CN218548299U - Double-control switch - Google Patents

Abstract

The present application relates to a dual-control switch comprising a movable part and a fixed part. The fixed part comprises a key fixing support, a mounting support, a connecting support and a rear seat. The movable part comprises a key, a swing rod driving part, a swing rod and a conductive component. The button fixed bolster sets up between button and linking bridge, and the installing support setting is between linking bridge and back seat, and the setting of pendulum rod driving piece is close to the terminal surface of linking bridge at the installing support, and pendulum rod and conductive component all set up in the accommodation space that installing support and back seat constitute. The button is movably connected with the swing rod in a driving mode, the swing rod driving part is movably connected with the swing rod, and the swing rod is movably connected with the conductive assembly.

Description

Double-control switch

Technical Field

The application relates to the technical field of electric appliances, in particular to a double-control switch.

Background

This section provides background information related to the present application and does not necessarily constitute prior art.

The double-control switch is a switch with two normally open and normally closed contacts, and the on-off action of the switch can be triggered by pressing one of the two contacts. The basic structure of the double-control switch comprises three connecting terminals, wherein one input connecting terminal and two output connecting terminals are arranged, a moving contact with two contacts is connected with the input connecting terminal, two fixed contacts are respectively connected with the two output connecting terminals, and a switch key assembly controls the two contacts of the moving contact to respectively perform on/off switching between the two fixed contacts. For a double-control switch in a wall switch, three major demand trends are faced: the technical improvements of high-current control, multi-line access and threadless wiring, which are based on the three requirements, need to increase the volume of the double-control switch, particularly the thickness of the double-control switch. However, the wire slots reserved on the wall for installing the double-control switch are standardized, and the space of the wire slots is fixed and limited. In addition, the three requirements also cause the problem that the wire occupies a large amount of the slot space, for example, compared with the prior art that a thick wire with a 4-square-millimeter access of a double-line (2 incoming wires plus 4 outgoing wires) occupies 8 times of the slot space of a thin wire with a 1-square-millimeter diameter of a single-line (1 incoming wire plus 2 outgoing wires), the problem that the slot space is not enough is highlighted. The problem that the space of a wire slot is insufficient is solved, a method for reducing the volume of a wire cannot be adopted, and only a method for reducing the volume of a double-control switch can be adopted, so that the thickness reduction design of the double-control switch is the most urgent and challenging technical problem in the production of the current double-control switch product.

The reduced thickness design of the dual-control switch is challenging for a number of reasons, the main reason being that there are many design conflicts in the art. Firstly, the increase of rated current needs to increase the breaking distance of the contact and the insulation distance between the guide pieces, and the increase of the distances is in contradiction with the design of thickness reduction. Secondly, the volume of each connecting terminal needs to be increased for multi-line access and thick lead access, and the increase of the volume is also contradictory to the design of thickness reduction. And once again, the thread-free quick connection and disconnection requires the increase of operation space for connection and disconnection and the intervention of fingers or tools, and the increase of the space is also contradictory to the design of thickness reduction. For the above reasons, the problem of large volume of the dual-control switch in the prior art is still very prominent, and it is impossible to obtain the ideal effect without optimizing the overall design and the structural design.

Moreover, the double-control switch provided by the prior art has various components and a complex structure, so that the adverse risk of the switch product is easily increased, and the light and thin development of the switch is not facilitated.

SUMMERY OF THE UTILITY MODEL

In view of the above, the present application provides a dual-control switch, which can solve the above technical problems in the related art.

Specifically, the method comprises the following technical scheme:

a dip switch, the dip switch comprising: a movable portion and a fixed portion.

The fixed part comprises a key fixing support, a mounting support, a connecting support and a backseat.

The movable part comprises a key, a swing rod driving part, a swing rod and a conductive component.

The key fixing support is arranged between the key and the connecting support, and the mounting support is arranged between the connecting support and the rear seat. The swing rod driving piece is arranged on the end face, close to the connecting support, of the mounting support, and the swing rod and the conductive assembly are arranged in an accommodating space formed by the mounting support and the rear seat. The swing rod driving piece is movably connected with the swing rod, the key is movably connected with the swing rod driving piece, and the swing rod is movably connected with the conductive assembly.

