KR20070116796A - Push-button operated rocker switch - Google Patents

Abstract

The electrical switch includes a push-button, a rocker switching mechanism having a rocker member, elastic pressing means, and drive converting means for converting an operation of the push button into an operation suitable for changing an operation mode of the rocker switching mechanism, wherein the elastic pressing member includes: It provides an elastic resistance against the movement of the push button toward the rocker member and provides an additional elastic resistance that reduces the differential force required to overcome the inertia of the rocker member.

Description

Push-button rocker switch {PUSH-BUTTON OPERATED ROCKER SWITCH}

The present invention relates to an electrical switch, in particular a push-button type electrical switch. More specifically, the present invention relates to a push-button switch comprising a rocker switching mechanism.

Electrical switches are essential unless they are unnecessary for electrical applications such as electrical appliances, electrical equipment and electrical equipment. Of the various types of switches known, push-button switches and rocker switches are the most widely used. The rocker switch typically includes a rocker member that can be toggled between at least two optional stable operating positions corresponding to different optional operating modes. Push-button switches typically include push-buttons that are driven linearly by a sequential linear movement, such as, for example, after a push-button is released.

Push-button driven switches that include a rocker type switching mechanism are already known. However, the actuation force characteristic of the known push-button driven rocker switches is not satisfactory due to the inherent driving force characteristics. For example, a spring biased rocker member generally integrated with a rocker switch, as can be seen from FIG. 1A, which shows a characteristic drive force diagram of a conventional rocker switch such as that shown in FIG. 1. A stepped driving force is applied to overcome the inertia of. The user will feel the resistance that appears as the reaction force of the driving force. This resistance disappears long before the rocker switch is moved to the next stable operating mode by the spring deflection inherent to the rocker switch.

Push-button driven switches are also known which have a rocker switching mechanism as the switching core. In this specification, such switches will be referred to as "push-button drive rocker switches" for convenience. Conventional push-button driven rocker switches include spring biased actuation push buttons such that the push button returns to a spring neutral position after each actuation push. The push button is typically designed to meet the rocker member after moving a predetermined distance towards the rocker.

When the operation mode of a conventional push button actuated rocker switch is changed, the user must press the push-button until the rocker switch is toggled. In general, the initial push is light and soft and the initial resistive force felt by the user is the incremental resistive force of the deflection spring. After the push button has moved a certain distance, the push button meets the rocker and the inertia of the rocker must be overcome in order for the rocker to be driven in the next mode of operation. Thus, when the push button and the rocker meet, the user will feel a sudden increase in resistance. The resistance by the rocker will gradually decrease and disappear when the rocker reaches the critical threshold position past the position where the rocker automatically moves to the next mode of operation without additional or additional toggle force.

Such sudden increase in resistance or stepped increase in resistance gives users a rough feeling they do not like. It is therefore desirable to provide a switch with reduced roughness described above. Since most switches are fixed on standard or predetermined size fixtures such as sockets or wallboards, additionally, if the switches with a compact working feel have a compact form so that the improved switches can be fixed on existing or standard fixtures Will help. However, the push button is typically a linear mover that can move along a longitudinal axis that is substantially perpendicular to the pivot axis of the rocker member, whereas the rocker switch operates by toggling the rocker member around the pivot axis. It is desired to provide an interface means or mechanism between the push button and the rocker switch while maintaining.

Preferred embodiments of the present invention will be described in more detail below with reference to embodiments and the accompanying drawings.

1 is a cross-sectional view showing the internal structure of a conventional rocker switching mechanism that receives an actuation force (F _N ).

FIG. 1A is a force-displacement diagram illustrating the driving force required to toggle the driving force downward to toggle the rocker switching mechanism of FIG. 1 to the next mode of operation.

Fig. 2 is an exploded view showing an important part of the electric switch of the first preferred embodiment of the present invention.

2A is an enlarged perspective view of a first embodiment of a suitable elastic pressing member for use in the preferred embodiment of FIG.

2B shows a second embodiment of a suitable elastic pressing member.

2C shows a third embodiment of a suitable elastic pressing member.

2D shows a fourth embodiment of a suitable elastic pressing member.

3 is a cross-sectional view of the switch of FIG. 2 assembled so that the push-button receives the driving force F ₁ in the operating mode of the zero-displacement position d ₀ .

3A is a perspective view of the switch of FIG. 3.

FIG. 4 shows the switch of FIG. 3 with the push-button displaced downwardly from the zero-displacement position by a distance d ₁ , in which the drive head of the pendulum drive member is in contact with the protruding arm of the membrane rocker member; 4A is a perspective view of the switch of FIG. 4.

