KR101884771B1 - Capacitive Touch Module Loading Improved Recognition Rate and Manufacturing Method for It - Google Patents

Abstract

According to the present invention, there is provided an electrostatic touch module having an improved recognition rate and a method of manufacturing the same. The electrostatic touch module includes a capacitive touch module, And is made of a specified number of touch parts made of a specified thickness T (T? 0.1 mm) or more and a nonconductive material having a restoring force against shrinkage due to external force, and the electrostatic touch screen And a nonconductive placement area that includes a non-conductive placement area in which the specified number of touch parts are placed or fixed in a designed geometric relationship or in a designed geometric relationship, and a geometric In contact with, or in contact with a specified number of touching portions that are stationary, And an adapter unit including a conductive placement area of a conductive material capable of forming an electric circuit by fixing and a conductive exposure area for exposing an electric circuit with the touch parts to the outside, Conductive plastic material or nonconductive paper material capable of accumulating static electricity by repetition or by friction, and the specified number of touch portions are arranged in a state in which the contact plate portion is not in contact with the electrostatic touch screen, And an electrical circuit is connected between the conductive arrangement region of the adapter unit and the human body and the electrostatic charge stored in the contact plate unit is discharged to discharge the electrostatic charge accumulated in the contact plate unit. The nonconductive placement area of the contact plate portion is set as a bottom surface, Is designed to form a three-dimensional bin space is empty between the conductive parts of the arrangement region of the three-dimensional space touch portions of the upper surface.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a capacitive touch module having an improved recognition rate,

The present invention relates to a touch module that is touched by an electrostatic touch screen, the touch module including a conductive material that induces a capacitive touch on an electrostatic touch screen, (T > = 0.1 mm) or more and a predetermined number of touch parts made of a non-conductive material and having a contact area contacting the electrostatic touch screen and a predetermined number of touch parts A contact plate portion including a nonconductive placement region that is placed or fixed in a designed geometric relationship in a designed geometry relationship and a specified number of touch portions that are placed or fixed in a geometric relationship designed in advance on the non- Conductive arrangement of conductive material capable of forming electrical circuit by contacting or batch fixing And an adapter unit including a conductive exposed region for exposing an electric circuit between the station and the touch units to the outside, wherein the contact plate includes a non-conductive member capable of repeating a process of contacting the electrostatic touch screen or storing static electricity by friction, Wherein the predetermined number of touch portions include a non-conductive placement region of the contact plate portion and a conductive placement region of the adapter portion in a state in which the contact plate portion is not in contact with the electrostatic touch screen The nonconductive placement region of the contact plate portion is made to be a bottom face so as to discharge an electrostatic charge accumulated in the contact plate portion while an electrical circuit is connected between the conductive placement region of the adapter portion and the human body, The touch portions of the three-dimensional space having the conductive arrangement region of the adapter portion as the upper surface The blank relates to a capacitive touch module and its manufacturing method having an improved recognition rate is produced to form a three-dimensional bin space.

The electrostatic touch coating in which a plurality of touch parts made of a conductive material are arranged in a geometrical arrangement structure assigned to a flat plate area and is touched to the capacitive touch screen has been developed (Japanese Patent Laid-Open Publication No. 10-2015-0029249 (2015.03.18)). However, the conventional electrostatic type touch coating has a problem that the geometrical arrangement structure for arranging the plurality of touch parts is exposed to the outside because the geometrical arrangement structure for arranging the plurality of touch parts is visually exposed to the outside.

Recently, a touch module that does not expose the geometric relationship formed by a plurality of touch parts using a touch film has been developed (Patent Registration No. 10-1482667 (Aug. It is known that a touch module having a touch film currently has the same performance as touching the touch portion directly to the electrostatic touch screen without exposing the geometric relationship formed by the touch portions to the outside.

However, in the case of the touch module manufactured with the recently developed touch film, in the initial stage of touching the capacitive touch screen, although it is stably recognized within the effective recognition rate range regardless of the capacitive touch screen, After touching, the recognition rate of a certain type of electrostatic touch screen (for example, Apple's iPhone) is decreasing. However, what is the cause of decrease of the recognition rate on the specific type of electrostatic touch screen after a certain period of time has elapsed since the touch module which was normally recognized at the beginning, what is the solution

An object of the present invention is to provide a touch module which is touched by an electrostatic touch screen, the touch module including a conductive material for causing an electrostatic touch on an electrostatic touch screen, (T > / = 0.1 mm) and having a predetermined number of touch parts and non-conductive materials and having a contact area contacting the electrostatic touch screen and a predetermined number of touch parts And a predetermined number of touches that are arranged or fixed in a geometric relationship predesignated on a nonconductive placement area of the contact plate, the contact plate comprising a nonconductive placement area that includes a nonconductive placement area that is placed or fixed in a designed geometric relationship, Conduction of conductive material capable of forming an electrical circuit by contacting and / And an adapter unit including a conductive area for exposing an electric circuit between the placement area and the touch parts to the outside, wherein the contact plate part is configured to repeatedly contact the electrostatic touch screen or to store static electricity by friction, Wherein the predetermined number of touch portions includes a nonconductive placement region of the contact plate portion and a conductive placement of the adapter portion in a state in which the contact plate portion is not in contact with the electrostatic touch screen, And a nonconductive placement region of the contact plate portion is connected to the lower surface of the contact plate portion in order to discharge an electrostatic charge accumulated in the contact plate portion, Dimensional space in which the conductive placement area of the adapter section is the upper surface. Capacitive touch module with empty improved recognition rate will be produced so as to form a three-dimensional bin space between parts and the manufacturing method thereof is to provide.

An electrostatic touch module having an improved recognition rate according to the present invention and a method of manufacturing the same, the electrostatic touch module including a conductive material that induces a capacitive touch on an electrostatic touch screen, (T > / = 0.1 mm) and having a predetermined number of touch parts and non-conductive materials and having a contact area contacting the electrostatic touch screen and a predetermined number of touch parts And a predetermined number of touches that are arranged or fixed in a geometric relationship predesignated on a nonconductive placement area of the contact plate, the contact plate comprising a nonconductive placement area that includes a nonconductive placement area that is placed or fixed in a designed geometric relationship, Of a conductive material capable of forming electrical circuitry And an adapter unit including a conductive placement area for exposing an electric circuit between the conductive placement area and the touch parts to the outside, wherein the contact plate part repeats a process of contacting the electrostatic touch screen, Wherein the predetermined number of touch portions includes a nonconductive placement region of the contact plate and a conductive portion of the adapter portion in a state in which the contact plate portion is not in contact with the electrostatic touch screen, Conductive area of the contact plate is connected to an electric circuit between the conductive placement area of the adapter and the human body while a contact area between the conductive placement area of the adapter and the non- Dimensional space in which the conductive placement area of the adapter section is the upper surface And is formed so as to form an empty three-dimensional space between the touch portions.

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In the electrostatic touch module having an improved recognition rate according to the present invention and the method of manufacturing the same, the adapter portion may be formed of a conductive material corresponding to the conductive placement region or the conductive exposure region, when the contact plate portion includes a non- And non-conductive paper materials are laminated or laminated.

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In the electrostatic touch module and the method of manufacturing the same according to the present invention, an empty space is formed between the predetermined number of touch parts and a nonconductive material provided in the touch module.

In the electrostatic touch module having an improved recognition rate according to the present invention and a method of fabricating the same, a designation layout in which a non-conductive placement area of the contact plate and a conductive placement area of the adapter are arranged and fixed in a geometric relationship in design, And an arrangement space part for forming a three-dimensional space between the number of touch parts.

In the electrostatic touch module having an improved recognition rate according to the present invention and a method of manufacturing the same, a predetermined number of touch parts, which are arranged and fixed in a geometric relationship in a design, are housed in a nonconductive placement area of the contact plate part and a conductive placement area of the adapter part, And a housing part for forming a three-dimensional hollow space therebetween.

In the electrostatic touch module and the method of manufacturing the same according to the present invention, the predetermined number of touch units include a plurality of touch panels including a plurality of touch panels including a plurality of touch panels, A predetermined number of touched portions are embedded in each of the trenched holes of the trenched trenched plate portion so that a specified number of touched portions are arranged and fixed in a designed geometrical relationship on the conductive trenched region of the adapter portion and then the trenched plate portion is removed, And is arranged and fixed in a designed geometrical relationship pre-designed on the conductive placement area of the adapter part while forming an empty space between the parts.

