The invention relates to a switch device, in which an operation unit used in a state of attachment to a panel, or the like, and a switch unit, in which an opening-closing contact is opening-closing operated by the operation unit, are structured to be separable from each other.
For example, Patent Literature 1 describes a known switch device in which an operation unit and a switch unit operated by the operation unit are structured to be separable.
A conventional switch device 1 described in Patent Literature 1 is depicted in
A switch device 100 is provided with an operation unit 110 and a switch unit 120 which are structured mutually attachable and detachable. The operation unit 110 transmits a pushing operating force, which is applied from the outside, to the switch unit 120. The switch unit 120 receives the operating force from the operation unit 110 and opens/closes a plurality of opening/closing contact portions on the basis of the operating force.
The operation unit 110 is provided with an operation unit main body 111 and a pushbutton 113. The pushbutton 113 has a substantially round columnar shape, and the upper end surface of the pushbutton 113 receives the operating force from the outside in the axial direction. A protrusion 114 having a round columnar shape is provided in a protruding condition at the side surface on the lower end side of the pushbutton 113. Two guide grooves 112 having a substantially inverted L-shape are provided facing each other on the lower side of the side surface of the operation unit main body 111 for allowing the operation unit main body 111 to be rotated and fitted into the switch unit 120.
The pushbutton 113 of the operation unit 110 is supported by the operation unit main body 111 such that the pushbutton can move in the axial direction and cannot rotate in the rotation direction. As depicted in
The switch unit 120 is provided with a partition wall 123 partitioning the inner space of a switch unit main body 121 in the horizontal direction, and a through hole 124 passing through along the central axial line X is provided in the central portion of the partition wall. Two engagement protrusions 122 to be engaged with the guide groove 112 of the operation unit 110 are integrally formed on the inner wall of the switch unit main body 121 above the partition wall 123.
A contact shaft 125 is inserted into the through hole 124 such that the contact shaft can move in the direction of the central axial line X, but cannot rotate about the central axial line X. A tubular pushbutton receptacle 126 into which the lower end portion of the pushbutton 113 is to be inserted from above is provided at the upper end of the contact shaft 125. A helical cut-out guide 127 which extends downward, while turning about the central axial line X, as shown in the figure, is provided in the circumferential side surface of the pushbutton receptacle 126 in order to engage with the protrusion 114 of the pushbutton 113.
An opening-closing contact mechanism 130 is accommodated in a space below the partition wall 123 in the switch unit main body 121. The opening-closing contact mechanism 130 is provided with a pair of fixed contactor pieces 132, each movable contactor piece being provided with a fixed contact 133, and a movable bridging piece 134 provided with a pair of movable contacts 135 at both ends. A distal end of the contact shaft 125 is joined to the central portion of the movable bridging piece 134, and a contact spring 131 that urges the movable bridging piece 134 in the direction of separating from the fixed contactor pieces 132 is attached to the contact shaft 125 between the movable bridging piece 134 and the partition wall 123. An external connection terminal piece 136 is drawn out to the outside of the main body 121 from each of the fixed contactor pieces 132. The fixed contact 133 of the fixed contactor piece 132 and the movable contact 135 of the movable bridging piece 134 are provided facing each other to enable contact and separation thereof.
The operation unit 110 is mounted on a panel (not shown in the figure).
In a state in which the switch unit 120 is separated from the operation unit 110, as depicted in
When the switch unit 120 is to be joined to the operation unit 110 from this state, initially, the switch unit 120 is fitted from below into the operation unit 110 so that the engagement protrusion 122 of the switch unit 120 is inserted into an inlet port of the guide groove 112 of the operation unit 110 and the protrusion 114 is inserted into an inlet port of the cut-out guide 127 of the switch unit.