FIG. 5 shows the switch of FIG. 3 with the push-button in displacement d ₂ , in which the drive member reaches a position where it encounters a second return resistance from the elastic pressing member, but still with the protruding arm of the rocker member; 5A is a perspective view of FIG. 5.

FIG. 6 shows the switch of FIG. 3 with the push-button in displacement d ₂ + δ where the rocker member is just starting to rotate to the next mode of operation without an externally applied driving force, FIG. 6A 6 is a perspective view.

FIG. 7 shows the switch of FIG. 3 with the push-button in displacement d ₃ , in which the rocker member is at a position half the distance to the next mode of operation and FIG. 7A is a perspective view of FIG. 7.

FIG. 8 shows the switch of FIG. 3 with the push-button in displacement d ₄ , in which the rocker member reaches the next mode of operation, and FIG. 8A is a perspective view of FIG. 8.

9 shows the switch of FIG. 3 with the rocker switch in the second mode of operation and the push-button returning to the zero displacement position.

10A is a force-displacement diagram of a conventional push button rocker switch showing the driving force exerted over the entire moving area of the push-button.

FIG. 10B is a force-displacement diagram showing exemplary force-distance characteristics by the first spring pressing means of the elastic pressing member of FIG. 2A.

10C is a force-displacement diagram showing exemplary force-distance characteristics by the second spring pressing means of the elastic pressing member of FIG. 2A.

10D is an exemplary force-displacement diagram showing the combined force of the driving force of the switch and the angular resistance of the spring pressing means of the rocker member and the elastic pressing member according to the present invention.

Fig. 11 is an exploded view showing a switch of the second preferred embodiment of the present invention.

12 is a cross-sectional view of the switch of FIG. 11 with the contactor actuating member in the initial stable position and the push button in the spring neutral position.

FIG. 13 shows the switch of FIG. 12 with the contactor actuating member moved to a position where the drive member rotates to a position acting on the rocker member of the rocker switch.

FIG. 14 shows the switch of FIG. 13 in which the contactor actuating member has moved to a position at which the drive member rotates to a position acting by the elastic return force by the second elastic urging means of the spring urging member.

FIG. 15 shows the switch of FIG. 13 in which the rocker member is rotated to the next mode of operation by the drive member being in downward motion of the push button contactor actuating member.

FIG. 16 shows the switch of FIG. 15 with the push button returned to the neutral position of FIG. 12 but the rocker member toggled to the next operating position.

It is therefore an object of the present invention to provide a push-button driven rocker switching mechanism, in particular a push-button driven rocker switch having resistive properties which alleviates the drawbacks of conventional designs. It is an auxiliary object of the present invention to provide a drive interface means or mechanism for operating a rocker switch by a push button. It is at least an object of the present invention to provide the public with a useful electrical switch with a push-button driven rocker switching mechanism.

Broadly speaking, the present invention teaches a push-button drive rocker switch that includes drive conversion means for converting a push-button action into a reciprocating action driving a rocker switching mechanism, and having improved resistance characteristics.

Accordingly, drive conversion means for converting the operation of the push-button, the rocker switching mechanism having the rocker member, the resilient urging means, and the push button into an operation suitable for the operation mode conversion of the rocker switching mechanism. in the electrical switch comprising a switch mode of the rocker switching mechanism, by means of drive conversion means acting as an interface between the push-button and the rocker member and responding to the operation of the push button; An elastic pressing member is disposed between the push-button and the rocker switching mechanism to provide an elastic resistance to the rocker member against the movement of the push button, the push button to return to a spring neutral or zero displacement position, and the drive converting means Rocker section to provide additional elastic resistance to the rocker member to cause switch action Of the difference between the driving force required to overcome the inertia, provides an electrical switch characterized in that the reduction (differential actuation force).

The elastic pressing means acts to help the rocker member to reduce the apparent height of the step of the driving force necessary to overcome the inertia of the rocker switching mechanism in order to toggle. The elastic pressing means facilitate this by gradually increasing the resistive force before contacting the rocker member.

Preferably, the resilient resistive force exerted on the push button by the elastic pressing means when the push-button moves toward the rocker member at a zero displacement position is incremental and the push button is The increase rate of the elastic resistance force is large when it is close to the rocker member, and the increase rate of the elastic resistance force is small when the push button is close to the zero displacement position. The two-stage elastic resistance provides the user with useful guidance or feedback as to how close the push button is to the toggle position.

