug 110 is a push-pull method, which employs a known system in which the lock is automatically locked when the socket 120 is pushed into the plug 110, and the lock is released by further pushing. I have.

  Such a system can be realized, for example, by a configuration as shown in FIG. In this figure, the frame 130 and the projection 125 are omitted.

  As shown in this figure, a constricted portion having a predetermined width is formed on the base side of the plug 110, and an annular plug-side lock ring 111 having a width smaller than this width is fitted. The outer diameter of the plug-side lock ring 111 is designed to substantially match the outer diameter of the plug 110 other than the constricted portion. On the other hand, a narrow circumferential groove is formed in the socket 120 near the inner entrance, and the socket-side lock ring 123 is fitted therein.

  When the socket 120 is pushed into the plug 110, as shown in FIG. 3B, the socket 120 is pushed by the socket-side lock ring 123, so that the plug-side lock ring 111 moves to the base of the constricted portion. The socket-side lock ring 123 fits into the groove on the distal end side of the constricted portion generated by this, so that the socket 120 is locked by the plug 110 and cannot be pulled out. At this time, the socket 120 is rotatable about the axis of the plug 110.

  To release the lock, the socket 120 is pushed further. Thereby, the socket side lock ring 123 rides on the plug side lock ring 111 as shown in FIG.

  When the socket 120 is pulled in this state, as shown in FIG. 3D, the plug-side lock ring 111 moves together with the socket-side lock ring 123 to the distal end side of the constricted portion. This eliminates a step that hinders the movement of the socket-side lock ring 123, so that the socket 120 can be pulled out of the plug 110.

  By the way, when such a push-pull method is adopted, locking and unlocking are performed by the operation of pushing the socket 120 into the plug 110. For this reason, when the socket 120 is pushed in with a strong force at the time of mounting, the socket 120 is pushed at once to the position shown in FIG. There is a risk that it will.

  Therefore, in the terminal connection mechanism 100 of the present embodiment, the frame portion 130 is arranged around the plug 110 and the projection 125 is formed on the socket housing 124. The protrusion 125 and the frame 130 can be switched between a contact state and a non-contact state by an axial rotation angle of the socket 120 with respect to the plug 110 at a pressed position where the lock state is established.

  In the present embodiment, the through hole 132 of the frame portion 130 has a rectangular shape, and the protruding portions 125 are arranged above and below the socket 120. When the socket housing 124 is oriented in the vertical direction, the pushed-in position becomes a locked state. The projection 125 and the frame contact. For this reason, the socket 120 cannot be pushed further. On the other hand, when the socket housing 124 is inclined obliquely, the projection 125 and the frame do not come into contact with each other at the pushed-in position where the lock state occurs. Therefore, the lock can be released by further pushing the socket 120.

  In order to clearly show this positional relationship to the operator, a triangular mark 134 is provided in the vertical direction with respect to the socket 120 of the frame portion 130, and a circular mark 135 is provided in the oblique direction (see FIG. 1). Also, a triangular mark 126 is provided in the vertical direction of the socket housing 124, and a circular mark 127 is provided in the horizontal direction. The socket 120 is locked by pushing the socket 120 in the direction in which the triangular marks overlap, and is unlocked by pushing the socket 120 in the direction in which the round marks overlap.

  When the operator attaches the socket 120 to the plug 110, as shown in FIG. 4, the socket housing 124 is turned upright, and the movable frame 130a is slid upward, and the projection 125 is attached to the frame 130. The socket 120 is pushed into the plug 110 until it hits. This results in a locked state. Since the socket 120 cannot be pushed any further, unintended unlocking can be prevented. At this time, the operator can use the triangular mark 126 of the socket housing 124 and the triangular mark 134 of the frame 130 as a guide.

  To remove the locked socket 120 from the plug 110, the socket 120 is rotated obliquely about the plug 110 as shown in FIG. As a result, the state in which the protrusion 125 abuts on the frame 130 is released. At this time, the operator can use the round mark 127 on the side surface of the socket housing 124 and the round mark 135 of the frame 130 as a guide.