Then, the switch unit main body 121 is turned in the direction of an arrow R (to the right) about the central axial line X. Since the pushbutton 113 is arranged to be incapable of rotating with respect to the operation unit main body 111, when the switch unit main body 121 is turned in the direction of arrow R, the protrusion 114 moves inside the helical cut-out guide 127. As a result, the protrusion 114 moves the pushbutton receptacle 126 upward, and following this movement, the movable contact 135 also moves upward, but when the switch unit main body 121 is stopped from turning, the movable contact 135 becomes a state (switch-on) contacting the fixed contact 133 (see
To detach the switch unit 120 from the operation unit 110, a procedure reversed to the procedure used to attach the switch unit 120 to the operation unit 110 is implemented. Thus, in a state in which the switch unit 120 depicted in
With the switch device 100 having such an arrangement, in a standby state, the movable contacts 135 and the fixed contacts 133 are closed at all times and the switch-on state is maintained, as depicted in
When the pushbutton 113 of the operation unit 110 is pushed down in this state, the movable bridging piece 134, which is linked to the pushbutton through the pushbutton receptacle 126 and the contact shaft 125, is lowered. Therefore, the movable contacts 135 are separated from the fixed contacts 133 and become the switch-off state (see
When an accident occurs such that the switch unit 120 joined to the operation unit 110 is detached from the operation unit 110, the movable contacts 135 of the switch unit 120 are urged by the return spring 131 in the separation direction and automatically separated from the fixed contacts 133 that have been in a closed state at all times, becoming a switch-off state (the state identical to the operation state). Therefore, when the switch device is used as an emergency stop switch, an accident causing the switch unit 120 to detach from the operation unit 110 results in a switch-off state. As a result, a stop command is issued to the control object and safety of the control object can be maintained.
Patent Literature 1: Japanese Patent Application Publication No. 2004-103363
In the aforementioned conventional switch device, the movable contacts of the opening-closing contact mechanism are urged at all times by the contact spring that urges in the direction such that the opening-closing state of the opening-closing contact is the opening-closing state at the time of the operation state, that is, in the direction in which the movable contacts and the fixed contacts are separated from each other in the case of a normally closed contact arrangement, or in the direction in which the movable contacts and the fixed contacts are closed in the case of a normally open contact arrangement.
Therefore, the problem associated with a switch device having a normally closed contact arrangement such that the opening-closing contacts are closed in the standby state is that when a slight impact force is applied to the switch unit 120, or the joined state of the switch unit 120 and the operation unit 110 becomes loose, the contact shaft 125 and the movable bridging piece 134 supporting the movable contacts 135 are pushed downward by the contact spring 131, the movable contacts 135 are separated from the fixed contacts 133, and an erroneous operation such as a switch-off operation can be temporarily performed.
In the switch device having a normally open arrangement such that the opening-closing contacts are open in the standby state, an impact force can erroneously close the fixed contacts with the movable contacts, regardless of the operator's intentions, thereby causing a switch-on state.
The invention is provided to resolve the aforementioned problems, and it is an objective of the invention to provide a switch device with a high operation reliability in which opening-closing contact portions are not erroneously opened or closed even when an impact is applied to the switch device from the outside.
In order to resolve the problems, the invention provides a switch device including an operation unit having a pushbutton for performing a pushing operation, and a switch unit detachably attached to the operation unit and equipped with an opening-closing contact mechanism opened or closed in conjunction with the pushing operation of the pushbutton of the operation unit.
The switch unit is provided with a rotary drive plate which rotates between a standby position and a usage position. In the standby position, the switch unit drives the opening-closing contact mechanism to be in an opening-closing state where the operation unit is in an operation state, and in the usage position, the switch unit drives the opening-closing contact mechanism to be in an opening-closing state where the operation unit is in a standby state. The operation unit is provided with an engagement portion engaged to the rotary drive plate to rotary-drive the rotary drive plate from the standby position to the usage position when the operation unit is joined and attached to the switch unit. The operation unit is attached to or detached from the switch unit to set the opening-closing contact mechanism to respectively predetermined opening-closing states.
In the embodiment, the opening-closing contact mechanism may be provided with a contact spring that urges an opening-closing contact of the opening-closing contact mechanism in a direction to be in an opening-closing state where the operation unit is in the standby state.
The rotary drive plate can be provided, at one end thereof, with a cam piece that drives the opening-closing contact mechanism.
Further, the rotary drive plate of the switch unit can be also provided with a return spring that returns the rotary drive plate from the usage position to the standby position when the switch unit is separated from the operation unit.
Further, the engagement portion engaging the rotary drive plate with the operation unit includes an engagement groove provided at the operation unit or the rotary drive plate and inclined in an axial direction and an engagement protrusion provided at the rotary drive plate or the operation unit so as to be engaged with the engagement groove.