Preferably, the additional elastic resistive force of the elastic pressing means acts to return the drive conversion means towards a neutral position away from the position at which the switching mode of the rocker switching mechanism is toggled.

Preferably, the additional elastic resistance is positive before the push button moves toward the rocker member and the drive converting means abuts against the rocker member, and after the drive converting means abuts on the rocker member and the inertia of the rocker member is overcome. After it is elastic, the elastic resistance is negative. Once the inertia is played out, the feeling of real resistance is no longer important for most practical purposes, so this negative force helps the drive changer and push button return to the zero displacement position. do.

Preferably, the elastic resistivity is negative and decremental after the rocker inertia is overcome but before the rocker member is driven to a position where switching mode changeover occurs without additional external driving force.

In a preferred embodiment, the drive converting means comprises a pendulum member that pivots around the pivot axis, the pendulum member pivoting about the pivot axis between positions to which the switching mode of the rocker switching mechanism switches. It includes a drive head. When the push button is in the spring neutral position, the pendulum member is in the pivot neutral position. In the pivot neutral position, the pendulum member is in an intermediate position where the rocker switching mechanism toggles.

Preferably, the pivot axis of the pendulum member is substantially perpendicular to the direction of operation of the push button.

In a preferred embodiment, the elastic pressing means comprises primary resilient urging means and secondary resilient urging means, wherein the primary elastic pressing means moves the push button to a spring neutral position or zero displacement position. The negative elastic pressing means returns the drive converting means in a pivoting manner toward the neutral position, which is an intermediate position where the switching mode of the rocker switching mechanism is changed by the drive converting means.

Preferably, the secondary resilient pressing means moves the push-button by a predetermined displacement from the neutral position towards the toggle position, which is a position where no additional external force is required to change the operating mode of the rocker switching mechanism. An action is provided to provide additional elastic resistance to the push button before contacting the rocker member.

Preferably, the pressing resistance towards the rocker member for the operation of the push-button is incremental after no additional force is required to change the operating mode of the rocker switching mechanism.

Preferably, the elastic urging means comprises a first spring urging means and a second spring urging means, the first spring urging means operating to return the push button to the zero displacement position, and the second spring urging means actuating the first spring urging means. One spring pressing means acted by a predetermined displacement relative to the push-button, but exerted a pressing resistance against the push-button before reaching the position where the operating mode of the rocker switching mechanism was switched.

Preferably, before the push-button is moving towards the position at which the operating mode of the rocker switching mechanism is switched, but before contacting the resistance of the rocker switching mechanism, the first spring pressing means and the second spring pressing means are applied to the push-button. Provide incremental resistance.

Preferably, the resistive force of the first spring pressing means is reactive of the driving force applied to the push-button and is substantially parallel to the direction of the driving force, and the resistive force of the second spring pressing means is acute with respect to the driving force applied. .

In a preferred embodiment, the first spring urging means comprises a pair of elastically deformable legs which are arranged substantially symmetrically about the axis of the push-button, said legs resisting the linear actuation motion of the push-button. to provide.

Preferably, the second spring pressing means is elastically deformed away from the rocker member of the rocker switching mechanism after the drive conversion means is in contact with the rocker member, and the second spring after the push-button has moved by a predetermined displacement toward the rocker member. The elastic deformation of the urging means operates to hinder the swinging motion of the drive conversion means.

Preferably, the drive conversion means comprises a pendulum member having a pendulum-like drive member or pivoted end and a pivoting end, the pivotal end of the drive member being relatively relative to the pivotable end. Pivoting, the pivotal end of the drive member and the rocker member of the rocker switching mechanism are configured to cooperate with each other such that the pivotal end of the drive member moves toward the rocker member in response to the actuation of the push-button so that the pivotal end operates The rocker member is driven towards a position where the operating mode of the rocker switching mechanism is switched so that it can rotate toward the position.

Preferably, the rocker member is pivotally moved about the rocker axis, the rocker member comprising a pair of protruding arms symmetrical about the rocker axis, and the pendulum drive member is a pair symmetrical about the pivotal end. And a protruding arms of the rocker member, wherein the protruding arms of the rocker member are selectively driven by corresponding drive heads to toggle the mode of operation of the rocker switching mechanism.

A typical rocker switch 100 is shown in FIG. The rocker switch includes a rocker member 110 and a switching mechanism. The rocker member is of a configuration and arrangement in which the movable electrical contactor of the switching mechanism can be driven to at least one first operating position and one second operating position so that a first selective connection and a second selective connection are formed. . Of course, the rocker switch may have more than two modes of operation. The rocker member 110 is mounted to pivot around the rocker axis 130, and once the rocker member is moved to the critical threshold position, the inner spring deflection causes the rocker member to move to the next mode of operation without additional external forces applied. Internal springs are deflected to ensure After the rocker member moves to the operating mode, the operating mode remains as long as it is not further toggled.

