KR20220001135U - Ultra-thin switch structure that can adjust the activation depending on the degree of pressurization - Google Patents

Abstract

The present invention relates to an ultra-thin switch structure that can control whether or not it is active depending on the degree of pressure, and more particularly, by adding a non-conductive cushioning material having a restoring force in the form of an empty part of the surface between the lower metal plate and the upper metal plate. It was invented so that the activation of the corresponding switch can be adjusted according to the degree of pressure applied orthogonally.
The invention can be directed towards ultra-thin according to the material used, and the simple structure can also aim for low manufacturing cost. And because the switch function can be digested with only very minute movements, the user can not feel a sense of alienation.

Description

Ultra-thin switch structure that can adjust the activation depending on the degree of pressurization

The present invention relates to a switch structure, and more particularly, to an ultra-thin switch capable of controlling whether to activate or not according to the degree of pressure.

In general, in the case of switches (Tact, Slide, Push, Micro, Multiway, etc.) that we use frequently, there is a separate operating radius and it is operated through contact through pressure. However, the existence of a separate operating radius makes it difficult to make the thickness of the switch structure below a certain level, which also affects the thickness of the device using the switch.

In the past, it was attempted to reduce the thickness through reorganization of the coupling structure of the switch, but this also does not affect the separate operating radius included in the operating principle, and there is a problem that it is only a high-level measure because a separate reorganization is required for each switch used. .

Moreover, since the user could not control whether the switch is active according to the degree of pressurization of the conventional switch, accidental switching is also a problem.

As described above, an object of the present invention to solve the problem is to change the switch operation structure itself to reduce the operating radius of the conventional switch structure to aim for an ultra-thin structure, and the user can select whether to activate it according to the degree of pressure It is to provide a switch structure that can.

The ultra-thin switch device capable of controlling whether to activate or not according to the degree of pressurization of the present invention for achieving the above-described object requires a non-conductive buffer material having a restoring force in the form of a lower metal plate and an upper metal plate connected to an electrode, and a part of the surface is empty Including inner case according to

Here, one or each of the protrusions may exist on the lower metal plate and the upper metal plate depending on the application environment, and the lower metal plate and the upper metal plate come into contact with each other to cause switching.

In addition, the non-conductive cushioning material with restoring force in the form of an empty part of the surface is located between the lower metal plate and the upper metal plate. When the upper metal plate is raised through its original restoring force, the contact point between the lower metal plate and the upper metal plate is lost.

Here, the non-conductive cushioning material with restoring force in the form of an empty part of the surface can vary the thickness, material, number of layers, etc. according to the application environment, so that the user can set the desired degree of pressurization. And the above components can be included in the inner case as needed to minimize play.

On the other hand, in the ultra-thin switch method of the present invention for achieving the above-mentioned object, the activation or non-activation can be controlled according to the degree of pressurization of the present invention. metal plate) descends, the step of pressing the non-conductive cushioning material (hereafter cushioning material) with restoring force in the form of an empty part of the surface located between the lower metal plate and the upper metal plate due to the lowered upper metal plate, compression of the cushioning material This includes a step in which the protrusion of the upper metal plate contacts the lower metal plate, and a step in which the lower metal plate to which the electrode is connected and the upper metal plate come into contact with each other to generate switching.

In addition, when the external pressure applied in the direction perpendicular to the switch disappears, the step of restoring the thickness of the cushioning material compressed by the pressure by its original restoring force, the step of returning the upper metal plate to its original position due to the restoration of the cushioning material , It further includes a step in which the contact point between the projection of the upper metal plate and the lower metal plate is lost as the upper metal plate rises, and the switching is cut off due to the loss of contact between the two metal plates.

When a non-conductive cushioning material with restoring force in the form of a partially empty surface between the lower metal plate and the upper metal plate is compressed by pressure, the projection of the upper metal plate contacts the lower metal plate and switches.