The end face, away from the key, of the key fixing support is provided with a groove, the connecting support enters the groove from a groove opening of the groove, and the outer side wall of the connecting support is connected with the inner side wall of the groove in a clamping mode. The middle part of the connecting support is provided with a hole which penetrates through the front end face and the rear end face of the connecting support, a raised barrier layer is arranged on the rear end face of the connecting support in the circumferential direction of a hole around the hole, and the outer side wall of the mounting support is connected with the barrier layer in a clamping mode. The end face, far away from the connecting support, of the mounting support is provided with a clamping block, a clamping hole is formed in the side wall of the rear seat, and the clamping block is connected with the clamping hole in a clamping mode.

The key is connected with the front end face of the key fixing support, the middle of the key is connected with the key fixing support, the joint forms a first fulcrum part, and the two ends of the key can rotate by taking the first fulcrum part as a circle center. The two ends of the end face of the key connection key fixing support are respectively provided with a pressing block, and the pressing blocks rotate along with the rotation of the two ends of the key. The briquetting runs through button fixed bolster, linking bridge's hole in proper order and with the contact of pendulum rod driving piece.

The front end face of the connecting support is connected with the key fixing support, and the rear end face of the connecting support is connected with the mounting support. The holes of the connecting bracket form a movable space of the swing rod driving piece. The bottom of the groove, away from the end face of the button, of the button fixing support is provided with two fixing portions, the two fixing portions penetrate through holes of the connecting support and are arranged on two sides of the middle of the swing rod driving piece, and the middle of the swing rod driving piece is hinged to the two fixing portions.

The pendulum rod driving piece comprises two transition pieces, the two transition pieces are symmetrically distributed and symmetrically arranged along the length direction of the key, namely, one transition piece corresponds to one end of the key, each pressing block of the key is correspondingly contacted with one transition piece, one pressing block of the key can directly act on one transition piece, and the other pressing block of the key directly acts on the other transition piece. When pressing the arbitrary one end at the both ends of button, the briquetting can be applyed pressure for the transition piece that corresponds, and the transition piece can use the middle part of pendulum rod driving piece to rotate as the centre of a circle to can make the pendulum rod driving piece take place the rotation action, the rotation action of pendulum rod driving piece can drive the pendulum rod and take place corresponding action, thereby trigger switch's break-make action.

The swing rod driving piece further comprises two push rods, the two push rods are arranged on the end face, far away from the pressing block, of the transition piece respectively, and one ends, far away from the transition piece, of the push rods penetrate through the mounting support and are arranged on two sides of the swing rod.

One end of the swing rod is hinged with the middle of the swing rod driving piece, so that the other end of the swing rod can rotate by taking the hinged joint as a circle center, and one end, far away from the swing rod driving piece, of the swing rod is connected with a trigger plate through an elastic part. Two first contacts are respectively arranged on two end faces of the trigger plate. When pressing the arbitrary one end of button, the transition piece can use the middle part of pendulum rod driving piece to rotate as the centre of a circle and make pivoted push rod promote the pendulum rod, and the one end that the pendulum rod kept away from the pendulum rod driving piece drives the trigger plate and takes place corresponding action this moment, and the elastic component produces tensile deformation.

The conductive assembly comprises a first terminal, a second terminal and a third terminal, and the conductive assembly further comprises a fixing plate, a second contact and a third contact, wherein the fixing plate and the second contact are connected with the first terminal, and the third contact is connected with the second terminal. The fixed plate is located trigger plate below, and the bottom and the fixed plate contact of trigger plate form second fulcrum portion, and the first contact setting of trigger plate is between second contact and third contact, uses second fulcrum portion as the centre of a circle through trigger plate to rotate, and the first contact realization on the trigger plate contacts with second contact or third contact. When the first contact and the third contact are contacted, the double-control switch is in a switch-on state; when the first contact and the second contact are contacted, the double-control switch is in an off state.

In one embodiment, the first terminal, the second terminal and the third terminal are used for connecting three-phase wires, the first terminal is connected with a neutral wire, the second terminal is connected with a live wire, and the third terminal is connected with a ground wire.