1A shows a typical drive force-displacement diagram of a conventional rocker switch. As shown in the figure, the maximum driving force occurs when the driving force is initially applied to overcome the inertia of the spring biased rocker member of the rocker switch. This maximum driving force is necessary to cause the rocker member to rotate in a pivotal manner from the neutral position to the toggle position where the operating mode of the rocker switch is switched, or to cause an initial movement around the rocker shaft. The next subsequent force that completes the conversion of the rocker member or toggle mode or mode of operation is gradually reduced and becomes negligible when the critical threshold position is reached. Once the critical threshold position is reached, the inner spring deflection of the rocker member is taken over to complete the toggling, and no further external force is required for the rocker member to completely change its operating position. As shown in the force diagram, the force F _N represents the characteristic minimum vertical driving force required to move the push-button downwards by the distance D.

Electrical switches including push-button driven rocker switching mechanisms are already known. The switches typically comprise a push-button, a rocker switching mechanism and drive conversion means for connecting the rocker members of the push-button and the rocker switching mechanism to each other. The drive converting means also converts the linear movement of the push-button into a rotational or swinging movement in order to drive the rocker member to various operating positions. In the conventional push button rocker switch, the resistance force felt or touched by the user while the operation mode of the switch is changed is generally as shown in FIG. 10A. A rapid increase or a stepwise increase in resistance upon initial contact with the rocker is evident from FIG. 10A.

In the force diagram of FIG. 10A, the total displacement area of the push-button of the electrical switch of FIG. 9 is represented by 0 to d ₄ . Position (0) and position (d ₄ ) correspond to the zero displacement and the maximum displacement of the push-button, respectively. The positions may also be expressed as rest positions and fully depressed positions, respectively. As is apparent from the force diagram, when the user presses the push-button 210 toward the rocker member to change the mode of operation, the user gradually increases until the push-button moves by a predetermined distance d ₁ . You can feel the resistance. In this position d ₁ , the drive converting means is in contact with the rocker member and the resistance inertia of the rocker is overcome when the rocker member is moved to the next stable operating position. This overcoming inertial force is a sudden stepped shape as shown in d ₂ of FIG. 10A. As a result, the user will experience a sudden or stepwise increase in resistance. Between the displacement position d ₂ and the displacement position d ₃ , the resistivity will gradually decrease and become a positive slope again (in other words, incremental) at the displacement position d ₃ passing through the critical threshold position. . This is because at ₃ d the deflection spring takes over and the restoring force appears as the push button recovers to its neutral position. The deflection spring force appears until the push-button completes the entire displacement area at position d ₄ .

In the following description, unless otherwise required, common reference numerals are used to refer to common or equivalent members.

2 to 9 a first preferred embodiment of a push button rocker switch 10 is shown. The electrical switch 10 comprises a rocker switching mechanism 100, push-button means comprising a button interface cap 200, a resilient urging assembly 300, a drive conversion member 400. And a main housing 500. While various components within the switch of this embodiment are housed in the main housing 500 for convenient mounting and insulation, it should be understood that the switch may be mounted as part of one device or installation.

The rocker switch 100 can be of a conventional design such as, for example, the rocker switch of FIG. 1. Of course, other suitable rocker switches or new rocker switches may sometimes be used without losing universality. A rocker switch 100 similar to the rocker switch of FIG. 1 includes a rocker member 110 and a contactor driven rocker switching assembly. The contactor driven rocker switching assembly, or in short, the rocker switching mechanism, includes an electrical contact member 120 that easily operates a number of optional electrical circuit connections or breaks. The particular connection generally depends on the instantaneous stable position of the rocker member 110. For example, two or three optional circuit connections may be formed by one rocker switching mechanism.

The spring assembly is generally formed in a rocker switch. The spring assembly is provided for urging the electrical contact member of the rocker member to be held in that position once it has been moved to a stable operating position. The spring assembly also performs a dual function of moving the contactor member to the next operating position once the rocker member is moved to the critical threshold position. Typically, the spring assembly includes a coil spring 140 whose axis is substantially perpendicular to the rocker shaft 130 and assembled inside the hollow body of the rocker member. Of course, other elastic pressing means may be used for the same or equivalent purpose.