According to the invention, the switch unit, which is separably joined to the operation unit, is provided with a rotary drive plate which rotates between a standby position and a usage position, operates the opening-closing contact mechanism in the standby position to an opening-closing state where the operation unit is in an operation state, and operates the opening-closing contact mechanism in the usage position to an opening-closing state where the operation unit is in a standby state. The operation unit is arranged to be engaged with the rotary drive plate and rotary-drive the rotary drive plate from the standby position to the usage position when the operation unit is joined and attached to the switch unit. Therefore, the opening-closing contact mechanism can be set to a respective predetermined opening-closing state by detaching or attaching the operation unit from or to the switch unit. As a result, if by any chance an accident occurs such that causes the operation unit to separate from the switch unit, the opening-closing state of the opening-closing contact mechanism can be obtained as the opening-closing state where the operation unit is in the operation state. The switch device thus can be used as an emergency safety device.
Further, the opening-closing contacts of the opening-closing contact mechanism are urged at all times in the direction to be in the opening-closing state at the time the operation unit is in the standby state, that is, in the direction in which the movable contacts and the fixed contacts are closed in the case of a normally closed contact structure and in the direction in which the movable contacts and the fixed contacts are separated from each other in the case of a normally open contact structure. Therefore, even when an impact is applied to the switch device in the standby state, the movable contacts are unlikely to move. As a consequence, erroneous operation is prevented and operation reliability of the switch device can be increased.
An embodiment of the invention will be explained hereinbelow in detail with reference to the drawings.
In
The operation unit 10 transmits an external operating force to the switch unit 20 and opens/closes an opening/closing contact mechanism located inside the switch unit 20. The operation unit includes a pushbutton 12 and an operation unit main body 11 that supports the pushbutton.
As shown in detail in
When the aforementioned components are assembled, initially, a bent portion 14a at one end of the return spring 14 is inserted in and engaged with an engagement groove 12b of the pushbutton 12. A distal end portion of the push rod 13 is inserted into the spring 14 engaged with the pushbutton 12, and a bent portion 14b at the other end of the spring 14 is inserted in and engaged with a fixing hole 13e of the push rod 13. In this state, the pushbutton 12 is rotated rightward, a pair of engagement protrusions 12c located inside the pushbutton 12 is aligned with a pair of L-shaped engagement grooves 13d on the outer circumference of the distal end portion of the push rod 13, and then the push rod 13 is inserted into the pushbutton 12, and the engagement protrusions 12c and the engagement grooves 13d are engaged with each other. As a result, the pushbutton 12 and the push rod 13 are joined through the return spring 14 so as to be rotatable relative to each other within a predetermined angular range, as depicted in
The operation unit 10 is formed by joining the operation unit main body 11 to the pushbutton 12 of the above-described structure. As shown in detail in
The assembly of the pushbutton 12, the push rod 13, and the return spring 14 is inserted from above into the operation unit main body 11. In this case, the lock pin 15 which is pressed inward by the lock spring 16 on the main body side pushes the push rod 13 such as to ride over the receding-protruding section on the outer circumference of the push rod 13 and be locked in a first recess 13a for locking. Then, a trigger spring 18 and a push body 19 are inserted from below into the operation unit main body 11, an engagement hole 19a in the push body 19 is engaged with an engagement protrusion 13f at the lower end side of the push rod 13, the main body 11 and the pushbutton 12 are integrally joined, and the operation unit 10 is formed.
The operation unit main body 11 and the pushbutton 12 are joined to be capable of moving in the axial direction and rotation direction with respect to each other. However, since two rotation suppressing protrusions 11j are provided with a spacing of angle C on the inner side of the upper portion of the operation unit main body 11, and a rotation suppressing protrusion 12d corresponding thereto and located on the pushbutton 12 is fitted between the two protrusions 11j, the range of rotation of the pushbutton 12 relative to the operation unit main body 11 is restricted to the range of angle C. Further, when the push rod 13 is inserted into the operation unit main body 11, a rotation preventing protrusion 11k provided inside the operation unit main body 11 correspondingly to a rotation preventing groove 13g provided in the axial direction on the outer circumference of the push rod engages with the rotation preventing groove 13g, thereby preventing the push rod 13 from rotating relative to the operation unit main body 11 and allowing only the vertical (axial) movement.