In one embodiment, the first terminal, the second terminal and the third terminal are all connected with a live wire of a mains supply, and the double-control switch realizes the switching action by controlling the on-off of the live wire.

The elastic part of the swing rod is in a compressed state, and the elastic part can apply pressure to the trigger plate, so that the elastic part and the fixed plate clamp the trigger plate tightly, the bottom of the trigger plate is in close contact with the fixed plate, and a second fulcrum part is formed.

The technical scheme provided by the embodiment of the application has the beneficial effects that at least:

the application provides a double control switch, when the arbitrary one end at the both ends of pressing the button, the pressing force that comes from the button can transmit to corresponding transition piece on, make the transition piece use the middle part of pendulum rod driving piece to rotate as the centre of a circle, it is corresponding, the push rod that is located the pivoted transition piece moves until and promote the pendulum rod with the pendulum rod contact towards the direction that is close to the pendulum rod thereupon, the pendulum rod is kept away from the one end drive of pendulum rod driving piece and is triggered the board rotation, it uses second fulcrum portion to rotate as the centre of a circle to trigger the board and makes first contact second contact or third contact, the break-make function of double control switch is realized to this process. The double control switch that this application embodiment provided converts the press motion of button into the rotation of transition piece and triggers the operation, because the contact site of transition piece and button is far away with the distance of the middle part of the pendulum rod driving piece as the centre of a circle, like this, the little stroke press motion of button can be converted into the big stroke motion of the transition piece of pendulum rod driving piece. The conversion from the small stroke to the large stroke is beneficial to reducing the installation height of the key and the development of the double-control switch in a light and thin way. The swing rod driving piece can be designed into an integrated structure, and has the advantages of simple structure, high transmission efficiency and completeness.

In addition, due to the continuous pressure of the elastic part on the trigger plate, the contact part of the trigger plate and the fixed plate can be used as a second fulcrum part, the oscillating bar drives the trigger plate to rotate around the second fulcrum part to realize the on-off function of the double-control switch, the operation reliability and the service life of the double-control switch are improved, the size of the double-control switch is reduced, and the light and thin development of the double-control switch is facilitated. Compared with the prior art, the double-control switch provided by the application uses fewer components, and the internal structure is simplified.

The following description will be given with reference to specific examples.

Drawings

The figures further illustrate the present application, but the examples in the figures do not constitute any limitation to the present application.

Fig. 1a is a schematic structural diagram of a dual-control switch according to an embodiment of the present application;

fig. 1b is a schematic structural diagram of a dual-control switch according to an embodiment of the present application;

fig. 2 is an exploded view of a dual-control switch according to an embodiment of the present application;

fig. 3 is a schematic structural diagram of a key and a key fixing bracket according to an embodiment of the present application;

fig. 4 is a schematic structural view of a key fixing bracket according to an embodiment of the present application;

FIG. 5a is a schematic structural view of a connecting bracket and a mounting bracket according to an embodiment of the present application;

FIG. 5b is a schematic view of a connection bracket and a mounting bracket according to an embodiment of the present application;

FIG. 6 is a schematic structural diagram of a mounting bracket according to an embodiment of the present application;

FIG. 7a is a schematic view of a connection structure of the swing link driving element, the swing link and the conductive element according to an embodiment of the present application;

FIG. 7b is a schematic diagram illustrating a connection structure of the swing link driving element, the swing link and the conductive element according to an embodiment of the present application;

FIG. 8 is a schematic structural diagram of a rear seat according to an embodiment of the present application;

FIG. 9a is a schematic view of a connection structure of a mounting bracket, a rocker driving element, a rocker and a conductive element according to an embodiment of the present application;

fig. 9b is a schematic view of a connection structure of the mounting bracket, the swing link driving element, the swing link and the conductive element according to an embodiment of the present application.

