KR102281597B1 - Capacitive Touch Module - Google Patents

Abstract

The present invention relates to a capacitive touch module, in the capacitive touch module to be touched by the capacitive touch screen, in the capacitive touch module to be touched by the capacitive touch screen, made of a conductive rubber material, A geometrical relationship between a plurality of touch units having a contact surface to be capacitively touched and a geometric relationship between a plurality of touch units formed by connecting the midpoints of the contact surfaces of the plurality of touch units is not overlapped with each other for each touch module of the same type within one area of a designated area. and a frame part having at least one conductive area arranged in a unique geometric relationship and transmitting the human body's capacitance to the touch unit, wherein the contact surface of the touch unit includes a plurality of parts provided within a designated area of the one side area. While maximizing the number of cases in which the touch units are arranged in a unique geometric relationship that does not overlap with each other, the touch rate recognized by touching the plurality of touch units arranged in the unique geometric relationship to the capacitive touch screen is a preset reference ratio It is manufactured in the shape of an ellipse or polygon having a circular contact surface with a diameter of 4 mm (±0.5 mm) to 7 mm (± 0.5 mm) or a contact area corresponding to the circular contact surface in order to maintain the above.

Description

Capacitive Touch Module

The present invention relates to a capacitive touch module to be touched by a capacitive touch screen, in the capacitive touch module to be touched by a capacitive touch screen, a contact surface to be capacitively touched to the capacitive touch screen made of a conductive rubber material The geometric relationship between the plurality of touch units and the plurality of touch units formed by connecting the midpoints of the contact surfaces of the plurality of touch units is arranged in a unique geometric relation so as not to overlap with each other for each touch module of the same type within a region of a designated area, and a frame part having at least one conductive area for transferring the human body's capacitance to the touch unit, wherein the contact surface of the touch unit is a unique non-overlapping part of a plurality of touch units provided within a designated area of the one side area. While maximizing the number of cases of arrangement in one geometric relationship, touch the plurality of touch units arranged in the unique geometric relationship on the capacitive touch screen to maintain a touch rate recognized by all at a preset reference rate or more It relates to a capacitive touch module manufactured in an oval or polygonal shape having a circular contact surface of ±0.5 mm) to 7 mm (± 0.5 mm) or a contact area corresponding to the circular contact surface.

Disclosed is a service using a touch module arranged in a pre-designed geometric relationship with a plurality of touch units made of a conductive rubber material as an identification means and/or authentication means for providing various services by touching the capacitive touch screen.

A typical capacitive touch screen is designed to use a capacitive touch by a user's finger as an input means, and is optimized to do so. When a finger directly touches the capacitive touch screen, the charge stored in the human body including the finger is directly transferred to the capacitive touch screen, and the midpoint of the surface where the finger is touched on the capacitive touch screen is recognized as the touch point. . Meanwhile, instead of a finger, a tool such as a touch pen may be touched on the capacitive touch screen and used as an input means instead of a finger.

In the case of a conventional touch pen, it is designed and manufactured to input a single touch point with a capacitive touch screen, and conductive rubber or conductive plastic is used for a portion in contact with the capacitive touch screen. Hereinafter, conductive rubber or conductive plastic used for capacitive touch is collectively referred to as 'conductive rubber' for convenience.

In general, since rubber is a non-conductive material and has a very large electrical resistance, it interferes with the flow of electric charges and generates static electricity by accumulating electric charges, thereby causing sparks. Accordingly, conductive rubber is mainly used as an antistatic agent to prevent static electricity in the field where rubber is used, and conductive rubber is used in place of a human finger in a part touched with a capacitive touch screen in a conventional touch pen.

Conductive rubber is manufactured by mixing rubber powder with conductive carbon or metal powder, and at least one of reinforcing agent, filler, plasticizer, accelerator, vulcanizing agent, flame retardant, anti-aging agent, and compounding oil is optionally added according to the physical or chemical properties of the rubber. It can be manufactured by mixing. Hereinafter, conductive carbon or metal powder used for manufacturing conductive rubber is collectively referred to as 'conductive carbon' for convenience, and a state in which a predetermined additive is added to a rubber component is collectively referred to as 'rubber' for convenience.