In the electrostatic touch module and the method of manufacturing the same according to the present invention, the predetermined number of touch portions include a plurality of tangible regions, each of which has a tangent to the tangent arrangement region of the contact plate portion, And a plurality of touch portions are embedded in the embossed holes of a part of the embossed holes of the laminated embossed plate portion so that a part of the touch portions are arranged and fixed on the nonconductive placement region of the contact plate portion, The remaining touched portions are embedded in the remaining touched holes of each of the touched holes of the laminated touched plate portion to place and fix the remaining touched portions on the conductive placement region of the adapter portion and then remove the touched plate portions, The non-conductive arrangement region of the contact plate portion and the front portion of the adapter portion Arranged in a geometrical relationship between design predesigned St. placement area is characterized in that the fixing.

In the electrostatic touch module having an improved recognition rate according to the present invention and the method of manufacturing the same, the predetermined number of touch portions are formed by using a robot arm operating on a non-conductive arrangement region of the contact plate portion, And is arranged and fixed in a designed geometrical relationship pre-designed on the non-conductive placement region of the contact plate portion.

In the electrostatic touch module having an improved recognition rate according to the present invention and a method of manufacturing the same, the predetermined number of touch parts are formed by forming a void space between each touch part using a robot arm operating on a conductive arrangement area of the adapter part And are arranged and fixed in a designed geometrical relationship pre-designed on the conductive placement area of the adapter part.

In the electrostatic touch module having an improved recognition rate according to the present invention and the method of manufacturing the same, the predetermined number of touch portions are formed by using a robot arm operating on a nonconductive placement region of the contact plate portion and a conductive placement region of the adapter portion, And is arranged and fixed in a designed geometrical relationship between the nonconductive placement area of the contact plate and the conductive placement area of the adapter part while forming an empty space between the touch parts.

In the electrostatic touch module having an improved recognition rate according to the present invention and a method of manufacturing the same, a method of manufacturing a touch module to be touched on an electrostatic touch screen, the method comprising the steps of: The method comprising: a first step of preparing a contact plate comprising an area and a nonconductive placement area comprising a specified number of touch parts arranged in a designed geometric relationship or in contact with a designed geometric relationship; A conductive placement area of a conductive material capable of forming an electrical circuit by being in contact with or fixed to a specified number of touch parts arranged or fixed in a designed geometric relationship and a conductive exposure area for exposing an electric circuit with the touch parts to the outside, A second step of preparing an adapter unit including And a conductive material for inducing an electrostatic touch on the electrostatic touch screen in at least one of a nonconductive placement area of the swing plate and a conductive placement area of the adapter, And a third step of disposing a specified number of touch parts manufactured with a thickness T (T? 0.1 mm) or more in a designed geometrical relationship in design, wherein the contact plate part repeats the process of contacting the capacitive touch screen, Conductive plastic material or nonconductive paper material capable of storing static electricity by the electrostatic touch screen, wherein the specified number of touch portions are arranged in a non-conductive arrangement of the contact plate portion And the conductive portion of the adapter portion is maintained in contact with the conductive portion of the adapter portion, An electrical circuit is connected between the conductive placement area and the human body and a nonconductive placement area of the contact plate is made to be a bottom face and a conductive placement area of the adapter is made an upper face to discharge the static charge stored in the contact plate, Dimensional void space between the touch portions of the dimensional space.

In the electrostatic touch module having an improved recognition rate according to the present invention and the method of manufacturing the same, the method further comprises preparing a fillet plate having a predetermined number of fillet holes formed in a designed geometric relationship, A step of laminating the embossed plate portions in the arrangement region, embedding each touch portion in each embossed hole formed in the embossed plate portion, and arranging and fixing the touched portion in a designed geometrical relationship in the designed arrangement region.

An electrostatic touch module according to the present invention is a touch module that is touched by an electrostatic touch screen. The electrostatic touch module includes a conductive material that induces an electrostatic touch on the electrostatic touch screen. The electrostatic touch module has a restoring force against contraction caused by external force A touch area made up of a specified number of touch parts and a nonconductive material manufactured to a specified thickness T (T? 0.1 mm) or more and having a contact area contacting the electrostatic touch screen and a predetermined number of touch parts in a designed geometric relationship A contact plate portion including a non-conductive placement region that includes a non-conductive placement region in which the contact plate portion is placed, fixed, or in contact with a predetermined number of touch portions that are arranged or fixed in a predetermined geometric relationship on a non-conductive placement region of the contact plate portion A conductive arrangement region of a conductive material capable of forming an electrical circuit; And the term circuit includes an adapter made in a conductive exposed region exposed to the outside, it characterized in that the group designed to form a three-dimensional bin space is empty between the designed geometric relationships specified number of touch portions that are arranged in a.

According to the present invention, the capacitive touch module further includes a plurality of touch portions arranged in a design geometric relationship through at least one of a non-conductive placement region of the contact plate portion and a conductive placement region of the adapter portion. Dimensional space, and a space space for forming a dimensional space.

According to the present invention, the capacitive touch module includes a non-conductive arrangement region of the contact plate portion and a conductive arrangement region of the adapter portion, and a three-dimensional space is defined between a specified number of touch portions arranged and fixed in a geometrical relationship in design And a housing part for forming the housing.

According to the present invention, the geometric relationship in the design may include at least one of a distance relation and an angular relation uniquely arranging the specified number of touch parts.

According to the present invention, the specified number of touch portions are arranged and fixed in a designed geometrical relationship designed in a nonconductive placement region of the contact plate portion, and can contact the conductive placement region of the adapter portion. On the other hand, the designated number of touch parts are arranged and fixed in a designed geometrical relationship in a designed conductive arrangement area of the adapter part, and can contact the non-conductive arrangement area of the contact plate part. The touch units of the specified number of touch units are fixedly disposed in the nonconductive placement area of the contact plate unit, the remaining touch units of the specified number of touch units are fixedly disposed in the conductive placement area of the adapter unit, The predetermined number of touch portions arranged and fixed to the nonconductive placement region and the conductive placement region of the adapter portion can form the designed geometric relationship in design.

According to the present invention, the specified number of touch parts are stacked on the non-conductive placement area of the contact plate part, and the embossed plate parts formed with the embossed holes forming the designed geometric relationship are laminated and assigned to the embossed holes of the laminated embossed plate part The number of touch parts is embedded so that a specified number of touch parts are arranged and fixed in a designed geometrical relationship on the nonconductive placement area of the contact plate part and then the embedded plate part is removed to form an empty space between the touch parts, And can be placed and fixed in a designed geometric relationship pre-designed on the non-conductive placement region of the device.

According to the present invention, the specified number of touch portions are formed by laminating embossed plates formed with embossed holes that form a designed geometrical relationship on a conductive arrangement region of the adapter portion, and a predetermined number of embossed holes are formed in the embossed holes of the laminated embossed plate portion A plurality of touch portions are arranged and fixed in a designed geometrical relationship in a designed design on a conductive placement region of the adapter portion by embedding a touch portion, and then the embedded plate portion is removed to form an empty space between the touch portions, And can be placed and fixed in a geometric relationship in a design designed in advance.

According to the present invention, the specified number of touch portions are formed by laminating the embossed plate portions formed with embossed holes forming the designed geometrical relationship on the nonconductive placement region of the contact plate portion, and part of the embossed holes of the laminated embossed plate portion A part of the touch part is embedded in the embedding hole of the adapter part to place and fix a part of the touch part on the nonconductive placement area of the contact plate part and the embedding plate part is stacked on the conductive placement area of the adapter part, The remaining touch portions are buried in the remaining buried holes of the buried holes to arrange and fix the remaining touch portions on the conductive buried regions of the adapter portion and then remove the buried plate portions to form empty spaces between the respective touch portions, Placed in a designed geometric relationship between the conductive placement area of the adapter and the adapter part. Can be fixed.

According to the present invention, the designated number of touch portions are formed on the non-conductive placement region of the contact plate portion while forming a void space between the respective touch portions using the robot arm operating on the non-conductive placement region of the contact plate portion Lt; RTI ID = 0.0 > geometry < / RTI >

According to the present invention, the predetermined number of touch parts are formed in a designed geometric relationship on the conductive placement area of the adapter part while forming a void space between the respective touch parts using the robot arm operating on the conductive placement area of the adapter part Batch can be fixed.