Wherein the reference numerals are: 100. a key fixing bracket; 101. a first groove; 102. a rotating part; 103. a first through hole; 104. a fixed part; 105. mounting holes; 106. a first engaging block; 200. mounting a bracket; 201. a second engaging block; 202. a second groove; 203. a limiting hole; 204. a third engaging block; 205. a fixed block; 300. connecting a bracket; 301. a first engaging groove; 302. an aperture; 303. a barrier layer; 304. a first engaging hole; 400. a rear seat; 401. a second engaging hole; 402. a wiring hole; 500. pressing a key; 501. a first boss portion; 502. an arc-shaped block; 503. briquetting; 600. a swing rod driving part; 601. a transition piece; 602. a push rod; 603. a guide block; 700. a swing rod; 800. a conductive component; 801. a first terminal; 802. a second terminal; 803. a third terminal; 804. a fixing plate; 805. a second contact; 806. a third contact; 901. an elastic portion; 902. a trigger plate; 903 a first contact.

Detailed Description

It should be understood that the specific embodiments described herein are merely illustrative of the present application and are not intended to limit the present application.

In the description of the present application, it is to be understood that the terms "center," "longitudinal," "lateral," "length," "width," "thickness," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," "clockwise," "counterclockwise," and the like are used in the orientations and positional relationships indicated in the drawings for convenience in describing the present application and for simplicity in description, and are not intended to indicate or imply that the referenced devices or elements must have a particular orientation, be constructed in a particular orientation, and be operated in a particular manner, and are not to be construed as limiting the present application. Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, features defined as "first" and "second" may explicitly or implicitly include one or more of the described features. In the description of the present application, "a plurality" means two or more unless specifically defined otherwise.

In the description of the present application, it is to be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral connection; they may be mechanically coupled, directly coupled, or indirectly coupled through intervening agents, both internally and/or in any other manner known to those skilled in the art. The specific meaning of the above terms in the present application can be understood by those of ordinary skill in the art as appropriate.

In this application, unless expressly stated or limited otherwise, the first feature "on" or "under" the second feature may comprise direct contact of the first and second features, or may comprise contact of the first and second features not directly but through another feature in between. Also, the first feature being "on," "above" and "over" the second feature includes the first feature being directly on and obliquely above the second feature, or merely indicating that the first feature is at a higher level than the second feature. The first feature being "under," "beneath," and "under" the second feature includes the first feature being directly above and obliquely above the second feature, or simply meaning that the first feature is at a lesser level than the second feature.

The present embodiments provide a double-control switch including a movable portion and a fixed portion. The fixing portion includes a key fixing bracket 100, a mounting bracket 200, a connecting bracket 300, and a rear seat 400. The movable portion includes a button 500, a swing link driving member 600, a swing link 700, and a conductive member 800. As shown in fig. 1a and fig. 1b, an operator presses the key 500 to turn on or off the dual-control switch, one of the two ends of the key 500 is in a tilted state, a gap exists between the key 500 and the key fixing bracket 100, the other end of the key 500 contacts and adheres to the key fixing bracket 100, and the tilted end of the key 500 can change the on-off state of the dual-control switch and change the original end that is not tilted into the tilted state. The button 500, the swing link driving member 600 and the swing link 700 constitute a pressing force transmission mechanism. With the dual-control switch horizontally placed as reference, the beneficial effects of the transmission mechanism can be described as follows: the force of pressing the button 500 vertically downwards is converted into the force of pushing the swing rod 700 horizontally through the swing rod driving element 600, so that the trigger plate 902 connected with the swing rod 700 and the swing rod 700 can be close to the vertical arrangement, because the accommodating space of the rear seat 400 is limited, and the conductive component 800 is horizontally arranged relatively, the swing rod 700 and the trigger plate 902 are obliquely arranged along the vertical direction, so that the gap which is formed because the connecting ends electrically connected with the commercial power and the conductive component 800 can not be contacted with each other can be effectively utilized, therefore, the accommodating space of the rear seat 400 is effectively utilized, the depth of the accommodating space can be correspondingly reduced, and the development of the double control switch in a light and thin manner is facilitated.

As shown in fig. 2, the key fixing bracket 100 of the dual control switch is used to connect the key 500. The connection bracket 300 is used to connect the key fixing bracket 100 and the mounting bracket 200 at the same time, and the connection bracket 300 can increase the strength of the on-off switch while reducing the thickness of the on-off switch as much as possible. The fixing bracket 100 is used for connecting the swing link driving member 600, and the fixing bracket 100 and the rear seat 400 are connected to form an accommodating space in which the swing link 700 and the conductive member 800 are disposed. The rear seat 400 is used to isolate the conductive assembly 800, and a three-phase wire (not shown in the drawing) connected to a commercial power is connected to the conductive assembly 800 through the rear seat 400.