The rocker member 110 includes a rocker body 111 having a pair of rocker arms 112. The rocker arm 112 is disposed symmetrically with respect to the neutral pivot axis of the rocker body. The lateral end of each rocker arm protrudes upward from the rocker body and extends toward the push-button.

The push-button means comprise a push button member and a button interface cap 200. The button interface cap 200 includes a main body having a contact surface 210. The upper and lower sides of the contact surface 210 interact with the push button member to transmit the downward movement of the push button member to the rocker member. The main body of the button interface cap 200 provides a distributed contact surface for interacting with the elastic pressing assembly 300 as well as pivotal support for the pivoting operation of the drive conversion member to be described below. The main body of the button interface cap 200 and the main housing 500 of the switch together push the push-button into or out of the main housing along a predetermined direction, ie towards the rocker member during the mode changeover operation. Cooperative guide means are formed for allowing linear slide or linear slide away from the rocker member.

The elastic pressing means of this embodiment includes an elastic pressing assembly 300 disposed between the button interface cap 200 and the rocker member 110. The elastic pressing assembly comprises a first elastic means 320 and a second elastic means 330. The first elastic means 320 provides an elastic return-pressing force to return to the initial spring neutral or zero displacement position d ₀ from the position at which the push button or button interface cap was pressed after the push button or button interface cap was released. . The resilient pressing means is also adapted to provide a rocker switch that is introduced by an incremental resistive force to the movement of the push button while the push button moves toward the rocker member prior to contacting the rocker member during operation of the push button rocker switch. The driving force characteristic helps to reduce the suddenness and ruggedness that the user feels. By gradually increasing the resistance while the push button is moving toward the rocker member, the height of the resistance step, ie the sudden step at d ₁ , will be reduced and the user will feel a better "feel".

Therefore, the first elastic pressing means of the elastic pressing assembly 300 performs various objects in the present invention. Firstly, the first elastic pressing means provides an incremental resistance, for example a variable resistive force, to the operation of the push-button causing a change of the operating mode. Specifically, resistance is shown that allows the user to feel resistance substantially along the entire displacement area of the push-button. Secondly, the first elastic pressing means provides an elastic spring deflection which causes the push-button to return to the zero displacement position when the push-button is released. Thirdly, the first elastic pressing means provides additional incremental resistance to narrow the step gap of the rocker drive force to be described below. Examples of suitable elastic pressing assemblies are shown in FIGS. 2A, 2B, 2C, and 2D. Of course, other suitable forms of elastic pressing assemblies may be employed without losing universality. It is also to be understood that although the assembly is disclosed in the specification, the terminology has been used for convenience only. Of course, the elastic pressing assembly may be formed as a single unit or distributed means.

The second elastic pressing means 330 provides additional elastic resistance to the push button when the push button moves toward the rocker member before contacting the rocker member. The resistive force is incremental to reduce the step-height of the additional or differential actuation force required to overcome the inertia of the rocker member.

Drive conversion means comprising a button interface cap 200 and drive conversion means comprising a drive conversion member 400 for converting the linear motion of the push button into a rotational or pivoting drive motion in order to benefit from additional incremental resistance while maintaining a compact design. It is arranged between the rocker members 100.

As shown in FIG. 2A, an example of an elastic pressing assembly 300 includes a platform member 310 and a pair of spring members 320. The pair of spring members are disposed at both side surfaces of the lower side of the platform member. Each spring member is a coil spring with a spring axis substantially parallel to the direction of the driving force so that the coil spring is compressed when the push button is pressed. When the push button is released, the energy accumulated in the spring member provides a return spring force for the push button to return to the spring zero position. Of course, the spring member may be selected to extend instead of being compressed while the push button is in operation. FIG. 2B illustrates a variation of the elastic pressing assembly 300A with a single coil spring disposed centrally in place of the spring members disposed on both sides of FIG. 2A. The coil spring may be a rectangular cross section instead of the circular cross section shown. FIG. 2C shows another variation of the elastic pressing assembly 300B which replaces the spring of FIG. 2A with a pair of elastic legs branching from the metal board and symmetrical about the center of the metal board. 2D illustrates another embodiment of an elastic pressing assembly that includes a platform member and a pair of elastic legs. In the design, the platform member and the pair of elastic legs are separated to facilitate adjusting the spring forces of the two parts respectively to improve flexibility.