The engagement of the engagement protrusion 12c of the pushbutton 12 with the L-shaped engagement groove 13d of the push rod 13 allows the pushbutton 12 to be rotated within a range of a rotation angle D (see
In the operation unit 10 having such a structure, in a standby state before the pushbutton 12 is pushed, the return spring 14 pushes up the pushbutton 12, and the lock pin 15 is engaged with the first recess 13a provided on the outer circumference of the intermediate portion of the push rod 13, thereby locking the push rod 13 in this position. Therefore, the pushbutton 12 is held, this position serving as a standby position. The lock pin 15 is supported by the lock holder 17 through the lock spring 16 to be radially retractable inside the operation unit main body 11.
When the pushbutton 12 is pushed axially by a predetermined force or a stronger force, the push rod 13 receives this force and the inclined upper wall of the recess 13a pushes the lock pin 15 in the outer circumferential direction against the lock spring 16, thereby releasing the engagement of the recess 13a and the lock pin 15, and pushing the push rod 13 over the lock pin 15. The lock pin 15 that came out of the recess 13a engages with a second recess 13b in the upper portion of the recess 13a and holds the pushbutton 12 and the push rod 13 in the pushing operation position thereof.
The push rod 13 is arranged to push down the push body 19, which is linked to a movable contactor holder 22 of the switch unit through the trigger spring 18, by such a pushing operation. The lower end of the push body 19 hits the upper end of the movable contactor holder 22 of the switch unit 20, pushes the movable contactor holder down, and opens/closes the opening-closing contact mechanism of the switch unit 20 (see
Further, a fixing thread 11d is provided on the outer circumference of the body portion 11c below a flange portion lib of the operation unit main body 11. A fastening nut 11e is screwed onto the thread 11d to fasten and fix the operation unit 10 to a panel such as a control panel. An axial engagement groove 11f (see
An engagement groove 11g for engagement with an engagement ridge 21b extending axially at the inner circumference of a cylindrical portion 21a of a switch unit main body 21 of the switch unit 20 is additionally provided at the outer circumference of the lower body portion 11c of the operation unit main body 11 (see
The switch unit 20 that is detachably connected to such an operation unit 10 is explained below.
As depicted in
Further, as shown in detail in
Further, as depicted in
The rotary drive portion 30 is provided with a rotary cover 31, a rotary drive plate 32, and a rotary drive spring 33. Engagement protrusions 32b formed at the inner circumferential side of the rotary drive plate 32, which is formed to be split in two substantially semicylindrical portions, are inserted in and engaged with a pair of semicircular-arc grooves 21d formed at the outer circumference of the cylindrical portion 21a of the switch unit main body 21, thereby rotatably supporting the rotary drive plate 32 with the cylindrical portion 21a. A cam piece 32a having a cam surface inclined in the circumferential direction is partially formed at the lower end of the rotary drive plate 32. As shown in
The rotary drive plate 32 supported by the cylindrical portion 21a of the switch unit main body 21 is covered from above with the rotary cover 31. The rotary drive spring 33 formed from a twisted coil spring is inserted between the rotary cover 31 and the rotary drive plate 32, and the two ends of the rotary coil spring are engaged. For this purpose, a round fitting hole 31a that fits the cylindrical portion 21a of the switch unit main body 21 is provided in the central portion of the rotary cover 31, and a fitting hole 31b that fits the upper protrusion 32d of the rotary drive plate 32 is provided outside the round fitting hole 31a. Further, a protrusion 31c engaging with the engagement groove 11f provided in the lower body portion 11c of the operation unit main body is formed protruding at a position facing the inner circumference of the fitting hole 31a.
When the rotary cover 31 is covered on the rotary drive plate 32, the distal end portion of the cylindrical portion 21a of the switch unit main body 21 is loosely fitted to the fitting hole 31a of the rotary cover 31, and the rotary cover 31 is rotatably supported on the switch unit main body 21. Further, at this time, the protrusion 32d at the upper portion of the rotary drive plate 32 is fitted to the fitting hole 31b of the rotary cover 31, and the rotary cover 31 and the rotary drive plate 32 are joined integrally together. Therefore, the rotary cover 31 and the rotary drive plate 32 are integrally rotatably supported by the cylindrical portion 21a of the switch unit main body 21. The rotary drive spring mounted between the rotary cover 31 and the cylindrical portion 21a of the switch unit main body 21 is locked at one end to the cylindrical portion 21a and locked at the other end to the rotary cover 31, whereby elastic restoration forces are applied in the axial and rotation directions to the rotary cover 31 and the rotary drive plate 32.