As shown in fig. 3 and 4, from the viewpoint of reducing the thickness of the dual control switch, the end surface of the key fixing bracket 100 close to the key 500 is provided with a first groove 101, and correspondingly, the end surface of the key 500 close to the key fixing bracket 100 is provided with a first protruding part 501, and the first protruding part 501 is connected with the first groove 101 in a matching manner, so that the distance between the key 500 and the swing link driving member 600 is shortened, which is beneficial to reducing the thickness of the dual control switch. Four rotating parts 102 arranged in a straight line are arranged in the middle of the end surface of the key 500 close to the key fixing support 100, and arc-shaped slots are arranged on the rotating parts 102, and for convenience of description, the arrangement direction of the four rotating parts 102 is hereinafter referred to as the x-axis direction. The middle of the end surface of the key 500 close to the key fixing support 100 is provided with four arc blocks 502 arranged along the x-axis direction, and the curved arc surfaces of the arc blocks 502 face the key fixing support 100. The arc piece 502 is connected with the arc clamping groove of the rotating part 102 in a clamping mode, the arc piece 502 and the rotating part 102 form a first fulcrum part, the arc piece 502 has the effect similar to a rotating shaft, and the two ends of the key 500 can rotate by taking the first fulcrum part as the circle center. Both ends of the first protruding portion 501 are provided with pressing blocks 503 along the x-axis direction, correspondingly, both ends of the groove bottom surface of the first groove 101 are provided with first through holes 103 along the x-axis direction, the first through holes 103 penetrate through the key fixing bracket 100, and the pressing blocks 503 can penetrate through the corresponding first through holes 103 to contact with the swing rod driving member 600. The middle part of the end face of the key fixing bracket 100 away from the key 500 is provided with two fixing parts 104 along the x-axis direction, a gap exists between the two fixing parts 104, and the fixing parts 104 are provided with mounting holes 105.

As shown in fig. 3, the end surface of the key fixing bracket 100 away from the key 500 is a groove structure, and two opposite inner side walls of the groove structure are provided with protruding first engaging blocks 106. The front end face of the connecting bracket 300 enters from the notch of the groove structure and is connected with the key fixing bracket 100 in a clamping way.

As shown in fig. 5a, a first concave engaging groove 301 is formed on a sidewall of the connecting bracket 300, and the first engaging groove 301 is engaged with the first engaging block 106. The middle part of linking bridge 300 is provided with hole 302, and hole 302 runs through linking bridge 300's preceding terminal surface and rear end to be provided with bellied barrier layer 303 around this hole 302's of orifice circumference at the rear end of linking bridge 300, be provided with first block hole 304 on the barrier layer 303, first block hole 304 runs through barrier layer 303. The outer side wall of the mounting bracket 200 is provided with a second snap-fit block 201, the mounting bracket 200 enters the hole 302 and the second snap-fit block 201 and the first snap-fit hole 304 are snap-fit connected.

As shown in fig. 5a, the end surface of the mounting bracket 200 away from the connecting bracket 300 is provided with a third engaging block 204. The outer side wall of the bottom of the mounting bracket 200 near one end of the base 400 is provided with a protruding fixing block 205. After the mounting bracket 200 and the connecting bracket 300 are clamped and connected, the fixing block 205 is contacted with the bottom of the connecting bracket 300, and the fixing block 205 and the second clamping block 201 clamp the connecting bracket 300.

As shown in fig. 5b and fig. 6, a second groove 202 is formed on the mounting bracket 200, and the second groove 202 is used for disposing the swing link driving element 600. The inner side walls of both ends of the second groove 202 are provided with limiting holes 203, and the limiting holes 203 function to limit and guide the rotation path of the swing rod driving member 600. The specific shape of the second recess 202 and the pendulum drive 600 match each other. The two fixing portions 104 are inserted into the second recess 202 through the holes 302 and are respectively located at two sides of the middle portion of the swing link driving member 600, the fixing portions 104 are hinged to the middle portion of the swing link driving member 600, and more specifically, a rotating shaft (not shown) is used to penetrate through the middle portion of the swing link driving member 600 and the two mounting holes 105.