According to the present invention, the specified number of touch parts form a void space between the respective touch parts using the robot arm operating on the non-conductive arrangement area of the contact plate part and the conductive arrangement area of the adapter part, And can be placed and fixed in a designed geometric relationship between the placement area and the conductive placement area of the adapter part.

According to the present invention, the capacitive touch module may be manufactured using a contact plate portion made of a paper material and an adapter portion having a conductive region on at least one surface by laminating or joining a conductive material to a paper material.

According to the present invention, the capacitive touch module may be manufactured using a contact plate portion of a nonconductive material and an adapter portion of a conductive material.

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Meanwhile, a method for fabricating a capacitive touch module according to the present invention is a method for manufacturing a touch module to be touched on a capacitive touch screen, the method comprising the steps of: forming a contact area contacting the capacitive touch screen, A first step of preparing a contact plate portion comprising a nonconductive placement region in which the touch portions of the contact plate are arranged or fixed in a designed geometric relationship with the design and a step of arranging the contact plate in a geometric relationship An adapter unit including a conductive placement area of a conductive material capable of forming an electric circuit by contacting or fixing the predetermined number of touch parts fixed or contacting and a conductive exposure area for exposing an electric circuit with the touch parts to the outside, A second step of preparing the contact plate portion and a non- Wherein the electrostatic touch screen includes a conductive material for causing at least one of a placement region and a conductive placement region of the adapter portion to have an electrostatic touch on the electrostatic touch screen and having a restoring force against shrinkage due to an external force, And a third step of disposing a specified number of touch units manufactured with a design geometric relationship in a designed geometric relationship, and forming an empty three-dimensional space between the designated number of touch units arranged in the designed geometric relationship .

According to another aspect of the present invention, there is provided a method of manufacturing a capacitive touch module, comprising: preparing a fillet plate having a predetermined number of fillet holes formed in a designed geometric relationship with a designed design; A step of laminating the plate portions, embedding the respective touch portions in the respective embossed holes formed in the embossed plate portion, and arranging and fixing them in the designed geometric relationship in the designed region.

According to the present invention, a capacitive touch module for generating a multi-touch point on a capacitive touch screen is manufactured by disposing and fixing a predetermined number of electrostatic touchable touch parts on a capacitive touch screen in a designed geometrical relationship in a designed design, The present invention has an advantage in that the recognition rate of the electrostatic touch can be maintained without decreasing even if the touch module is used for a predetermined period or more by manufacturing an empty space between a specified number of touch portions arranged and fixed to the touch module.

1 is a view illustrating a structure of a touch module according to an embodiment of the present invention.
2A and 2B are views showing an embodiment of a touch module according to an embodiment of the present invention.
3A to 3H are views illustrating a process of fabricating a touch module according to an embodiment of the present invention.
4A to 4J are views illustrating a process of fabricating a touch module according to another embodiment of the present invention.

The operation principle of the preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings and description. It should be understood, however, that the drawings and the following detailed description are exemplary and explanatory and are intended to provide further explanation of the invention, and are not to be construed as limiting the present invention.

In other words, the following embodiments correspond to the preferred embodiment of the present invention, which is a preferred embodiment of the present invention. In the following embodiments, specific configurations may be omitted, or functions implemented in specific configurations may be referred to as specific configurations It is to be clearly understood that the embodiments that divide or separate the functions embodied in two or more configurations into one configuration are all within the scope of the present invention unless otherwise mentioned in the following embodiments. Therefore, it should be clearly stated that various embodiments corresponding to subsets or combinations based on the following embodiments can be subdivided based on the filing date of the present invention.

In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear. The terms used below are defined in consideration of the functions of the present invention, which may vary depending on the user, intention or custom of the operator. Therefore, the definition should be based on the contents throughout the present invention.

As a result, the technical idea of the present invention is determined by the claims, and the following embodiments are merely means for effectively explaining the technical idea of the present invention to a person having ordinary skill in the art to which the present invention belongs Only.

1 is a view showing a structure of a touch module 100 according to an embodiment of the present invention.

1 illustrates an example of a side structure of the touch module 100. As a person skilled in the art will refer to and / or modify the touch module 100, It will be appreciated that the various embodiments of the module 100 may be deduced, but the present invention includes all of the above-described embodiments, and the technical features of the module 100 are not limited to those shown in FIG.

Referring to FIG. 1, the touch module 100 includes a conductive material (or a capacitive material) that induces an electrostatic touch on an electrostatic touch screen. The touch module 100 has a restoring force against contraction caused by an external force. A contact area 115 made of a nonconductive material and contacting the electrostatic touch screen, and a predetermined number of touch parts 105, which are made of a predetermined number or more of T (T? 0.1 mm) (Not shown) on the nonconductive placement area 120 of the contact plate 110. The contact plate 110 includes a nonconductive placement area 120, which is configured and arranged to place or fix, in a designed geometric relationship, A conductive placement area 130 of a conductive material capable of forming an electrical circuit in contact with or placed on a predetermined number of touch parts 105 which are arranged or fixed in a geometric relationship, And a conductive exposed region 135 for exposing an electric circuit to the outside with a predetermined number of touch units 105 having a thickness T or more, And a void space is formed between the predetermined number of touch units 105 and a nonconductive material included in the touch module 100 according to the method. The touch module 100 may include a plurality of touch portions 105 formed on the contact plate 110 and electrically connected to the conductive portion 120 and the adapter portion 125, (140) for forming a three-dimensional hollow space between a specified number of touch portions (105) arranged and fixed in a geometrical relationship in design through one or more arrangement regions (120, 130) And / or a predetermined number of touch portions (not shown) that are arranged and fixed in a geometric relationship in design by housing the conductive placement region 130 of the adapter plate 125 and the non-conductive placement region 120 of the contact plate 110 105 and a housing part 145 for forming a three-dimensional hollow space therebetween. According to an embodiment of the present invention, the touch module 100 includes a conductive region of a conductive material in contact with a human body, and electrically connects the conductive region to the conductive exposed region 135 of the adapter unit 125 And a handle 150 for forming an electric circuit up to the number of touch units 105. [ Hereinafter, the conductive region of the touch unit 105 and the adapter unit 125 will be described in blue for convenience.

The touch module 100 includes at least three touch units 105, which are manufactured by disposing a predetermined number of touchable touch units 105 on a capacitive touch screen in a specific designed geometric relationship, Four touch units 105, or five touch units 105. [0064] However, the number of touch units 105 disposed in the touch module 100 is not limited to three to five. For example, currently, a touch screen provided on an Apple iPhone is limited to support a maximum of five multi-touches. If the limitation is solved, the designation N of the touch unit 105 can be made to be six or more.

According to an embodiment of the present invention, the touch module 100 includes a placement area 120, 130 (not shown) formed of a nonconductive material and having a geometry of a designed area (e.g., a square structure having a width of 3 cm) And a plurality of touch units 105 are arranged and fixed in a predetermined design geometric relationship. The plurality of touch units 105 are arranged and fixed in a layout area 120 The design geometric relationships formed by the designated number of touch portions 105 by the housing structure are designed and manufactured so as to maintain airtightness without being visually exposed to the outside. That is, when the touch module 100 designed and manufactured according to the present invention is touched to the electrostatic touch screen, the portions actually contacting the electrostatic touch screen are not the touch portions 105 but the touch portions 105, Wherein the contact plate part (110) contacting the electrostatic touch screen is a contact area (115) of the contact plate part (110) among the arrangement areas (120, 130) Designed to be guided by a touch screen.

According to the first geometric relationship embodiment of the present invention, the design geometrical relationship in which the specified number of touch portions 105 are disposed is determined by the distance relationship between the specified number of touch portions 105 and the angular relationship between at least one or both May include a unique geometric relationship corresponding to the combination.

According to the second geometric relationship embodiment of the present invention, the geometric relationship in the design is determined by designating a designated position on the arrangement area 120, 130 where the specified number of touch parts 105 are arranged and fixed, as the reference point, And may include a unique geometric relationship corresponding to at least one or a combination of the distance relationship and the angular relationship between the specified number of touch portions 105. [

According to the third geometric relationship of the present invention, the geometric relationship in the design is determined by setting one of the touch units 105 as a reference point, ) And the angular relationship between the angular relationship and the angular relationship.

According to a fourth geometric relationship implementation of the present invention, the geometric relationship in the design can be at least partially a combination of at least two of the first through third geometric relationships, and the present invention is not limited thereto .