According to the Korean Industrial Standards (KS) standard, a rubber material with an electrical resistance of 3x10^8Ω or less is defined as conductive rubber (KS M ISO 2878:2012). On the other hand, the conductive rubber used as an antistatic agent is used to prevent the accumulation of electric charge rather than to use the flow of electric charge. In this case, the electrical resistance is mostly 10^6Ω or more. On the other hand, although conductive rubber used in conventional touch pens is used for the flow of electric charge for capacitive touch, most of them have an electrical resistance of 1,000Ω or more, and even 10^6Ω or more due to a high rubber compounding ratio for a smooth writing and touch feeling. There are also products with electrical resistance, however low they are, far exceeding 500Ω. However, in the case of a conventional touch pen, it is not a problem even if the resistance of the conductive rubber is high because it is used for touch recognition of one touch point. In addition, in the case of the conductive rubber used in the conventional touch pen, it is manufactured with a hardness of 30 to 40 based on the Shoa A hardness scale in order to maximize the touch area due to the pen pressure generated at the time of touch with a soft writing and touch feeling.

On the other hand, the touch module of the present invention is made by arranging a plurality of touch units made of a conductive rubber material in a pre-designed geometric relationship, and not only needs to recognize all of the capacitive touches for the plurality of touch units, but also has a plurality of touch units provided in the touch module. The geometric relationship of the design of the touch part of the touch screen and the geometric relationship of a plurality of touch points touched on the actual capacitive touch screen must match (or close) within the allowable error (or probability distribution), and the conventional conductive rubber material is used as it is. Therefore, when manufacturing the touch module of the present invention, it is technically difficult to use it as an identification means and/or authentication means for providing various services.

An object of the present invention for solving the above problems is, in the capacitive touch module to be touched on the capacitive touch screen, a plurality of the capacitive touch screen made of a conductive rubber material and having a contact surface to be capacitively touched on the capacitive touch screen. The geometric relationship between the touch unit and the plurality of touch units formed by connecting the midpoints of the contact surfaces of the touch unit and the plurality of touch units is arranged in a unique geometric relation so as not to overlap with each other for each touch module of the same type within one region of a designated area, and a frame portion having at least one conductive area for transferring capacitance to the touch portion, wherein the contact surface of the touch portion has a unique geometric relationship that does not overlap a plurality of touch portions provided within a designated area of the one side area. While maximizing the number of cases in which a plurality of touch units arranged in the unique geometric relationship are touched on the capacitive touch screen, a diameter of 4 mm (± 0.5 mm) is maintained to maintain a touch rate recognized by all of them above a preset reference rate. ) to 7 mm (± 0.5 mm) to provide a capacitive touch module manufactured in the shape of an oval or polygonal shape having a circular contact surface or a contact area corresponding to the circular contact surface.