The pressing piece 503 rotates with the rotation of the key 500. The pressing block 503 penetrates the first through hole 103 and the hole 302 in sequence and is in contact with the swing link driving member 600.

As shown in fig. 7a and 7b, the rocker driving element 600 includes two transition pieces 601, and the two transition pieces 601 are symmetrically distributed and symmetrically arranged along the length direction of the key 500, that is, one transition piece 601 corresponds to one end of the key 500, and the pressing block 503 at each end of the key 500 is correspondingly contacted with one transition piece 601, and the pressing block 503 can directly act on the corresponding transition piece 601. When any one of the two ends of the button 500 is pressed, the pressing block 503 can apply pressure to the corresponding transition piece 601, and the transition piece can rotate by using the middle of the swing rod driving piece 600 as a circle center, so that the swing rod driving piece 600 can rotate. The swing link driving member 600 further includes two push rods 602, the two push rods 602 are respectively disposed on the end surface of the transition piece 601 far away from the pressing block 503, and one end of the push rod 602 far away from the transition piece penetrates through the mounting bracket 200 and is disposed on two sides of the swing link 700. The end of the push rod 602 away from the transition piece is provided with a convex arc toward the swing link 700, for example, the convex arc includes but is not limited to: circular arc, elliptical arc, etc. The rotation of the transition piece 601 drives one of the push rods 602 to move towards the swing rod 700, and the other push rod 602 moves away from the swing rod 700. The two sides of the transition piece 601 are provided with protruding guide blocks 603, the guide blocks 603 are connected with the limiting holes 203, and in the rotating process of the transition piece 601, the guide blocks 603 can move along the preset path of the limiting holes 203. The shape of the limiting hole 203 is related to the preset path.

As shown in fig. 7a, 7b, 9a and 9b, one end of the swing link 700 is hingedly connected to the middle of the swing link driver 600, and more particularly, a rotation shaft (not shown) is used to penetrate through the middle of the swing link driver 600, the two mounting holes 105 and the swing link 700. Therefore, the other end of the swing rod 700 can rotate around the hinged joint, one end of the swing rod 700, which is far away from the swing rod driving element 600, is connected with a trigger plate 902 through an elastic part 901, and the trigger plate 902 is made of conductive metal. The trigger plate 902 is disposed obliquely, and two first contacts 903 are disposed on two end surfaces of the trigger plate 902. When any end of the button 500 is pressed, the transition piece 601 can rotate around the middle of the swing link driving piece 600, so that the rotating push rod 602 pushes the swing link 700, the swing link 700 drives the trigger plate 902 to rotate through the elastic portion 901 to generate a corresponding action, and the elastic portion 901 generates tensile deformation. The conductive assembly 800 is made of conductive metal, the conductive assembly 800 comprises a first terminal 801, a second terminal 802 and a third terminal 803, the first terminal 801, the second terminal 802 and the third terminal 803 are all in a threaded hole structure, and a lead is fixed by screws after being placed into the threaded hole. The conductive assembly 800 further includes a fixing plate 804, a second contact 805, and a third contact 806, wherein the fixing plate 804, and the second contact 806 are connected to the first terminal 801, and the third contact 806 is connected to the second terminal 802. The fixed plate 804 is horizontally arranged and located below the trigger plate 902, the bottom of the trigger plate 902 is in contact with the fixed plate 804 to form a second fulcrum portion, the trigger plate 902 is arranged between the second contact 805 and the third contact 806, and the first contact 903 on the trigger plate 902 is in contact with the second contact 805 or the third contact 806 by rotating the trigger plate 902 around the second fulcrum portion. When the first contact 903 and the third contact 806 are in contact, the double control switch is in a switch-on state; when the first contact 903 and the second contact 805 are in contact, the on-off switch is in an off state. The elastic portion 901 is a spring, and in a compressed state of the elastic portion 901, the elastic portion 901 applies pressure to the obliquely arranged trigger plate 902, so that the elastic portion 901 and the fixed plate 804 clamp the trigger plate 902, so that the bottom of the trigger plate 902 is in close contact with the fixed plate 804 and forms a second fulcrum portion.