The elastic pressing assembly 300 provides additional spring means to provide additional incremental resistance to the push button during the operation mode change of the rocker switch in order to narrow the aforementioned resistance steps or differentials. Said further spring means are suitable for fulfilling the requirements of the above-mentioned second elastic reaction means, hereinafter referred to as secondary spring means for convenience. In this embodiment, the platform member 310 is made of an elastic material such as steel sheet, and is made of a thin metal board. The secondary spring means comprise a pair of spring arms 330 integrally formed with the metal board and overhang the metal board. As can be seen from FIG. 2A, the spring arm 330 is connected with the metal board at one of the longitudinal ends of the spring arm and extends toward the other longitudinal end of the metal board. The free ends of the pair of spring arms face each other and face each other. In other words, the pair of spring arms are substantially collinear and parallel to the longitudinal axis of the metal board.

The drive converting means is a pendulum-like drive converting member (shortly pendulum member) 400 suitable for converting the linear motion of the push button into a rotary motion or a pivoting motion to facilitate the conversion of the operating mode of the rocker switch. ). The pendulum-type drive conversion member 400 includes a main body 410 mounted to pivot over the housing of the button interface cap 200. At the distal end of the main body 410 distal from the pivot axis, a pair of slightly chamfered shoulder portions 420 are formed. The shoulders 420 are chamfered to incline the distal end of the main body from the centerline of the main body such that the outer edge of the main body is shorter than the center of the main body 410. The shoulders are laterally displaced from the centerline of the main body and are substantially symmetric about the pivot axis. This lateral symmetry facilitates the symmetrical operation of the rocker switch of the type shown in FIG. 1 having two modes of operation.

The operation of the push button type rocker switch of FIG. 2 will be described with reference to FIGS. 3 to 9. As shown in FIGS. 3 and 3A, the push button is initially in the zero displacement position or the spring neutral position d ₀ . When the driving force F is applied, it encounters a reaction force F ₂ (reactive force) by the main spring means, that is to say the spring member 320. 4 and 4A, the push button moves downward by a predetermined distance and is located at the displacement d ₁ . At this displacement, the front edge of the right shoulder of the pendulum drive conversion member 400 begins to move and contacts the corresponding protruding head of the rocker member. The rear side of the right shoulder of the drive conversion member also contacts the bottom of the spring arm 330.

Due to the outwardly sloped shoulders of the chamfered shoulders, the drive conversion member acts like a cam over the protruding head and begins to rotate counterclockwise around the pivot axis as the push button is pressed further. Since the back side of the shoulder of the drive conversion means is already in contact with the spring arm at the displacement position d1, further rotation of the conversion drive member will cause the spring member to be pushed further if the push button is pressed further from the displacement d1 to the displacement d2. Try to move away from the plane of the metal board. Since the spring member is hinged to the metal board, the free end of the spring arm 330 pivots around the junction between the spring arm 330 and the metal board.

As shown in FIGS. 5 and 5A, when the push button is in the displaced position d ₂ , the spring arm 330 pivots clockwise around the pivot connection by an angle α. Since the spring arm 330 is integrally integrated with the elastic metal board, when the spring arm is in the displaced position d ₂ , the elastic pressing force represented by the force arrow F ₁ will act on the spring arm. In this displacement position, the total resistive force or total counteracting force (F) felt by the user is the sum of the vertical components of the force F ₁ and the force F ₂ . In the present embodiment, the displacement position d ₂ is selected as the position at which the rocker member starts to receive the toggle force. Angular position α is also set to the maximum angle the spring arm can turn. This maximum angular position is set by limiting means which are arranged on the main housing of the push button, for example in the form of an inner ceiling which prevents further advancement of the spring member 330. In summary, the sources of driving and resistance forces are as follows;

(a) F, the driving force exerted on the pushbutton by the user,

(b) F ₂ , upward resistance force by the spring member 320 of the elastic pressing assembly,

(c) F ₁ , the force exerted on the spring arm when the spring arm is rotated by an angle α.

In FIG. 6 the push button moves further downward by an additional displacement δ and is located at the displacement d ₂ + δ, where δ is a very small value. In this displacement position, the push button is pressed with a suitable force applied to overcome the initial rotational inertia of the rocker member such that the rocker member starts to pivot around its axis. The resistive force represented by the force arrow F ₃ at the angle (γ) position relative to the vertical is driven by the pushbutton housing providing an additional threshold force to overcome the inertia of the rocker member. Is an additional force exerted over the rear edge of the shoulder. At this displacement, the total resistive force or total disturbance force F felt by the user is the sum of the vertical components of the forces F ₁ , F ₂ and F ₃ .