A capacitive touch module according to the present invention is a capacitive touch module for touching a capacitive touch screen, and includes a plurality of touch units made of a conductive rubber material and having a contact surface to be capacitively touched on the capacitive touch screen, and the The geometric relationship between the plurality of touch parts formed by connecting the midpoints of the contact surfaces of the plurality of touch parts is arranged in a unique geometric relationship so as not to overlap with each other for each touch module of the same type in one area of a designated area, and the capacitance of the human body is applied to the touch and a frame part having at least one conductive region that transmits to the part, wherein the contact surface of the touch part arranges a plurality of touch parts provided within a designated area of the one side region in a unique geometric relationship that does not overlap with each other In order to maximize the number of touch parts arranged in the unique geometric relationship and touch the capacitive touch screen to maintain the recognized touch rate above the preset reference ratio, the diameter of 4 mm (± 0.5 mm) to 7 mm It is characterized in that it is manufactured in an oval or polygonal shape having a circular contact surface of (±0.5 mm) or a contact area corresponding to the circular contact surface.
In the capacitive touch module according to the present invention, the contact surface of the touch unit is a circular contact surface with a diameter of 4 mm (± 0.5 mm) or more for an effective capacitive touch based on human capacitance for a designated capacitive touch screen, or It is characterized in that it is manufactured in an elliptical or polygonal shape having a contact area corresponding to a circular contact surface of diameter 4 mm (±0.5 mm) or more.
In the capacitive touch module according to the present invention, the contact surface of the touch unit has a diameter of 7 mm (± 0.5 mm) in order to maintain the number of cases in which a specified number of touch units are arranged in different geometrical relationships within a specified area to be greater than or equal to the specified number. ) or less, or an elliptical or polygonal shape having a contact area corresponding to a circular contact surface of 7 mm (±0.5 mm) or less in diameter.
In the capacitive touch module according to the present invention, the hardness of the touch part is characterized in that it is manufactured to a hardness of 60 (±5) to 70 (±5) based on a Shore A hardness scale.
In the capacitive touch module according to the present invention, the geometrical relationship is characterized in that it includes a geometrical relationship that excludes a line arrangement structure in which three or more touch parts are arranged in a line among the plurality of touch parts.
In the capacitive touch module according to the present invention, the geometrical relationship is characterized in that it comprises an arbitrary arrangement structure in which three or more touch units among the plurality of touch units are not arranged in a line.
In the capacitive touch module according to the present invention, the geometrical relationship is that at least one touch unit among a plurality of touch units disposed on one side of the frame unit provided in each touch module of the same type is spaced apart by at least a minimum identification distance of at least 3.5 mm. and a geometric relationship in which the geometrical relationship of the touch units provided in each touch module of the same type is not overlapped with each other by placing them in different positions of the same type, and the minimum identification distance is provided in one region of the frame unit provided in other touch modules of the same type. It is characterized in that it includes the distance between the centers of the comparison target touch unit.
In the capacitive touch module according to the present invention, the geometrical relationship divides one side area of the frame part into divided areas with a number less than the number of touch units, and arranges one touch unit at an arbitrarily calculated position on each divided area. However, it is characterized in that it comprises a geometric relationship of further disposing at least one touch unit at a designated position on at least one designated area among the divided areas.
A capacitive touch module according to the present invention is a capacitive touch module for touching a capacitive touch screen, comprising: a plurality of touch units made of a conductive rubber material and having a contact surface to be capacitively touched on the capacitive touch screen; and a frame portion having at least one conductive area disposed on one side of the plurality of touch units in a specified geometric relationship and transmitting the human body's capacitance to the touch unit, wherein the contact surface of the touch unit has a diameter of 6 mm (±0.5). mm) to 7 mm (±0.5 mm) of circular contact surface, or an oval or polygonal shape having a contact area corresponding to the circular contact surface.

On the other hand, in the capacitive touch module according to the present invention, in the capacitive touch module to be touched by the capacitive touch screen, a plurality of touch units made of a conductive rubber material and having a contact surface to be capacitively touched on the capacitive touch screen and a frame portion having at least one conductive area arranged on one side of the plurality of touch units in a specified geometric relationship and transmitting the human body's capacitance to the touch unit, wherein the contact surface of the touch unit has a diameter of 5 mm ( It is manufactured in the shape of an oval or polygon having a circular contact surface of ±0.5 mm) to 7 mm (± 0.5 mm), or a contact area corresponding to the circular contact surface.

On the other hand, in the capacitive touch module according to the present invention, in the capacitive touch module to be touched by the capacitive touch screen, a plurality of touch units made of a conductive rubber material and having a contact surface to be capacitively touched on the capacitive touch screen and a frame portion having at least one conductive area on one side of the plurality of touch units arranged in a specified geometric relationship and transmitting the human body's capacitance to the touch unit, wherein the contact surface of the touch unit has a diameter of 4 mm ( It is manufactured in the shape of an oval or polygon having a circular contact surface of ±0.5 mm) to 7 mm (± 0.5 mm), or a contact area corresponding to the circular contact surface.

On the other hand, in the capacitive touch module according to the present invention, in the capacitive touch module to be touched by the capacitive touch screen, a plurality of touch units made of a conductive rubber material and having a contact surface to be capacitively touched on the capacitive touch screen and a frame portion having at least one conductive area disposed on one side of the plurality of touch units in a specified geometric relationship and transmitting the human body's capacitance to the touch unit, wherein the contact surface of the touch unit has a diameter of 3 mm ( It is manufactured in the shape of an oval or polygon having a circular contact surface of ±0.5 mm) to 7 mm (± 0.5 mm), or a contact area corresponding to the circular contact surface.

According to the present invention, as for the electrical resistance of the touch part, a resistance value measured between a contact part contacting the conductive area of the frame part among parts of the touch part and the contact surface may be 300 Ω or less. Alternatively, as for the electrical resistance of the touch part, a resistance value measured between a contact part that contacts the conductive region of the frame part and the contact surface among parts of the touch part may be 250 Ω or less. Alternatively, as for the electrical resistance of the touch unit, a resistance value measured between a contact portion contacting the conductive region of the frame portion among portions of the touch portion and the contact surface may be 200 Ω or less. Alternatively, as for the electrical resistance of the touch unit, a resistance value measured between a contact portion contacting the conductive region of the frame portion among portions of the touch portion and the contact surface may be less than or equal to 150Ω. Alternatively, as for the electrical resistance of the touch part, a resistance value measured between a contact part contacting the conductive region of the frame part and the contact surface among the parts of the touch part may be less than or equal to 120Ω.