When the operation unit 10 and the switch unit 20 arranged in the above-described manner are separated from each other, as depicted in
The procedure by which the operation unit 10 is thus joined to the switch unit 20, in which the rotary drive portion 30 is placed at the standby position, to obtain the usage state will be explained hereinbelow with reference to
The lower body portion 11c of the main body 11 of the operation unit 10 is inserted from above into the cylindrical portion 21a of the switch unit 20 in which the rotary drive portion 30 is placed at the standby position. For this purpose, initially, as depicted in
Once such an alignment is attained, the lower body portion 11c of the operation unit main body 11 is inserted from above into the cylindrical portion 21a of the switch unit 20, in which the rotary drive portion 30 is placed at the standby position, and pushed down while the protrusions 31c, 32c are fitted to the engagement groove 11f, and the engagement ridge 21b is fitted to the engagement groove 11g (
When the protrusion 31c of the rotary cover 31 and the protrusion 32c of the rotary plate 32 reach the horizontal portion 11f-2 of the engagement groove 11f, as shown in
The operation unit 10 is thus inserted to the very end into the rotary drive portion 30, and becomes the usable state when the operation unit 10 is joined to the switch unit 20, as shown in
When the switch unit 20 and the operation unit 10 are separated from each other from the joined state thereof, the operations may be performed according to a procedure reversed with respect to the joining procedure illustrated by
In the switch device 1 depicted in
When the pushbutton 12 of the operation unit 10 is pushed in the direction of an arrow P, as depicted in
In order to return the switch device 1 in such an operation state to the standby state such as depicted in
In order to facilitate such an operation of releasing the locked state, as shown in
In the standby state before the pushing operation of the pushbutton 12, the lock pin 15 is engaged with the recess 13a in the lower part of the push rod 13 joined to the pushbutton 12, as depicted in
In the operation state in which the pushbutton 12 has been pushed, the lock pin 15 engages with the recess in the upper part of the push rod 13 and the locked state is maintained. Therefore, the pushbutton 12 is at the push-down position, the cam portion 12e of the pushbutton 12 approaches the cam portion 11m of the operation unit main body 11, and practically no gap is present therebetween.
When the pushbutton 12 is rotated from this state to the right in the preset range of rotation angle C described hereinabove, the cam surface of the cam portion 12e of the pushbutton 12 comes into contact with the cam surface of the cam portion 11m of the operation unit main body 11 and is pushed up along this cam surface. The push rod 13 rises accordingly, and the recess 13a located in the lower part thereof engages with the lock pin 15 and returns to the original standby position.
When the locked state at the operation position created by the lock pin 15 is thus released, the movable contactor holder 22, the push rod 13, and the pushbutton 12 are pushed by the restoration forces of the contact spring 27 and the trigger spring 18, and returned to the position of the standby state. The pushbutton 12 is returned to the original rotation position by the twisted return spring 14 and becomes the standby state depicted in
If by any chance an accident occurs such that the switch unit 20 of the switch device 1 separates from the operation unit 10, as depicted in
In the switch device 1 of the invention, in a state in which the rotary drive portion 30 is placed at the usage position and the pushbutton 12 is in the standby state, as depicted in
1—switch device, 10—operation unit, 11—operation unit main body, 12—pushbutton, 13—push rod, 20—switch unit, 21—switch unit main body, 22—movable contactor holder, 25-1a—normally open fixed contact; 25-2b—normally closed fixed contact, 26-1a—normally open movable contact, 26-2b—normally closed movable contact, 27—contact spring, 30—rotary drive portion, 31—rotary cover, 32—rotary drive plate, 32a—cam piece, 33—rotary return spring
Number | Date | Country | Kind |
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2013-019361 | Feb 2013 | JP | national |
This is continuation application of Ser. No. 14/815,274 filed on Jul. 31, 2015, which is a PCT International Application No. PCT/JP2013/083155 filed Dec. 11, 2013, which claims priority of Japanese Patent Application No. 2013-019361 filed Feb. 4, 2013, the disclosure of which is incorporated herein.
Number | Date | Country | |
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Parent | 14815274 | Jul 2015 | US |
Child | 15481070 | US | |
Parent | PCT/JP2013/083155 | Dec 2013 | US |
Child | 14815274 | US |