According to an embodiment of the present invention, the geometric relationship in the design preferably includes a reference point for the coordinate rotation of the geometric relationship in the design that places the specified number of touch portions 105. [ The reference point may be a coordinate origin of a coordinate system corresponding to the geometric relation for disposing the specified number of touch parts 105 (for example, the origin of a coordinate system corresponding to the placement area 120 or 130) And the reference point of the geometric relation, and the design geometric relation for arranging the designated number of touch parts 105 includes a discrimination rule capable of discriminating the reference point through mutual arrangement relation . For example, when five touch units 105 are arranged in the touch module 100, the layout regions 120 and 130 in which the five touch units 105 are arranged are divided into four design division regions , One touch portion 105 is disposed in each of the four divided regions, and one touch portion 105 is additionally disposed at a specific position on one of the four divided regions (i.e., (One touch portion 105 is arranged in the area and the two touch portions 105 are arranged in one of the divided regions) and then the specific position where the one touch portion 105 is additionally disposed A position that is spaced by a specific distance in a specific direction on the basis of the reference position). In this case, when five touch points are recognized as multi-touches on the electrostatic touch screen, the mutual arrangement relation with respect to the five touch points is read based on the division area on the design, and the reference point is identified (for example, And a specific position is discriminated through a touch point corresponding to one touch part 105 disposed additionally to the discriminated one of the divided areas and corresponding thereto To identify the reference point. However, the rule for determining the reference point is not limited to the above example, and various modifications may be made, and it is evident that the present invention can also be applied to the scope of the modified embodiment.

The touch unit 105 includes an electrostatic touchable electroconductive material (or capacitive material) on the electrostatic touch screen. Preferably, the touch unit 105 may be contracted by an external force (for example, a pushing force applied by a human hand) And a material having a specified elasticity that can be restored to its original state as the external force is released. The touch portion 105 may be made of a material having elasticity for shrinking / restoring, or may be manufactured so that a hollow space is formed therein and / or a foam space is formed.

According to the method of the present invention, the touch portion 105 may be formed by forming a metal film of a metallic material on the outside of the cushioning material having the foamed space including the elastic material capable of shrinking / restoring. The cushioning material may be formed of a foamable material such as sponge or polyurethane. The metal film may be formed by plating a metallic material on the buffer material and / or by yarn or cotton on a metallic material. For example, the touch portion 105 may have a structure of an EMI shielding gasket formed by forming a metal film of a cushioning material.

According to another embodiment of the present invention, the touch portion 105 may be formed of a conductive rubber material or a conductive plastic material that can be shrunk / restored, or may be made of a solid dielectric material or a liquid- The present invention is not limited thereto, and can be manufactured using a dielectric material made of a material and a container for housing the material.

According to the method of the present invention, the touch portion 105 may be manufactured to have the same thickness T or at least one different thickness of the specified thickness T or more, and thus the present invention is not limited thereto.

The contact plate 110 includes a contact area 115 contacting the electrostatic touch screen when the touch module 100 is touched to the electrostatic touch screen, (Or at least some of the touch portions 105) in a designed geometric relationship and / or in contact with a specified number of touch portions 105 disposed in a design geometric relationship, (120), and is made of a geometric structure of the designed area.

According to the method of the present invention, the contact plate 110 may be formed of a nonconductive (at least translucent) conductive material such that a specified number of the touch parts 105 disposed in the nonconductive placement area 120 are visually exposed to the outside, (Or proximity) to the electrostatic touch screen, it is preferable that the electrostatic touch screen includes a thickness capable of inducing a change in electrostatic force caused by the touch portions 105 to the electrostatic touch screen . For example, the contact plate 110 may be made of an opaque (or at least translucent) nonconductive material having a thickness of less than 0.2 mm. If the contact plate 110 is made of a paper material, the contact plate 110 may be manufactured to have a thickness corresponding to a paper material of 180 g or less per unit area.

The adapter portion 125 contacts and / or contacts a specified number of touch portions 105 (or at least a portion of the touch portion 105) arranged and fixed in the nonconductive placement region 120 of the contact plate portion 110, Or a conductive material comprising a conductive material for disposing and fixing a specified number of touch portions 105 (or at least a portion of the touch portions 105) that contact the nonconductive placement region 120 of the contact plate portion 110, Region 130 and forms an electrical circuit with the designated number of touch portions 105. [ The conductive placement region 130 of the adapter portion 125 may include a geometric structure of a predefined area corresponding to the nonconductive placement region 120 of the contact plate 110.

A conductive exposed region 135 is formed on one side of the adapter unit 125 to expose the electrical circuit formed with the predetermined number of the touch units 105 to the outside or electrically coupled to the handle unit 150 .

Or may be fixed to the conductive placement region 130 of the adapter section 125 or may be fixed to the nonconductive placement region 120 of the contact plate 110 And the predetermined number of touch parts 105 fixedly distributed and arranged in the conductive placement area 130 of the adapter part 125 form the designed geometric relationship of the designed design.

According to the first touch portion arrangement of the present invention, the designated number of touch portions 105 are arranged in a designed geometric relationship while forming a void space in the non-conductive placement region 120 of the contact plate portion 110 And the predetermined number of touch portions 105 disposed in the nonconductive placement region 120 of the contact plate portion 110 can be electrically contacted with the conductive placement region 130 of the adapter portion 125 have.

For example, a predetermined number of touch portions 105 arranged and fixed in the nonconductive placement region 120 of the contact plate portion 110 may be formed by contacting a contact region 115 of the contact plate portion 110 with an electrostatic touch screen (See, for example, FIG. 2a), and the contact plate 110 may be made of a conductive material such as an electrically conductive material, When a predetermined pressing force is applied through the adapter unit 125 in contact with the touch screen, a specified number of touch units 105 fixedly disposed in the nonconductive placement area 120 of the contact plate unit 110 are pressed And may be made to contact the conductive placement region 130 of the adapter portion 125 by an attractive force to form an electrical circuit.

The height of at least one touch portion 105 of the predetermined number of touch portions 105 arranged and fixed in the nonconductive placement region 120 of the contact plate portion 110 may be made different, Some of the designated number of touch portions 105 fixed and arranged in the conductive placement region 120 are fabricated to maintain contact with the conductive placement region 130 of the adapter portion 125 When the contact plate 110 contacts the electrostatic touch screen and a predetermined biasing force is applied through the adapter unit 125, the non-conductive placement area 120 of the contact plate 110 may be in contact with the non- The rest of the touch part 105 fixed to the adapter part 125 can be made to contact the conductive placement area 130 of the adapter part 125 by the biasing force to form an electric circuit.

According to the second touch portion arrangement of the present invention, the designated number of touch portions 105 are arranged and fixed in a designed geometrical relationship in the designed conductive space 130 while forming a void space in the conductive placement region 130 of the adapter portion 125. [ And a predetermined number of touch portions 105 disposed in the conductive placement region 130 of the adapter portion 125 may be in electrical contact with the nonconductive placement region 120 of the contact plate portion 110 .

For example, a predetermined number of touch portions 105 arranged and fixed in the conductive placement region 130 of the adapter portion 125 may be formed by contacting a contact region 115 of the contact plate portion 110 with an electrostatic touch screen The contact plate 110 may be manufactured to be spaced apart from the nonconductive placement area 120 of the contact plate 110 by a predetermined distance before the contact plate 110 contacts the capacitive touch screen and the adapter 125 The predetermined number of touch portions 105 fixedly disposed in the conductive arrangement region 130 of the adapter portion 125 are pressed by the pressing force to the nonconductive state of the contact plate portion 110 by the pushing force, May be fabricated to contact the placement area 120 to induce electrostatic changes on the capacitive touch screen.

Or the height of at least one touch portion 105 of the predetermined number of touch portions 105 arranged and fixed in the conductive placement region 130 of the adapter portion 125 may be made differently so that the conductive placement of the adapter portion 125 Some of the designated number of touch portions 105 fixedly disposed in the region 130 may be manufactured to maintain contact with the nonconductive placement region 120 of the contact plate portion 110, When the predetermined touch force is applied through the adapter unit 125 by contacting with the electrostatic touch screen, the remaining touch unit 105, which is fixedly disposed in the conductive arrangement region 130 of the adapter unit 125, Conductive placement area 120 of the contact plate 110 to induce electrostatic changes on the capacitive touch screen.