According to the present invention, the number of the touch units may be 3 to 5. Alternatively, the number of the touch units may be four or more. Alternatively, the number of the touch units may be 5 or more.

According to the present invention, the hardness of the touch part may be manufactured to a hardness of 60 (±5) to 70 (±5) based on the Shore A hardness scale. Alternatively, the hardness of the touch part may be manufactured to a hardness of 50 to 80 based on a Shore A hardness scale.

According to the present invention, the geometrical relationship may include a geometrical relationship that excludes a structure in which three or more touch parts are arranged in a row among the plurality of touch parts.

According to the present invention, the geometric relationship may include an arbitrary arrangement structure in which three or more touch units among the plurality of touch units are not arranged in a line.

According to the present invention, the geometrical relationship is achieved by disposing at least one touch unit among a plurality of touch units disposed on one side of the frame unit provided in different touch modules of the same type at another position spaced apart by a minimum identification distance of at least 3.5 mm. It includes a geometric relationship in which the geometric relationship of the touch units provided in different touch modules of the same type is not overlapped, and the minimum identification distance is between the centers of the comparison target touch units provided in one region of the frame unit provided in other touch modules of the same type. distance may be included.

According to the present invention, the geometric relationship includes a geometric relationship in which a plurality of touch units disposed on the frame portion are spaced apart from each other by a minimum recognition distance of 7.5 mm or more, and the minimum recognition distance is a touch contacting the capacitive touch screen. It may include the distance between the negative contact surface outlines.

According to the present invention, the geometrical relationship divides one side region of the frame part into divided regions with a number less than the number of touch units, and arranges one touch unit at an arbitrary calculated position on each divided region, at least among the divided regions. It may include a geometric relationship of further disposing at least one touch unit at a designated position on one designated area.

On the other hand, in the capacitive touch module according to the present invention, in the capacitive touch module to be touched by the capacitive touch screen, a plurality of touch units made of a conductive rubber material and having a contact surface to be capacitively touched on the capacitive touch screen and a frame portion having at least one conductive area disposed on one side of the plurality of touch units in a specified geometric relationship and transmitting the human body's capacitance to the touch unit, wherein the contact surface of the touch unit is 5*5 mm (±0.5mm) to 6*6mm (±0.5mm) of a square contact surface, or may be manufactured in a circular or polygonal shape having a contact area corresponding to the square contact surface.

On the other hand, in the capacitive touch module according to the present invention, in the capacitive touch module to be touched by the capacitive touch screen, a plurality of touch units made of a conductive rubber material and having a contact surface to be capacitively touched on the capacitive touch screen and a frame portion having at least one conductive area disposed on one side of the plurality of touch units in a specified geometric relationship and transmitting the human body's capacitance to the touch unit, wherein the contact surface of the touch unit is 4*4 mm (±0.5mm) to 6*6mm (±0.5mm) of a square contact surface, or may be manufactured in a circular or polygonal shape having a contact area corresponding to the square contact surface.

On the other hand, in the capacitive touch module according to the present invention, in the capacitive touch module to be touched by the capacitive touch screen, a plurality of touch units made of a conductive rubber material and having a contact surface to be capacitively touched on the capacitive touch screen and a frame portion having at least one conductive area disposed on one side of the plurality of touch units in a specified geometric relationship and transmitting human capacitance to the touch unit, wherein the contact surface of the touch unit is 3*3 mm (±0.5mm) to 6*6mm (±0.5mm) of a square contact surface, or may be manufactured in a circular or polygonal shape having a contact area corresponding to the square contact surface.

According to the present invention, when a touch module in which a plurality of touch units made of a conductive rubber material are arranged in a pre-designed geometric relationship is used as an identification means and/or authentication means for providing various services by touching the capacitive touch screen, the touch The touch rate of the module (= probability of recognizing all touch points touched on the capacitive touch screen) and authentication rate (= probability of successful authentication by matching the geometric relationship between the touch points touched on the capacitive touch screen and the stored geometric relationship) It has the advantage of providing stable service while maintaining the level above a certain level required by the workplace.