As shown in fig. 7a, the transition piece 601 of the rocker driver 600 requires a larger surface area to ensure accurate contact between the transition piece 601 and the pressing block 503 than the middle of the rocker driver 600, and the rocker driver 600 is designed to have a structure with two large ends and a thin middle from the viewpoint of improving the convenience of mounting the rocker driver 600 on the mounting bracket 200.

As shown in fig. 8, a second engaging hole 401 is provided on a side wall of the top of the rear seat 400, the second engaging hole 401 penetrates through the side wall of the rear seat 400, and the rear seat 400 is engaged with the third engaging block 204 through the second engaging hole 401, thereby achieving connection with the mounting bracket 200. Wiring holes 402 are formed in the side wall of the bottom of the rear base 400, the wiring holes 402 penetrate through the side wall of the rear base 400, and the three wiring holes 402 correspond to a first terminal 801, a second terminal 802 and a third terminal 803 respectively. The lead wire is connected to the first terminal 801, the second terminal 802, or the third terminal 803 through the wiring hole 402, and is fixed by a screw through the wiring hole 402. The rear seat 400 is a slot structure, and three accommodation spaces are divided in the rear seat 400 for accommodating the first terminal 801, the second terminal 802 and the third terminal 803 respectively.

As shown in fig. 9a and 9b, the pressing motion of the button 500 is converted into the rotation of the transition piece 601, the rotation of the transition piece 601 is converted into the pushing of the push rod 602 to the swing link 700, the rotation of the swing link 700 is converted into the rotation of the trigger plate 902, and the on-off conversion of the dual-control switch is realized through the process. In this process, a small stroke pressing motion of the button 500 can be converted into a large stroke motion of the swing link driving member 600. The conversion from the small stroke to the large stroke is beneficial to reducing the installation height of the key 500 and the development of the double-control switch in a light and thin way.

The pressing force from the button 500 can be rapidly and accurately transmitted to the swing rod driving element 600 to drive the transition piece 601 to rotate, but since the on-off of the double-control switch is finally triggered by the trigger plate 902 rotating around the second fulcrum, the rotating angle of the transition piece 601 does not need to be too large, the depth of the hole 302 can be correspondingly reduced, and the double-control switch is favorably developed in a light and thin manner.

The push rod 602 pushes the swing rod 700 to drive the rotating structure of the trigger plate 902, so that the accommodating space of the rear seat 400 can be reasonably utilized, and the light and thin development of the double-control switch is facilitated.

Further, the swing rod 700 drives the trigger plate 902 to rotate through the elastic part 901, and the contact conversion between the first contact 903 and the second contact 805 and the contact conversion between the first contact and the third contact 806 are switched, so that the on-off triggering of the dual-control switch is more accurate and efficient. The first contact 903 is arranged between the second contact 805 and the third contact 806, improving the on-off triggering effect.

In the dual control switch provided in the embodiment of the present application, the elastic portion 901 may be designed in various structural forms as long as the compression direction of the elastic portion 901 is along the length direction of the swing link 700. The swing rod driving piece 600 related to the embodiment of the application is manufactured in an integrated forming mode, is of an integrated structure, is convenient to assemble, simplifies the assembling process of the double-control switch, and further enables the swing rod driving piece 600 to have a long service life. The rocker arm drive 600 may be made of, for example, a Polycarbonate (PC) material, which has high strength and high flexibility. The width of the transition piece 601 of the swing link driving member 600 is greater than the width of the middle portion of the swing link driving member 600, so that the contact area between the button 500 and the swing link driving member 600 is increased, and the transmission of the pressing force by the swing link driving member 600 is more flexible, smooth and efficient.

In the dual-control switch provided by this embodiment, when the button 500 is pressed to rotate one end by 1.8 °, the transition piece 601 of the corresponding swing link driving element 600 rotates by 1.8 °, and meanwhile, the corresponding push rod 602 moves laterally by 0.7mm, so as to drive the swing link 700 to rotate by 7 ° to implement on-off switching.