  In this state, the lock is released by further pushing the socket 120 as shown in FIG. Thus, the socket 120 can be pulled out, and the socket 120 can be removed from the plug 110 as shown in FIG.

  As described above, the terminal connection mechanism 100 of the present embodiment employs a push-pull method in which the socket 120 is locked by being pushed into the plug 110 and is further unlocked by being pushed further. In the pushed-in position where the lock state is established, the protrusion 125 that can switch between the contact state and the non-contact state with the frame part 130 is formed according to the rotation angle with respect to the plug 110, so that operability is high, reliability and safety Also excellent in nature.

  In the above-described example, the frame unit 130 is configured by the moving frame unit 130a and the fixed frame unit 130b. However, as illustrated in FIG. 7, the frame unit 130 may be a frame unit 130 that is entirely fixed. Also in this case, a through hole 132 for exposing the plug 110 is formed so that the edge is not at a uniform distance from the plug 110.

  Further, the through-hole 132 formed in the frame portion 130 is not limited to a rectangular shape. It is only necessary to have an edge whose distance from the plug 110 is not uniform. For example, as shown in FIG. 8A, a circular shape in which a notch is formed in a part of the circumference may be used. In this case, when releasing the lock, the socket housing 124 is inclined so that the projection 125 is aligned with the cutout portion. At this time, as shown in FIG. Even when the through hole 120 has a rectangular shape or the like, the number of the protrusions 125 may be one.

  The notch formed in a part of the circumference may be two places. For example, two notches are arranged diagonally. In this case, the number of the protrusions 125 may be two. For example, the two protrusions 125 are arranged diagonally. If the number of the protrusions 125 is one, and the plug 110 or the cable is heavy, the plug 110 may bow and fall. In the case where the number of the protrusions 125 is two, the lower protrusions 125 hit the frame portion 130, so that the fall can be suppressed.

  Since the socket 120 can be rotated with respect to the plug 110, if there are two projections 125, the projection is always located in the lower half, regardless of which direction the socket 120 is connected. That is, the lower protrusion 125 can be applied to the frame 130.

  Further, the marks used as a guide for the lock position and the lock release position are not limited to triangles and round shapes. The mark may be used as a guide for either the lock position or the unlock position, or both may be omitted.

100 terminal connection mechanism 110 plug 111 plug side lock ring 120 socket 123 socket side lock ring 124 socket housing 125 projection 126 triangle mark 127 round mark 130 frame 130a moving frame 130b ... Fixed frame part 132 ... Through hole 134 ... Triangle mark 135 ... Round mark

Claims (5)

A terminal connection mechanism having a cylindrical plug and a cylindrical socket attached to the plug, wherein the socket is locked by pushing the socket into the plug, and further unlocked by further pushing. ,
A frame portion in which a through hole having an edge in which the plug is exposed and the distance from the plug is not uniform,
A socket housing for holding the socket in a state where a plug mounting portion is projected,
A projection is formed on the socket protruding side of the socket housing at a pushing position where the locking state is established, and the contacting state and the non-contacting state with the frame can be switched by a rotation angle with respect to the axis of the plug. A terminal connection mechanism, characterized in that: The through-hole has an edge in which a cutout is formed at least two places in a part of the circumference,
The terminal connection mechanism according to claim 1, wherein the socket housing has at least two protrusions.   The terminal connection mechanism according to claim 1, wherein the frame portion includes a movable frame portion that hides the plug by sliding.   The frame and the socket housing are provided with a mark as a guide of a rotation angle at which the frame and the projection are in contact with each other at the pushed-in position where the lock state is established. Item 4. The terminal connection mechanism according to any one of Items 1 to 3.   The frame portion and the socket housing are provided with a mark as a guide of a rotation angle at which the frame portion and the protrusion are in a non-contact state at the pushed-in position where the lock state is established. The terminal connection mechanism according to claim 1.