1A and 1B show a touch module according to an embodiment of the present invention.
2A to 2H are diagrams illustrating a manufacturing process of a touch module according to an embodiment of the present invention.
3 is a view showing a structure of a touch unit according to an embodiment of the present invention.
4 is a diagram illustrating a geometric relationship of a touch unit provided in a touch module according to an embodiment of the present invention.
5A and 5B are diagrams illustrating an embodiment using a touch module according to an embodiment of the present invention.

Hereinafter, the principle of operation of the preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings and description. However, the drawings shown below and the following description are for preferred implementation methods among various methods for effectively explaining the features of the present invention, and the present invention is not limited only to the following drawings and description.

That is, the following embodiment corresponds to an embodiment of a preferred union form among numerous embodiments of the present invention, and an embodiment in which a specific configuration is omitted in the following embodiment, or a function implemented in a specific configuration is a specific configuration The divided embodiment, or the embodiment in which the functions implemented in two or more components are integrated into any one component, etc., are clearly stated to be within the scope of the present invention, even if not separately mentioned in the following examples. Therefore, it is clearly specified that various embodiments corresponding to a subset or a complement can be divided retroactively from the filing date of the present invention based on the following examples.

In addition, in the following description of the present invention, if it is determined that a detailed description of a related well-known function or configuration may unnecessarily obscure the gist of the present invention, the detailed description thereof will be omitted. And the terms to be described later are terms defined in consideration of functions in the present invention, which may vary according to the intention or custom of the user or operator. Therefore, the definition should be made based on the content throughout the present invention.

As a result, the technical spirit of the present invention is determined by the claims, and the following examples are one means for efficiently explaining the technical spirit of the present invention to those of ordinary skill in the art to which the present invention belongs. only

1a and 1b show the touch module 100 according to an embodiment of the present invention.

In more detail, FIGS. 1A and 1B show a plurality of touch parts 105 made of a conductive rubber material and a frame part 110 for arranging the plurality of touch parts 105 in a specified geometric relationship. An embodiment of the touch module 100 is shown, and those of ordinary skill in the art to which the present invention pertains may refer to and/or modify various types of the touch module 100 manufactured by referring to and/or modifying the drawings 1a and 1b. Although the implementation method can be inferred, the present invention is made by including all the inferred implementation methods, and the technical characteristics are not limited only to the implementation method illustrated in FIG. 1 .

1A and 1B, the touch module 100 includes a plurality of touch units 105 made of a conductive rubber material and having a contact surface 305 to be capacitively touched on the capacitive touch screen; and a frame part 110 having at least one conductive area on one side of which the touch part 105 is arranged in a specified geometric relationship and transmits the human body's capacitance to the touch part 105 . Preferably, FIG. 1A shows a touch module in which a plurality (eg, five) of touch units 105 made of a conductive rubber material are arranged in an arbitrary unique geometric relationship (ie, a different geometric relationship for each touch module 100 ). (100) is shown, and FIG. 1B is a diagram in which 12 touch units 105 are arranged in a geometric relationship in the form of a lattice structure, and a designated number (eg, 2 to 5) among the 12 touch units 105 of the lattice structure is shown. ) shows the touch module 100 having the touch part 105 of a conductive rubber material. However, the embodiment of the touch module 100 of the present invention is not limited to the forms shown in Figs. 1a and 1b, and various embodiments modifying it according to the intention of those skilled in the art (eg, Fig. 1b by modifying the quadrangular lattice structure to 6 It can be transformed into an embodiment having the touch unit 105 in a prismatic honeycomb lattice structure, etc.), and the present invention clearly states that all such deformable embodiments are included within the scope of the right.

The touch unit 105 is a generic term for components that are capacitively touched on the capacitive touch screen among the components of the touch module 100, and is made of a conductive rubber material, and is made of a conductive rubber material, and one side area 115 of the frame unit 110 ( For example, among the regions of the touch module 100 , the touch unit 105 to be touched on the capacitive touch screen is exposed in a specified geometric relationship.

The frame unit 110 is a generic term for components in which a plurality of touch units 105 are arranged in a specified geometric relationship among the components of the touch module 100, and a plurality of touch units 105 made of a conductive rubber material are provided in a specified geometrical relationship. It comprises a one side area 115 arranged in a relationship and at least one side conductive area for transferring the human body's capacitance to the plurality of touch units 105 made of the conductive rubber material. The one side region 115 of the frame part 110 may be manufactured in various plate structures such as a flat plate structure and/or a curved plate structure.