According to the third embodiment of the present invention, the touch portions 105 of the predetermined number of touch portions 105 are fixedly disposed in the nonconductive placement region 120 of the contact plate portion 110, The touch portion 105 of the contact plate 110 may be arranged and fixed while forming an empty space in the conductive placement region 130 of the adapter portion 125. The non- The predetermined number of touch portions 105 that are arranged and fixed in the conductive placement region 130 of the semiconductor device 125 are fabricated to form the designed geometric relationship of the designed design.

For example, a portion of the touch portion 105, which is fixedly disposed on the non-conductive placement region 120 of the contact plate portion 110, may be configured such that the contact region 115 of the contact plate portion 110 contacts the capacitive touch screen The remaining touch parts 105 are formed to be spaced apart from the conductive placement area 130 of the adapter part 125 by a predetermined distance and fixed to the conductive placement area 130 of the adapter part 125, May also be fabricated to remain spaced apart from the nonconductive placement area 120 of the contact plate 110 by a predetermined distance before the contact area 115 of the contact plate 110 contacts the capacitive touch screen The nonconductive placement region 120 of the contact plate 110 and the adapter portion 125 (not shown) may be connected to the contact plate portion 110 when the contact plate portion 110 contacts the electrostatic touch screen and a predetermined biasing force is applied through the adapter portion 125. [ Each of the touch portions 105 arranged and fixed in the conductive arrangement region 130 The pushing force makes contact with the conductive placement area 130 of the adapter part 125 and the nonconductive placement area 120 of the contact plate 110 so that all the designated number of touch parts 105 are connected to the adapter part 125 to form an electrical circuit and to induce electrostatic changes on the electrostatic touch screen.

Or at least one of the non-conductive placement regions 120 of the contact plate 110 and the conductive placement regions 130 of the adapter portion 125 are different from each other, A part of the touch units 105 fixedly disposed in the nonconductive placement area 120 of the adapter unit 110 may be maintained in contact with the conductive placement area 130 of the adapter unit 125, The contact plate 110 can be manufactured such that a part of the touch part 105 fixedly disposed on the conductive placement area 130 of the contact plate 110 maintains contact with the non- Conductive contact area of the contact plate 110 and the conductive placement area 130 of the adapter 125 when the contact plate 110 contacts the electrostatic touch screen and a predetermined biasing force is applied through the adapter 125. [ The rest of the touch portion 105, The conductive portion 130 of the adapter portion 125 and the nonconductive placement region 120 of the contact plate 110 are in contact with each other so that all of the designated number of touch portions 105 are electrically connected to the electrical circuit And to induce electrostatic changes on the electrostatic touch screen.

According to the fourth embodiment of the present invention, the predetermined number of touch parts 105 are arranged in the non-conductive arrangement area 120 of the contact plate 110 and the conductive arrangement area 130 of the adapter part 125 It can be placed and fixed in a designed geometric relationship in designing while forming an empty space. In this case, the predetermined number of touch portions 105 are arranged between the non-conductive placement region 120 of the contact plate 110 and the conductive placement region 130 of the adapter portion 125 (see, for example, FIG. 2b) And may be fixed or adhered to the nonconductive placement region 120 of the contact plate 110 and the conductive placement region 130 of the adapter portion 125.

According to the fifth embodiment of the touch portion arrangement of the present invention, the predetermined number of touch portions 105 are formed on the basis of the method of at least partially combining at least two embodiments among the first to fourth touch portion arrangement embodiments Space, and can be arranged in a designed geometric relationship so as to induce multiple touches on the electrostatic touch screen. Accordingly, the present invention is not limited thereto.

According to the present invention, it is preferable that the design geometrical relationship of the touch parts 105 disposed in the arrangement areas 120 and 130 of the touch module 100 has uniqueness. Since the area of the placement areas 120 and 130 is finite and the touch areas 105 disposed in the placement areas 120 and 130 have a calculated calculated touch area, The number of cases in which the specified number of touch portions 105 can be arranged in different geometric relationships is limited. According to the present invention, in the process of designing a geometric relationship in design to arrange a specified number of touch parts 105 in a unique geometrical relationship in the touch module 100, a specified number of touch parts 105 are arranged in a finite area, The minimum distinction distance is set in order to derive the maximum number of cases in which the distances can be arranged in different geometric relationships.

In the case where two or more touch units 105 are touched to the electrostatic touch screen, the minimum distinction recognition distance can distinguish the touch points by the two or more touch units 105 in the corresponding electrostatic touch screen by different touch points It includes the minimum recognition distance. On the other hand, the minimum recognition distance may be different for each electrostatic touch screen. Therefore, the present invention can design the geometric relationship of the touch units 105 by setting the maximum value of the minimum recognition distance of each electrostatic touch screen designated as a target to be touched by the touch module 100 to the designation minimum distinction distance have.

According to the present invention, the geometric relationship in design of the touch portions 105 disposed in the arrangement regions 120 and 130 of the touch module 100 is such that the geometric relationships designed in different geometric relationships regardless of touching any of the electrostatic touch screens It is desirable to have an identity that is distinguished by a different geometric relationship. The electrostatic touch on the electrostatic touch screen is a touch, not the point touch. The operating system of the apparatus having the electrostatic touch screen calculates the touch point as the touch point. Calculated as moving. Therefore, a minimum identification distance is set to allow the touch module 100 to be identified in a different geometric relationship even when a specified number of touch portions 105 having different geometric relationships are touched on the electrostatic touch screen.

The minimum identification distances are designed in different geometric relationships so that a specific number of touch portions 105 disposed on the touch module 100 are distinguished from each other in order to identify them in different geometric relationships even when they are touched on the capacitive touch screen Includes a minimum identification distance at which a specified number of touch portions 105 provided in the module 100 should be apart. On the other hand, the minimum identification distance may be different for each electrostatic touch screen. Thus, the present invention can design the geometric relationship of the touch units 105 by setting the maximum value among the minimum identification distances of the respective electrostatic touch screens designated to be touched to the touch module 100 as the minimum distances for designing .

According to the present invention, the design geometrical relationship of the touch portions 105 disposed in the arrangement regions 120 and 130 of the touch module 100 can be arbitrarily selected without touching the specific direction of the electrostatic touch screen, Even if the geometric relationship of the touched touch points is matched within the allowable tolerance range with the geometric relationship in the design.

For the readability of the geometric relationship, the geometric relationship of the touch points touched in any direction in any region of the capacitive touch screen should be co-ordinated to match the geometric relationship in the design, At least one touch part 105 of the touch parts 105 may be fixedly disposed at a designated position by setting the designated touch part 105 for self-defining the reference point of the coordinate rotation without external assistance.

The predetermined number of touch parts 105 arranged in the arrangement areas 120 and 130 of the touch module 100 are arranged in a layout area designated as a geometric relationship in design corresponding to at least one or a combination of two (120, 130).

According to an embodiment of the present invention, the touch module 100 fixes and arranges at least one touch part 105 of a designated number of touch parts 105 at predetermined positions on the placement areas 120 and 130, The geometric structure of the arrangement regions 120 and 130 in which the designated touch portion 105 and the remaining touch portions 105 are arranged are arranged in the calculated positions, Or by setting a geometrical structure relation between the designated touch portion 105 and the remaining touch portions 105, the designated touch portion 105 fixedly arranged at the specified position based on the set geometrical structure relationship You can set the reference point through. For example, when five touch units 105 are arranged in the arrangement regions 120 and 130 of the touch module 100 as shown in FIG. 1, four touch units 105 of the N touch units 105, One of the touch portions 105 can be fixedly arranged at a predetermined position (for example, a position tangent to the side of the lower left corner portion). 1 corresponds to a designated touch unit 105 fixedly disposed at a predetermined position (for example, a position tangent to a side of a left lower corner) using the geometrical structure relationship of the arrangement regions 120 and 130 1, according to the example of FIG. 1, the placement regions 120 and 130 are divided into four equal divided regions (for example, four divided regions of the same quadrangle) One touch portion 105 is disposed at each calculated position on the four divided regions, and the touch portion 105 is assigned to a predetermined position (for example, a position tangent to the side of the lower left corner portion) on one of the four divided regions When touching the touch parts 105 according to the example of FIG. 1 to the electrostatic touch screen, the geometric structure relationship (= placement area (= 120, < / RTI > 130) (For example, a position tangent to the side of the lower left corner portion) on the specified area, based on the geometric structure relationship between the two touch points, The designated touch point can be identified. Meanwhile, apart from the example of FIG. 1, the interior angle of a vertex corresponding to the designating touch part 105 of a pentagonal interior angle formed through a line segment connecting five touch parts 105 is designed to be always smaller than other interior angles Five touch units 105 can be arranged according to the geometrical structure relationship between the touch unit 105 and the remaining touch units 105. In this case, the five touch units 105 are touched to the capacitive touch screen The touch point corresponding to the smallest angle among the five angles of the cabinets connecting the five touch points to be formed can be identified by the designated touch point. In the present invention, the embodiment in which the designated touch unit 105 is fixedly disposed at a specified position and the reference point of coordinate rotation is determined is not limited to the above example, and the designated touch unit 105 may be disposed at a designated position Various embodiments can be derived in which the reference point of coordinate rotation is fixedly arranged, and that the present invention encompasses all of the above-mentioned deriveable ranges as a scope of right.