7 shows a push button positioned at the displacement d ₃ . At this displacement, the rocker member automatically reaches a critical threshold displacement to complete all the transitions of the toggle motion without requiring additional external force. The push button actuation mechanism is configured such that the push button moves further downward from the displacement position d ₃ to the lower dead end d ₄ . Additional free displacement areas (d ₃ to d ₄ in this embodiment) are provided to accommodate the amount of variation in the critical threshold displacement of the rocker member or to fit the tolerance of the rocker member properties over time. In this step, an elastic force by the spring arm 330 acts to cause the drive conversion member 400 to return to its initial zero displacement position again.

8 shows a push button located at the displacement d ₄ . At this displacement, the rocker member 110 terminates the operation mode change, and the spring arm 330 drives the drive changeover member clockwise again to return to its initial position.

In FIG. 9, after the push button is released, the push button is returned to the zero displacement position d ₀ by the spring member 330. In this displacement position, the rocker member ends the operation mode change and the spring arm 330 returns the drive change member back to the initial start position.

The overall resistance F felt by the user during the aforementioned operation mode conversion is shown in FIG. 10D. The force diagram of FIG. 10D shows three forces, an increment of force F ₂ , d ₁ and d ₂ , by the spring member 320 with increasing displacement between d ₀ and d ₄ as shown in FIG. 10B. And an additional force F ₃ exerted by the vertical component of the reaction force F _{1 applied} to the spring arm 330 held constant by the confinement device and the rear edge of the shoulder of the drive conversion member above the push-button housing. Is the sum of the vertical components. For simplicity, the force on the hinge is ignored. As shown in FIG. 10A, it can be seen that the height of the resistance step d ₁ is significantly reduced.

11-16, there is shown a second preferred embodiment of the electrical switch of the invention in the form of a switchable socket outlet comprising a push-button acting as a rocker switching mechanism. Since the main operating parts are generally similar, in the following description, similar, identical or equivalent parts to those of the first preferred embodiment described above are denoted by the same reference numerals for simplicity and convenience unless otherwise required in the specification.

Electrical switch 20, similar to switch 10 of the first preferred embodiment, comprises a rocker switching mechanism 100, a push-button comprising a button interface cap 200, an elastic pressing assembly 300, a drive conversion member 400. And a main housing 500. Similar to the first preferred embodiment, the elastic pressing assembly includes primary spring urging means and secondary spring urging means. The main elastic pressing means provides an incremental resistance equal to the amount of downward movement of the push button and is illustrated by a pair of spring members 330. The secondary spring pressing means comprises a pair of protruding spring arm members with a fixed end of each spring arm member disposed near the end of the lateral wing of the example spring-like metal board 310 and the free ends pointing towards each other. Illustrated as 330.

The switchable socket also includes a movable contact member and a stationary contact member, the connections of which are toggled by a rocker switching mechanism. 11 to 16 show the sequence of operation by moving the movable rocker member 110 from the first switch position to the second switch position by the push button. The operation sequence is substantially the same as described with reference to Figs. 2 to 9 and will not be repeated here.

Although the present invention has been described with reference to the above-described examples or preferred embodiments, the above embodiments are intended to aid the understanding of the present invention and should not be construed as limiting the present invention. The scope of the invention should be determined and / or inferred from the foregoing preferred embodiments with reference to the appropriate figures and description in the specification. In particular, it will be apparent to those skilled in the art that modifications or variations can be made within the scope and scope of the present invention.

In addition, while the present invention has been described with reference to standalone switches and wall-socket switches, it is to be understood that the present invention may be applied to other types of switches without losing their universality, either modified or unmodified. Also, the dimensions and displacements referred to are for comparison only and do not imply any limitations.

Claims (17)