The fixed part all adopts the block connection in the double control switch that this application embodiment provided, and the mode of block connection has the strong and advantage of the dismouting of being convenient for of fastening. In addition, the connection structure of the fixing part in the double-control switch provided by the embodiment of the application is favorable for reducing the thickness of the double-control switch while maintaining the connection strength, so that the development of thinning and lightening of the double-control switch is facilitated.

In summary, the double control switch provided in the embodiment of the present application can realize the conversion from a small stroke to a large stroke, which is beneficial to reducing the thickness of the double control switch, making the double control switch thinner and lighter, and improving the aesthetic property of the double control switch. In addition, compared with the double-control switch provided by the related technology, the double-control switch provided by the embodiment of the application reduces the use of parts, simplifies the internal structure arrangement, is convenient to disassemble, increases the good feeling of user experience, and effectively improves the product competitiveness.

The technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above-mentioned embodiments only express several implementation modes of the present application, and the description thereof is specific and detailed, but not construed as limiting the scope of the claims. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the concept of the present application, which falls within the scope of protection of the present application. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims (7)

1. A double control switch, the double control switch includes a movable part and a fixed part, characterized in that:

the fixed part comprises a key fixing support, a mounting support, a connecting support and a rear seat;

the movable part comprises a key, a swing rod driving part, a swing rod and a conductive component;

the key fixing support is arranged between the key and the connecting support, the mounting support is arranged between the connecting support and the rear seat, the swing rod driving piece is arranged on the end face, close to the connecting support, of the mounting support, and the swing rod and the conductive assembly are both arranged in an accommodating space formed by the mounting support and the rear seat;

the button is movably connected with the swing rod in a driving mode, the swing rod driving part is movably connected with the swing rod, and the swing rod is movably connected with the conductive assembly.

2. The on-off switch of claim 1, wherein: the end face, away from the key, of the key fixing support is provided with a groove, the connecting support enters the groove from a notch of the groove, and the outer side wall of the connecting support is connected with the inner side wall of the groove in a clamping mode.

3. The on-off switch of claim 2, wherein: the middle of the connecting support is provided with a hole, the hole penetrates through the front end face and the rear end face of the connecting support, a protruding barrier layer is arranged on the rear end face of the connecting support in a circumferential mode around an orifice of the hole, and the outer side wall of the mounting support is connected with the barrier layer in a clamping mode.

4. The on-off switch of claim 3, wherein: the end face, far away from the connecting support, of the mounting support is provided with a clamping block, the side wall of the rear seat is provided with a clamping hole, and the clamping block is connected with the clamping hole in a clamping mode.

5. The on-off switch of claim 4, wherein: the button with the preceding terminal surface of button fixed bolster is connected, the middle part of button with the button fixed bolster is connected and this junction constitutes first fulcrum portion, the both ends of button can use first fulcrum portion rotates as the centre of a circle, the button is connected be provided with the briquetting on the both ends of the terminal surface of button fixed bolster respectively, the briquetting runs through in proper order button fixed bolster with the hole and with the contact of pendulum rod driving piece.

6. The on-off switch of claim 5, wherein: the swing rod driving part comprises two transition parts and two push rods, the two transition parts are symmetrically distributed and symmetrically arranged along the length direction of the button, the transition parts can rotate by taking the middle of the swing rod driving part as a circle center, the two push rods are respectively arranged at the two end faces, far away from the pressing block, of the transition parts, and one ends, far away from the transition parts, of the push rods penetrate through the mounting support and are arranged on two sides of the swing rod.

7. The on-off switch of claim 6, wherein:

one end of the oscillating rod is hinged with the middle part of the oscillating rod driving piece, one end of the oscillating rod, which is far away from the oscillating rod driving piece, is connected with a trigger plate through an elastic part, and two first contacts are respectively arranged on two end faces of the trigger plate;

the conductive assembly comprises a first wiring end, a second wiring end, a third wiring end, a fixing plate, a second contact and a third contact, the fixing plate and the second contact are connected with the first wiring end, the third contact is connected with the second wiring end, the fixing plate is located below the trigger plate, the bottom of the trigger plate is in contact with the fixing plate to form a second fulcrum portion, the first contact is arranged between the second contact and the third contact, the trigger plate rotates by taking the second fulcrum portion as a circle center, and the first contact on the trigger plate is in contact with the second contact or the third contact.

Images