2a and 2b illustrate an embodiment of a touch module 100 according to an embodiment of the present invention.

In more detail, FIG. 2A illustrates an embodiment of a touch module 100 in the form of a paint, FIG. 2B illustrates an embodiment of a touch module 100 in the form of a character product made of a paper material, The touch module 100 according to the embodiment of FIG. 2b is based on the structure of the touch module 100 shown in FIG. Those skilled in the art will appreciate that various modifications may be made to the embodiment of implementing the touch module 100 (e.g., some of the components may be omitted, The present invention is not limited to the above-described embodiments, and the technical features of the present invention are not limited thereto.

Referring to FIG. 2A, the touch module 100 of the paint type includes a conductive material (or a capacitive material) that induces an electrostatic touch on the electrostatic touch screen, and has a restoring force against contraction caused by external force A predetermined number of touch parts 105 made of a specified thickness T (T? 0.1 mm) or more, a contact area 115 made of a nonconductive material and in contact with the electrostatic touch screen, A non-conductive placement region 120 comprising a non-conductive placement region 120 in which a plurality of contact regions 105 are arranged and fixed in a designed geometric relationship, A conductive placement area 130 of a conductive material capable of forming an electrical circuit by contacting and / or placing a predetermined number of touch parts 105 which are arranged or fixed in a geometric relationship designed in advance, And a conductive exposed region 135 for exposing an electric circuit with the touch units 105 to the outside and a conductive region exposed by the non-conductive arrangement region 120 of the contact plate 110, And a housing part 145 housing the conductive placement area 130 of the part 125 and forming a three dimensional space between the designated number of touch parts 105 arranged and fixed in a geometrical relationship in design And a predetermined number of touch units 105 having a thickness T or more. In accordance with the method of operation, the predetermined number of touch units 105 and the nonconductive And is formed to form an empty space between materials. According to an embodiment of the present invention, the coated touch module 100 includes a conductive region of a conductive material in contact with a human body, and electrically connects the conductive region to the conductive exposed region 135 of the adapter unit 125 And a handle 150 for connecting the plurality of touch units 105 to form a predetermined number of touch units 105 to form an electric circuit.

2A shows a state in which a predetermined number of touch parts 105 are arranged and fixed in a designed geometrical relationship in a designed design in a nonconductive placement area 120 of the contact plate part 110, (B) of FIG. 2a shows a state in which a predetermined number of touch portions are provided in the nonconductive placement region 120 of the contact plate portion 110, (105) of at least one of the touch portions (105) arranged and fixed in the nonconductive placement region (120) of the contact plate portion (110) in a designed geometric relationship, So that at least one touch portion 105 is kept in contact with the conductive placement region 130 of the adapter portion 125. In this case,

Referring to FIG. 2B, the touch module 100 of a character product type made of a paper material includes a conductive material (or a capacitive material) that induces an electrostatic touch on the electrostatic touch screen, A predetermined number of touch parts 105 having a restoring force against contraction and made to a specified thickness T (T? 0.1 mm) or more, a contact area 115 made of a nonconductive material and contacting the electrostatic touch screen, A contact plate 110 including a nonconductive placement area 120 in which the specified number of touch parts 105 are arranged or fixed in a designed geometrical relationship with a designed design, A conductive material capable of forming an electrical circuit by being placed or fixed in contact with a specified number of touch portions 105 which are arranged or fixed in a predefined geometric relationship on the arrangement region 120 And a conductive exposed region 135 for exposing an electrical circuit between the conductive placement region 130 of the contact plate 110 and the touch portion 105 to the outside, Between a predetermined number of touch portions 105 arranged and arranged in a design geometric relationship through at least one of the placement regions 120 and at least one of the conductive placement regions 130 of the adapter portion 125, And a placement space unit 140 for forming a three-dimensional space. The space unit 140 is formed to form a void space between a specified number of touch units 105 having a thickness T or more, And is formed to form an empty space between the touch units 105 and the nonconductive material provided in the touch module 100. [ According to an embodiment of the present invention, the coated touch module 100 includes a conductive region of a conductive material in contact with a human body, and electrically connects the conductive region to the conductive exposed region 135 of the adapter unit 125 And a handle 150 for connecting the plurality of touch units 105 to form a predetermined number of touch units 105 to form an electric circuit.

Referring to FIGS. 2A and 2B, an empty space is formed between a predetermined number of touch portions 105 that are arranged and fixed in the arrangement regions 120 and 130 of the touch module 100. In the present invention, forming an empty space between a predetermined number of touch parts 105 arranged and arranged in the arrangement areas 120 and 130 of the touch module 100 is performed by touching the touch module 100 to the electrostatic touch screen In order to improve the touch recognition rate. If a material such as a plastic material or a paper material is included between a predetermined number of touch parts 105 arranged and fixed in the arrangement areas 120 and 130 of the touch module 100, A plastic material, a paper material, or the like provided in the touch module 100 is a nonconductive material, but static electricity may be accumulated in the process of repeatedly touching the touch module 100 to the electrostatic touch screen. That is, an electromagnetic field is formed on the surface of the electrostatic touch screen in order to recognize the electrostatic touch. When the plastic material or the paper material provided between the touch parts 105 is continuously exposed to the electromagnetic field, Static electricity can be accumulated in the paper or the material of the paper. Although electrostatic charge can be accumulated in the contact plate 110 of the same nonconductive material, even if static electricity is accumulated in the contact plate 110, the discharge is performed at the time of contact with the electrostatic touch screen, The plastic material or the paper material provided between the touch parts 105 can not be discharged and static electricity can be accumulated. The stored static electricity increases the probability of causing noise to the electrostatic touch screen, and as a result, it can provide a cause of obstructing the accurate electrostatic touch by the touch portions 105. The present invention forms an empty space between a specified number of touch parts 105 arranged and fixed in the arrangement areas 120 and 130 of the touch module 100 so that the arrangement areas 120 and 130 of the touch module 100 So that a precise electrostatic touch by a specified number of touch portions 105 arranged and fixed is caused.

According to one embodiment of the present invention, a void space is formed between a predetermined number of touch parts 105 arranged and fixed in the arrangement areas 120 and 130 of the touch module 100, A separate embossed plate 300 can be used to precisely arrange and fix the specified number of touch portions 105. [ The embossing plate 300 is formed with a specified number of embossing holes 305 corresponding to the geometric relations designed to arrange the designated number of touch parts 105 in the designed geometric relationship, Holes are formed in such a manner that the touch portion 105 can be embedded. The embedded plate part 300 is formed of a removable geometry structure on the placement areas 120 and 130 of the touch module 100. The embedded plate part 300 is disposed on the arrangement area of the touch module 100, The respective touch parts 105 are embedded in the respective embedding holes 305 of the embossed plate part 300 and are fixed to the arrangement areas 120 and 130 in a state of being stacked on the first and second substrates 120 and 130, It is possible to precisely arrange and fix the structure in a designed geometrical relationship while forming an empty space between the parts 105.

When a predetermined number of touch units 105 are arranged and fixed in the nonconductive placement area 120 of the contact plate 110 according to the first touch unit arrangement of the present invention, A plurality of embossed plate parts 300 are formed on the embossing area 120 and a predetermined number of embossing holes 300 are formed in the embossing holes 305 of the embossed plate part 300, The touch portion 105 is embedded and fixed and arranged in a designed geometrical relationship in a designed number of touch portions 105 on the nonconductive placement region 120 of the contact plate portion 110 The predetermined number of touch portions 105 are formed in the nonconductive placement region 120 of the contact plate portion 110 while forming an empty space between the respective touch portions 105, ) Can be placed and fixed in a designed geometric relationship .