-Push-button, A rocker switching mechanism having a rocker member, Elastic pressing means, and An electrical switch comprising drive conversion means for converting the operation of the push button into an operation suitable for the operation mode conversion of the rocker switching mechanism, The drive converting means can be switched between the push-button and the rocker member by means of drive converting means acting as an interface between the push-button and the rocker member, the switching mode of the rocker switching mechanism, the elastic pressing member being the push-button and the rocker Disposed between the switching mechanisms to provide an elastic resistance against the movement of the push button toward the rocker member, to cause the push button to return to the spring neutral or zero displacement position, and to provide additional elastic resistance to the drive conversion means to provide the rocker member And the differential actuation force required to overcome the inertia of the rocker member for causing the switching operation to be reduced. 2. The elastic resistance force of claim 1, wherein the elastic resistance exerted on the push button by the elastic pressing means when the push-button moves toward the rocker member in the zero displacement position is incremental, and the elastic resistance force when the push button is close to the rocker member. The increase rate of is large, the electrical switch characterized in that the increase rate of the elastic resistance force is small when the push button is close to the zero displacement position. 3. An electrical switch as claimed in claim 1 or 2, wherein the additional elastic resistive force of the elastic pressing means operates to return the drive conversion means towards a neutral position away from the position at which the switching mode of the rocker switching mechanism is toggled. . 4. The method of claim 3, wherein the additional elastic resistance is positive before the push button moves toward the rocker member and the drive conversion means contacts the rocker member, after the drive conversion means contacts the rocker member and the inertia of the rocker member. The electric switch is characterized in that the elastic resistivity is negative after this is overcome. 5. The electrical method of claim 4, wherein the inertia of the rocker is overcome, but the elastic resistance is negative and decremental before the rocker member is driven to the position where the switch mode change occurs without additional external driving force. switch. The method according to any one of the preceding claims, wherein the drive converting means includes a pendulum member pivoting about a pivot axis, the pendulum member pivoting about a pivot axis between positions to which the switch mode of the rocker switching mechanism switches. And an actuating drive head. 7. The electrical switch of claim 6, wherein the pivot axis of the pendulum member is substantially perpendicular to the direction of operation of the push button. An elastic pressing means according to any one of the preceding claims, wherein the elastic pressing means comprises a primary elastic pressing means and a secondary elastic pressing means, wherein the primary elastic pressing means returns the push button to the spring neutral position or the zero displacement position, and the secondary elastic pressing means. And the drive switching means returns in a pivoting manner toward the neutral position, which is an intermediate position where the switching mode of the rocker switching mechanism is switched by the drive switching means. 9. The drive elasticity of claim 8, wherein the negative elastic pressing means moves by a predetermined displacement toward the toggle position, where the push-button has moved from the neutral position to a position where no additional external force is required to change the operating mode of the rocker switching mechanism. The switch initiating an action of providing additional elastic resistance to the push button before contacting the rocker member. The method according to any one of the preceding claims, characterized in that the pressing resistance towards the rocker member with respect to the push-button operation after the additional force is not required to change the operating mode of the rocker switching mechanism is incremental. Electrical switch. 2. The method of claim 1 wherein the elastic urging means comprises a first spring urging means and a second spring urging means, the first spring urging means operative to return the push button to the zero displacement position, and the second spring urging means. And wherein the first spring pressing means acts a predetermined displacement with respect to the push-button, but applies a pressing resistance against the push-button before reaching the position where the operating mode of the rocker switching mechanism is switched. 12. The method of claim 11, wherein the push-button is moving toward a position where the operating mode of the rocker switching mechanism is switched but before contacting the resistance of the rocker switching mechanism, the first spring pressing means and the second spring pressing means are adapted to the push-button. An electrical switch providing incremental resistance to. 12. The driving force according to claim 11, wherein the resistance of the first spring pressing means is substantially parallel to the direction of the driving force in the reactive force of the driving force applied to the push-button, and the resistance of the second spring pressing means is applied to the driving force applied. An electric switch, characterized in that acute angle. 14. The method of claim 13, wherein the first spring pressing means comprises a pair of elastically deformable legs arranged substantially symmetrically about an axis of the push-button, the legs for the linear actuation operation of the push-button. An electrical switch, characterized by providing a resistance. 15. The method of claim 14, wherein the second spring pressing means is elastically deformed away from the rocker member of the rocker switching mechanism after the drive conversion means is in contact with the rocker member, and the push-button is moved after the predetermined displacement toward the rocker member. 2. An electrical switch, characterized in that the elastic deformation of the spring pressurizing means operates to hinder the swinging motion of the drive converting means. The drive conversion means according to claim 1, wherein the drive conversion means comprises a pendulum member having a pendulum drive member or pivoted end and a pivot end, the pivot end of the drive member being relative to the pivotal end. The pivoting end of the drive member and the rocker member of the rocker switching mechanism are configured to cooperate with each other to cause the pivotal end of the drive member to move toward the rocker member in response to the actuation of the push-button. And the rocker member is driven toward a position at which the operating mode of the rocker switching mechanism is switched so that it can rotate toward an operating position. 17. The rocker member of claim 16, wherein the rocker member is pivotally moved about the rocker axis, the rocker member comprising a pair of protruding arms symmetrical about the rocker axis, and the pendulum drive member is symmetrical about the pivotal end. A pair of drive heads, wherein the drive arms of the rocker members and the protruding arms of the rocker members are arranged such that the protruding arms of the rocker members are selectively driven by corresponding drive heads that toggle the operating mode of the rocker switching mechanism. An electric switch, characterized in that.