This switch structure allows the user to set the desired minimum pressure according to the material, thickness, number of layers, etc. of the cushioning material existing between the lower metal plate and the upper metal plate. Accordingly, an ultra-thin switch can be provided.

In addition, the simple switch structure reduces the manufacturing cost, and the user does not feel a sense of heterogeneity in switching because switching can be performed only with very minute movements.

1 is a cross-sectional view according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in more detail with reference to the accompanying drawings. The features and advantages of the present invention will become more apparent from the following detailed description of preferred embodiments based on the accompanying drawings.

Prior to this, the terms or words used in the present specification and claims conform to the technical idea of the present invention based on the principle that the inventor can appropriately define the concept of the term in order to describe his invention in the best way should be interpreted as meanings and concepts that

In addition, it will be apparent to those of ordinary skill in the art that the present invention can be practiced without specific matters such as components of specific circuits in the following description.

In addition, since the present invention may include various changes and may include various embodiments, specific embodiments will be illustrated and described in the drawings. However, this is not intended to limit the present invention to specific embodiments, and it should be understood that all modifications and substitutions included in the spirit and scope of the present invention are included.

1 is a cross-sectional view according to an embodiment of the present invention.

In the present invention with reference to the accompanying drawings, a lower metal plate 2 is placed on the inner case 1, and a non-conductive cushioning material 3 having a restoring force in the form of a partially empty surface is placed thereon, and a certain amount is placed thereon. The upper metal plate 4 including the protrusion 5 of the height is configured to have a structure in which the high surface of the protrusion 5 is positioned downward.

Here, the projections 5 of a certain height included in the upper metal plate 4 may be included in the lower metal plate 2 depending on the environment, and in this case, the high surface of the projections should be positioned at the top. In addition, protrusions may be included in both the lower metal plate 2 and the upper metal plate 4 depending on the application environment, and the protrusions should be configured so that their high surfaces face each other.

In addition, the non-conductive cushioning material 3 having a restoring force in the form of a partially empty surface positioned between the upper metal plate 4 and the lower metal plate 2 may have different thickness, material, number of layers, etc. depending on the application environment. In addition, it may be configured without the inner case 1 depending on the application environment.

When the pressurizing object 6 presses the upper metal plate 4, the upper metal plate 4 descends to press the cushioning material 3, and the cushioning material 3 is compressed according to the pressurized level and included in the upper metal plate 4 The protrusion (5) is in contact with the lower metal plate (2), the switching occurs.

Afterwards, when the pressurization of the pressurized object 6 is finished, the cushioning material 3 is restored to its original shape according to the restoring force, and accordingly, the upper metal plate 4 rises and the projections 5 included in the upper metal plate 4 and The bonding of the lower metal plate 2 is stopped and the switching is also terminated.

1: inner case 2: lower metal plate
3: cushioning material 4: upper metal plate
5: Protrusion 6: Object that applies pressure

Claims (4)

A switch structure that contains a non-conductive cushioning material with restoring force in the form of an empty part of the surface between the lower metal plate and the upper metal plate including protrusions A switch structure containing a non-conductive cushioning material with restoring force in the form of a partially empty surface between the lower metal plate including the protrusion and the upper metal plate A switch structure that includes a non-conductive cushioning material with restoring force in the form of a partially empty surface between the lower metal plate including protrusions and the upper metal plate including protrusions The step of lowering the upper metal plate by external pressure; The step of contacting the upper metal plate and the lower metal plate due to the compression of the cushioning material due to the lower metal plate or the upper metal plate or the protrusions included in each metal plate, and the step of generating the switching by contacting the lower metal plate to which the electrode is connected and the upper metal plate.
In addition, when the pressure applied from the outside in a direction perpendicular to the switch disappears, the cushioning material compressed by pressure restores its thickness by its original restoring force, and the upper metal plate returns to its original position due to the restoration of the cushioning material. The method further includes a step in which the upper metal plate rises and the contact point between the upper metal plate and the lower metal plate is lost, and the switching is cut off due to the loss of contact between the two metal plates.

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