When a predetermined number of touch units 105 are arranged and fixed in the conductive arrangement area 130 of the adapter unit 125 according to the second touch unit arrangement of the present invention, The embossed plate portion 300 having the embossed holes 305 forming the designed geometrical relationship designed on the embossed embossing plate 130 is stacked and the specified number of touch portions 300 are formed in the embossed holes 305 of the embossed plate portion 300, A predetermined number of touch parts 105 are arranged and fixed in a designed geometrical relationship in a designed manner on the conductive placement area 130 of the adapter part 125 and then the embedded plate part 300 is removed, The predetermined number of touch parts 105 may be arranged and fixed in a designed geometric relationship on a conductive placement area 130 of the adapter part 125 while forming an empty space between the touch parts 105 have.

According to the third touch part arrangement of the present invention, the touch parts 105 of the specified number of touch parts 105 are fixedly disposed in the nonconductive placement area 120 of the contact plate part 110, The touch portion 105 of the contact plate 110 forms a designed geometric relationship on the nonconductive placement region 120 of the contact plate 110 when the contact portion 105 is fixedly disposed on the conductive placement region 130 of the adapter portion 125. [ And a part of the touch part 105 is embedded in the embedded hole 305 of each of the embedded holes 305 of the laminated embedded plate part 300 A part of the touch part 105 is fixedly placed on the nonconductive placement area 120 of the contact plate part 110 and the embedded plate part 300 is placed on the conductive placement area 130 of the adapter part 125, And the remainder of the embossed holes 305 of the embossed plate 300 are laminated to the remaining embossed holes 305, A predetermined number of touch parts 105 are formed on each touch part 105 by arranging and fixing the remaining touch parts 105 on the conductive placement area 130 of the adapter part 125, Are arranged and fixed in a designed geometric relationship between the nonconductive placement region 120 of the contact plate 110 and the conductive placement region 130 of the adapter portion 125, .

According to another embodiment of the present invention, a predetermined number of touch parts 105 fixed and arranged in the arrangement areas 120 and 130 of the touch module 100 may be mounted on the robot arm instead of the embedding plate part 300 And can be disposed and fixed in the placement regions 120 and 130.

The predetermined number of touch units 105 are arranged and fixed in the nonconductive placement area 120 of the contact plate 110 according to the first touch unit arrangement of the present invention. Conductive placement area 120 of the contact plate 110 while forming an empty space between the respective touch parts 105 using a robot arm operating on the nonconductive placement area 120 of the contact plate 110. [ ) In a designed geometric relationship.

When the designated number of touch units 105 are arranged and fixed in the conductive arrangement area 130 of the adapter unit 125 according to the second touch unit arrangement of the present invention, A robot arm operating on the conductive placement area 130 of the adapter part 125 forms a void space between each touch part 105 and is placed on the conductive placement area 130 of the adapter part 125 Can be placed and fixed in a geometric relationship in a designed design.

According to the third touch part arrangement of the present invention, the touch parts 105 of the specified number of touch parts 105 are fixedly disposed in the nonconductive placement area 120 of the contact plate part 110, The predetermined number of touch portions 105 may be disposed on the nonconductive placement region 120 of the contact plate 110 when the touch portion 105 of the contact plate 110 is fixedly disposed on the conductive placement region 130 of the adapter portion 125. [ The nonconductive placement area 120 of the contact plate 110 is formed with a space between each touch part 105 by using a robot arm operating on the conductive placement area 130 of the adapter part 125. [ And the conductive placement region 130 of the adapter portion 125. In this manner,

FIGS. 3A through 3H illustrate a process of fabricating the touch module 100 according to an embodiment of the present invention.

3A through 3H illustrate a case where the touch module 100 of the paint form shown in FIG. 2a (b) is formed while forming a void space between the designated number of touch modules 100 using the emboss plate portion 300, 3, a method of manufacturing the touch module 100 according to the present invention will be described with reference to FIGS. 3 and 4, The process of fabricating the touch module 100 for the other type of touch module 100 or the process of fabricating the touch module 100 using the robot arm, etc.), but the present invention includes all of the above- And the technical features thereof are not limited only by the method shown in FIG.

3A, a contact plate 110 having a geometric structure of a designed area (for example, a square structure with a width of 3 cm) is prepared, and a geometric structure corresponding to the area and the geometrical structure of the contact plate 110 And a predetermined number of embossing holes 305 are formed according to a geometric relationship corresponding to a geometric relationship in design for disposing the designated number of touch portions 105. The embossing plate portion 300 having the predetermined number of embossing holes 305 is prepared, The embedding plate portion 300 is stacked on the nonconductive placement region 120 of the contact plate portion 110. According to the method of the present invention, the laminated plate portion and the embedding plate portion 300 may be laminated using a frame capable of inserting (or fixing) a plate having a geometric structure of the designed area.

The embedding plate 300 is stacked in the nonconductive placement area 120 of the contact plate 110 and each of the embossing holes 305 formed in the embossing plate 300 is formed with the respective touch parts 300, The predetermined number of touch parts 105 are placed in the nonconductive placement area 120 of the contact plate part 110 by inserting the contact parts 105 into the nonconductive placement area 120 of the contact plate part 110, Precise placement and fixation in the designed geometric relationship.

When the predetermined number of touch portions 105 are precisely arranged and fixed in the designed geometric relationship in the designed design in the nonconductive placement region 120 of the contact plate portion 110 using the embossed plate portion 300 as shown in FIG. 3d so that void spaces are formed between a predetermined number of touch parts 105 arranged and fixed in the nonconductive placement area 120 of the contact plate part 110. [ According to the embodiment of the present invention, the predetermined number of touch parts 105 are manufactured to form a void space therebetween, and the predetermined number of touch parts 105 and the touch module 100 Conductive material (for example, the housing part 145, etc.).

3E, the adapter unit 125 having the conductive placement area 130 is coupled to the housing unit 145 and the conductive unit 125 is coupled to the housing unit 145, (135). The conductive exposed region 135 of the adapter portion 125 may be coupled with a portion including the conductive placement region 130 using a bolt.

3 (a) and 3 (b), the contact plate 110 and the combined portion of the touch unit 105 are combined with each other, The touch module 100 having an empty space between the touch units 105 is manufactured. The touch module 100 of the paint type is manufactured as shown in FIG. 3H by coupling the handle 150 to the conductive exposed area 135 of the touch module 100 manufactured as shown in FIG. 3g, for example, by bolting or the like .

4A to 4J are views illustrating a process of fabricating the touch module 100 according to another embodiment of the present invention.

4A to 4J illustrate a case where a touch module 100 of a character product type of paper material shown in FIG. 2B is formed while forming an empty space between a designated number of touch modules 100 using the embossed plate portion 300 4 is a flow chart illustrating a process of manufacturing the touch module 100 according to an embodiment of the present invention. Referring to FIG. 4, The process of fabricating the touch module 100 for the other type of touch module 100 or the process of fabricating the touch module 100 using the robot arm, etc.), but the present invention includes all of the above- And the technical features thereof are not limited only by the method shown in FIG.

A contact plate 110 having a geometric structure of a designed area as shown in FIGS. 4A to 4B is prepared, and a geometric structure and an area corresponding to the area and the geometrical structure of the contact plate 110 are prepared After arranging the arrangement space part 140 in which the empty space for arranging the designated number of the touch parts 105 is formed, the nonconductive placement area 120 of the contact plate part 110 as shown in (a) to (b) The deposition space portion 140 is laminated on the substrate.

The geometric structure and the area that can be inserted into the void space of the arrangement space part 140 as shown in FIGS. 4A to 4B correspond to the geometrical relationship in design for arranging the designated number of touch parts 105 The embedding plate portion 300 having the specified number of embossing holes 305 is prepared according to the geometric relationship of the embossing plate portion 300 and the embossing plate portion 300. Then, as shown in (a) to (b) (300).

The embedding plate portion 300 is inserted into the empty space of the arrangement space portion 140 as shown in FIGS. 4C to 4C, and the embedding plate portion 300 (see FIG. 4D) The touch portions 105 are embedded in the respective embedded holes 305 formed in the contact plate portion 110 and simultaneously disposed and fixed in the nonconductive placement region 120 of the contact plate portion 110, Are precisely arranged and fixed in a non-conductive arrangement region (120) of the contact plate portion (110) in a designed geometrical relationship.