The touch module 100 connects the handle portion 500 having a predetermined conductive area to the frame portion 110 and electrically connects the conductive area of the handle portion 500 and the conductive area of the frame portion 110 . It may be manufactured in the form of a painting connected to , or it may be mounted on a painting having the handle unit 500 . Alternatively, the touch module 100 may be mounted on a card-shaped object or manufactured in a card form by forming the frame portion 110 and the touch unit 105 to have a thin thickness. The appearance of the object on which the touch module 100 is mounted or the object including the touch module 100 can be variously modified or applied according to the intention or service field of those skilled in the art, and the present invention is not limited thereto. It is clear that

According to the implementation method of the present invention, the touch part 105 is made of a conductive rubber material manufactured by mixing conductive carbon (eg, conductive carbon or metal powder included) and rubber, and the conductive rubber is applied to the designated touch part 105 . ) in the shape of compression molding or injection molding, and/or cutting processing.

The conductive rubber has a characteristic that as the mixing ratio of conductive carbon increases, the electrical resistance of the touch part 105 decreases (or electrical conductivity increases), and at the same time, the hardness of the touch part 105 increases and becomes hard. , Conversely, as the mixing ratio of the rubber increases, the electrical resistance of the touch unit 105 increases (or the electrical conductivity decreases), and at the same time, the hardness of the touch unit 105 decreases and becomes soft.

According to the embodiment of the present invention, the touch module 100 is manufactured in a form in which the touch unit 105 protrudes to a predetermined height on one side area 115 of the frame unit 110 (however, the touch module 100) When manufactured in the form of a card, it is the same height as the frame unit 110 (eg, it can be manufactured at the reference height '0' of the one side area 115 of the frame unit 110). If the frame unit 110 has a flat plate structure, the height of the touch unit 105 disposed on the frame unit 110 is designed to have the same height for simultaneous touch, or to a different height for sequential touch. may be designed, but even if they are designed to have the same height for simultaneous touch, the height of each touch unit 105 may vary within the tolerance range in the process of manufacturing the actual touch module 100, and for sequential touch, each touch unit ( When the heights of the 105 are designed to be different heights, the heights of the respective touch units 105 are naturally manufactured differently. In addition, even if each touch unit 105 is designed to have the same height in design for simultaneous touch and each touch unit 105 is manufactured to have the same height through various error corrections in the manufacturing process, the process of using the touch module 100 The height of each touch unit 105 is gradually changed due to wear or aging of the touch unit 105 . The plurality of touch units 105 provided in the touch module 100 of the present invention should all be recognized for touch on the capacitive touch screen even if the process error, wear, or aging as described above occurs, and has appropriate hardness and electrical characteristics (eg, , electrical resistance or electrical conductivity, etc.) and contact area.

According to the implementation method of the present invention, the hardness of the touch part 105 made of a conductive rubber material is preferably manufactured to a hardness of 60 (±5) to 70 (±5) based on the Shore A hardness scale, and the touch point The hardness of the touch unit 105 according to the contact area in which the contact surface 305 of the touch unit 105 contacts the capacitive touch screen may be manufactured to a hardness of 50 to 80 based on the Shoa A hardness scale.

When the hardness of the touch part 105 is manufactured to exceed 80 based on the Shore A hardness scale, it is necessary to increase the mixing ratio of conductive carbon in the process of manufacturing the conductive rubber constituting the touch part 105. In this case, the conductive The resistance of the rubber decreases and the electrical conductivity increases to improve the electrical properties of the touch unit 105, but on the contrary, it is difficult to implement touch recognition for all of the plurality of touch units 105, so the touch rate of the touch module 100 ( = Probability of recognizing all the touch points touched on the capacitive touch screen) increases, and such a sharp decrease in the touch rate increases the authentication rate of the touch module 100 (= touches on the capacitive touch screen). The probability of successful authentication by matching the geometric relationship of a plurality of touch points and the stored geometric relationship) is sharply reduced. That is, when the hardness of the conductive rubber exceeds 80 based on the Shore A hardness scale, even if all the conductive rubbers are designed to touch the flat-panel capacitive touch screen during the design process of the touch module 100, the manufacturing process Due to process error, abrasion or aging of conductive rubber, some conductive rubber touches all of the designed contact area to the capacitive touch screen, while other conductive rubbers do not touch the capacitive touch screen, or the designed contact The probability that all touches will not be recognized increases as much as the area. In order to manufacture the touch part 105 with a hardness of more than 80 to enable all touches, the manufacturing cost in the manufacturing process increases, and even if all of the touch parts 105 are made to be touchable, the touch module may be caused by wear or aging of the conductive rubber. The touch rate and authentication rate of (100) are continuously decreased. If the hardness of the touch unit 105 is manufactured to exceed 90 based on the Shore A hardness scale, the electrical characteristics of the touch unit 105 will be further improved, but the problem of a sharp decrease in the touch rate and authentication rate as described above occurs, of course. , not only is easily broken even by a slight impact at the time of touch, but also increases the probability of damaging the surface of the capacitive touch screen during the touch process.