A predetermined number of touch portions 105 are formed in the nonconductive placement region 120 of the contact plate portion 110 using the embossed plate portion 300 as shown in FIGS. 4A to 4D, (A) through (b) of FIG. 4e, the embedding plate portion 300 inserted into the arrangement space portion 140 is removed, The processing is performed such that a void space is formed between a specified number of touch parts 105 arranged and fixed in the nonconductive placement area 120 of the plate part 110. [ According to the embodiment of the present invention, the predetermined number of touch parts 105 are manufactured to form a void space therebetween, and the predetermined number of touch parts 105 and the touch module 100 Conductive material (for example, the arrangement space portion 140) and the like.

A laminate part having the same thickness as the thickness of the adapter part 125 is laminated on one side of the arrangement space part 140 as shown in (a) to (b) of FIG. 4g, Similarly, an adapter unit 125 having a conductive placement area 130 and a conductive exposed area 135 and having a 'U' shape is prepared, and the placement space part (FIG. 4A) U 'shape) of the adapter unit 125 (or the touch units 105 fixedly disposed on the non-conductive placement region 120 of the contact plate 110) An electrical circuit is provided between the conductive placement region 130 of the adapter section 125 and the touching portions 105 by contacting the conductive placement region 130 of the conductive portion 125 with the touching portions 105 And the conductive exposed region 135 of the adapter unit 125 is exposed to the outside. According to the method of the present invention, the conductive exposed region 135 of the adapter unit 125 is physically coupled to the character-shaped handle 150 and electrically coupled to the conductive region of the handle 150, It is preferable that a thickness of the engaging groove is formed to be smaller than or equal to a thickness of the character-shaped grip portion 150.

By physically engaging the handle-shaped grip portion 150 in the engaging groove formed in the conductive exposed region 135 of the adapter portion 125 as shown in (a) to (b) of FIG. 4j, the character- An electric circuit is formed between the conductive area formed on one side of the conductive part and the conductive exposed area 135 of the adapter part 125 so that the touch module 100 having the character shaped handle part 150 can be manufactured .

100: touch module 105: touch part
110: contact plate part 115: contact area
120: nonconductive placement area 125: adapter part
130: conductive placement area 135: conductive exposure area
140: Arrangement space part 145: Housing part
150: handle portion 300:
305: buried hole

Claims (12)

A touch module which is touched by a capacitive touch screen,
A predetermined number of touch parts including a conductive material that induces an electrostatic touch on an electrostatic touch screen, a predetermined number of touch parts having a restoring force against contraction caused by external force, and being manufactured with a specified thickness T (T? 0.1 mm) or more;
A contact plate made of a nonconductive material and including a contact region contacting the electrostatic touch screen and a nonconductive placement region for placing or contacting the designated number of touch portions in a designed geometric relationship; And
A conductive placement area of a conductive material capable of forming an electrical circuit by being in contact with or fixed to a specified number of touch parts arranged or fixed in a predetermined geometric relationship on a non-conductive placement area of the contact plate part, And an adapter portion including a conductive exposure region for exposing an electrical circuit to the outside,
Wherein the contact plate portion includes a nonconductive plastic material or a nonconductive paper material capable of repeating the process of contacting the electrostatic touch screen or accumulating electrostatic charge by friction,
Wherein the predetermined number of touch portions maintain contact with both the nonconductive placement region of the contact plate portion and the conductive placement region of the adapter portion even when the contact plate portion is not in contact with the electrostatic touch screen,
An electrical circuit is connected between the conductive placement area of the adapter unit and the human body and a nonconductive placement area of the contact plate is made to be a bottom surface and a conductive placement area of the adapter unit is set to a top surface Dimensional void space between the touch portions of the three-dimensional space.
[2] The apparatus of claim 1,
When the contact plate portion includes a nonconductive paper material,
Wherein a conductive material and a nonconductive paper material corresponding to the conductive placement area or the conductive exposure area are laminated or laminated on each other.
The method according to claim 1,
Wherein the touch module is formed to form an empty space between the designated number of touch parts and a non-conductive material provided in the touch module.
The method according to claim 1,
Further comprising an arrangement space portion for forming a three-dimensional space between a predetermined number of touch portions arranged and fixed in a geometrical relationship in design through at least one of the non-conductive arrangement region of the contact plate portion and the conductive arrangement region of the adapter portion, Wherein the touch module is a touch panel.
The method according to claim 1,
Further comprising a housing part for housing a nonconductive placement area of the contact plate and a conductive placement area of the adapter to form a three-dimensional space between a specified number of touch parts arranged and fixed in a geometrical relationship in design. Capacitive touch module.
The touch panel according to claim 1,
And a predetermined number of touch portions are embedded in the respective embedded holes of the laminated embedded plate portion to form conductive portions of the conductive placement region of the adapter portion, The predetermined number of touch portions are arranged and fixed in a designed geometric relationship, and then the embedded plate portion is removed, thereby forming an empty space between the touch portions and being arranged and fixed in a designed geometrical relationship on a conductive placement region of the adapter portion Wherein the capacitive touch module is a capacitive touch module.
The touch panel according to claim 1,
A step of laminating an embossed plate portion having embossed holes for forming a designed geometric relationship on a nonconductive placement region of the contact plate portion and embedding a part of the touch portion in embossed holes of a part of the embossed holes of the laminated embossed plate portion, A plurality of touch parts are arranged and fixed on the nonconductive placement area of the contact plate part and the above mentioned embedded plate parts are stacked on the conductive placement area of the adapter part and the remaining touch parts are embedded in the remaining filling holes of each of the embedded holes of the above- And the other of the touch parts is disposed and fixed on the conductive placement area of the adapter part. Then, the embedded plate part is removed to form a space between the touch parts, and a design designed between the nonconductive placement area of the contact plate part and the conductive placement area of the adapter part Wherein the electrostatic touch module is arranged and fixed in a geometric relationship .
The touch panel according to claim 1,
And is arranged and fixed in a designed geometrical relationship on a nonconductive placement region of the contact plate portion while forming a void space between the respective touch portions using a robot arm operating on the nonconductive placement region of the contact plate portion Capacitive touch module.
The touch panel according to claim 1,
Wherein the robot arm is disposed and fixed in a designed geometrical relationship on a conductive placement area of the adapter while forming an empty space between the touch parts using a robot arm operating on the conductive placement area of the adapter part. .
The touch panel according to claim 1,
A robot arm operating on the nonconductive placement region of the contact plate portion and the conductive placement region of the adapter portion is used to form a space between each touch portion and a space between the nonconductive placement region of the contact plate portion and the conductive placement region of the adapter portion, And wherein the capacitive touch module is disposed and fixed in a geometric relationship in a designed design.
A method of fabricating a touch module to be touched by a capacitive touch screen,
A contact plate portion made of a nonconductive material and including a contact region contacting the electrostatic touch screen and including a nonconductive placement region for placing or contacting a designated number of touch portions in a designed geometric relationship ;
A conductive placement area of a conductive material capable of forming an electrical circuit by being in contact with or fixed to a specified number of touch parts arranged or fixed in a predetermined geometric relationship on a non-conductive placement area of the contact plate part, A second step of preparing an adapter portion including a conductive exposure region for exposing an electric circuit to the outside;
And a conductive material for inducing an electrostatic touch on the electrostatic touch screen in at least one of a nonconductive placement region of the contact plate portion and a conductive placement region of the adapter portion and has a restoring force against contraction due to external force And a third step of disposing a specified number of touch units manufactured with a specified thickness T (T? 0.1 mm) in a designed geometric relationship in design,
Wherein the contact plate portion includes a nonconductive plastic material or a nonconductive paper material capable of repeating the process of contacting the electrostatic touch screen or accumulating electrostatic charge by friction,
Wherein the predetermined number of touch portions maintain contact with both the nonconductive placement region of the contact plate portion and the conductive placement region of the adapter portion even when the contact plate portion is not in contact with the electrostatic touch screen,
An electrical circuit is connected between the conductive placement area of the adapter unit and the human body and a nonconductive placement area of the contact plate is made to be a bottom surface and a conductive placement area of the adapter unit is set to a top surface Dimensional void space between the touch portions of the three-dimensional space.
12. The method of claim 11,
And preparing a fillet plate having a specified number of fillet holes formed therein in a designed geometric relationship,
The third step may include the step of laminating the embossed plate portion in the arrangement region, embedding each touch portion in each embossed hole formed in the embossed plate portion, and arranging and fixing the touched portion in a designed geometric relationship in the designed arrangement region Wherein the touch module includes a plurality of touch modules.

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