On the other hand, when the hardness of the touch part 105 is manufactured to be less than 50 based on the Shore A hardness scale, it is necessary to increase the mixing ratio of rubber in the process of manufacturing the conductive rubber constituting the touch part 105. In this case, the conductive rubber Not only does the electrical conductivity decrease by increasing the resistance of the touch screen, even when a slight horizontal force is applied while the touch unit 105 is touched on the capacitive touch screen, the midpoint of the touched area on the capacitive touch screen moves and the touch module The authentication rate of (100) (= the probability of successful authentication by matching the geometric relationship between a plurality of touch points touched on the capacitive touch screen and the stored geometric relationship) is sharply reduced. That is, the capacitive touch screen using a human finger as an input means calculates the midpoint of the touched surface and recognizes it as a touch point. If the touched area on the capacitive touch screen is deformed, of course, the midpoint of the touched surface is also spaced apart, As a result, the geometrical relationship of the plurality of touch points is distorted, so that the authentication rate of the touch module 100 is sharply reduced. Conductive rubber may also be used in a touch pen used as an input means of a conventional capacitive touch screen. In this case, the rubber compounding ratio is increased for a soft writing and touch feeling, and the hardness is less than 50. Of course, the conductive rubber of the touch pen, which provides only one point touch and is used as an input means, is manufactured with a hardness of less than 50, so even if the electrical properties are poor, there is no problem at all to use it as a one-point input means, and in some cases, the pen pressure can be reflected. It may have a feature that can be used as an input means. However, when the touch module 100 is manufactured using such a conductive rubber material, even if all the touch units 105 provided in the touch module 100 are touched by the capacitive touch screen, the The low resistance not only reduces the touch rate of the touch module 100 by dispersing the electrostatic change of the capacitive touch screen compared to a single point touch, but also reduces the touch module ( 100) causes the problem of a sharp drop in the authentication rate. For example, the hardness of the touch part 105 is set to a hardness of 60 (±5) to 70 (±5) based on the Shore A hardness scale, and the contact surface 305 of the touch part 105 is 6 mm in diameter (± 0.5 mm). ) of the circular contact surface 305 and the number of touch units 105 to be all touched as five, when the touch module 100 is manufactured, both the touch rate and the authentication rate of the touch module 100 are Gaussian probability distribution of 95% or more. However, in the case of manufacturing the hardness of the touch unit 105 to less than 50 under the same conditions, both the touch rate and the authentication rate of the touch module 100 sharply decrease to less than 20%, so that the touch module 100 is an effective identification means and / Or, it cannot be used as a means of authentication.

According to the embodiment of the present invention, the touch rate of the touch module 100 increases as the electrical resistance of the plurality of touch units 105 decreases (eg, the resistance value approaches 0 Ω). However, since the conductive rubber constituting the touch part 105 contains a certain ratio of rubber in addition to the conductive carbon having high conductivity, it has no choice but to have an electrical resistance of a certain value. According to the present invention, the electrical resistance of the conductive rubber has a correlation with the mixing ratio of the conductive carbon and rubber constituting the conductive rubber, and the mixing ratio of the conductive carbon and the rubber has a correlation with the hardness of the conductive rubber.

On the other hand, the capacitive touch screen using a human finger as an input means can recognize the capacitive touch even if the amount of change in the electrostatic change of the capacitive touch screen is small as the touched area is larger, which is the contact surface 305 of the touch unit 105 . ) is large, even if the electrical resistance of the touch unit 105 is small, capacitive touch recognition is possible. This means that the smaller the contact surface 305 of the touch unit 105 is, the smaller the electrical resistance of the touch unit 105 is to be able to recognize the capacitive touch, and as a result, the electrical resistance of the touch unit 105 is the contact surface. It also has a certain correlation with the area of (305).

In addition, in a capacitive touch screen using a human finger as an input means, a circuit for detecting a change in electrostatic due to a capacitive touch detects a capacitive touch using a series circuit formed with the human body at the time when the capacitive touch occurs. designed to do That is, the capacitive touch screen is a human body when a human finger touches (or approaches) in a state in which a micro current flows (or in a state in which a high frequency is formed) in the conductive medium (eg, ITO) of the touch panel. A capacitive touch is recognized by detecting a change in electrostatic by using a series circuit structure formed with and reading the position. At this time, as the number of touch points simultaneously touched in the series circuit increases, each The probability that the amount of change in the capacitance of the touch points is out of the range set to be detectable by a valid capacitive touch increases. For example, in the case of some capacitive touch screens, even if a plurality of touch points are touched, if each touch point connects a different cell and a series circuit in the touch cell structure of the capacitive touch screen, all of the plurality of touch points can be recognized, but which When a plurality of touch points are connected to one series circuit at the same time, it may not be recognized all of them (for example, when three or more touch points connect a series circuit to one series circuit, all three touch points cannot be recognized). there is. Therefore, due to the characteristics of the series circuit structure for recognizing the capacitive touch in the capacitive touch screen, the electrical resistance of the touch unit 105 is the number of touch units 105 that can be provided in the touch module 100 so as to be recognizable. also has a certain correlation. According to the embodiment of the present invention, the geometrical relationship with respect to the plurality of touch units 105 provided in the one side region 115 of the frame unit 110 is three or more touch units ( It is preferable to include a geometric relationship excluding the in-line arrangement structure in which 105) is arranged in a line, and preferably, the geometric relationship includes three or more touch parts 105 among the plurality of touch parts 105 as shown in FIG. 1A. It may include an arbitrary arrangement structure that is not arranged in a line.

A preferred embodiment of the contact surface 305 of the touch unit 105 according to the present invention is as follows.

According to the first contact surface 305 embodiment of the present invention, the contact surface 305 of the touch unit 105 is a circular contact surface 305 having a diameter of 6 mm (±0.5 mm) to 7 mm (± 0.5 mm), or It is preferable to be manufactured in an elliptical or polygonal shape having a contact area corresponding to the circular contact surface 305 .

According to the second contact surface 305 embodiment of the present invention, the contact surface 305 of the touch part 105 is a circular contact surface 305 having a diameter of 5 mm (±0.5 mm) to 7 mm (± 0.5 mm), or It is preferable to be manufactured in an elliptical or polygonal shape having a contact area corresponding to the circular contact surface 305 .

According to the third contact surface 305 embodiment of the present invention, the contact surface 305 of the touch unit 105 is a circular contact surface 305 having a diameter of 4 mm (±0.5 mm) to 7 mm (± 0.5 mm), or It is preferable to be manufactured in an elliptical or polygonal shape having a contact area corresponding to the circular contact surface 305 .

According to the fourth contact surface 305 embodiment of the present invention, the contact surface 305 of the touch unit 105 is a circular contact surface 305 having a diameter of 3 mm (±0.5 mm) to 7 mm (± 0.5 mm), or It is preferable to be manufactured in an elliptical or polygonal shape having a contact area corresponding to the circular contact surface 305 .

According to the fifth contact surface 305 embodiment of the present invention, the contact surface 305 of the touch unit 105 is a square contact surface 305 of 5 * 5 mm (±0.5 mm) to 6 * 6 mm (± 0.5 mm). ), or preferably manufactured in a circular or polygonal shape having a contact area corresponding to the square contact surface 305 .

According to the sixth contact surface 305 embodiment of the present invention, the contact surface 305 of the touch unit 105 has a square contact surface 305 of 4 * 4 mm (±0.5 mm) to 6 * 6 mm (± 0.5 mm). ), or preferably manufactured in a circular or polygonal shape having a contact area corresponding to the square contact surface 305 .

According to the seventh contact surface 305 embodiment of the present invention, the contact surface 305 of the touch unit 105 is a square contact surface 305 of 3*3 mm (±0.5 mm) to 6*6 mm (± 0.5 mm). ), or preferably manufactured in a circular or polygonal shape having a contact area corresponding to the square contact surface 305 .

According to the first to seventh contact surface 305 embodiments, the contact surface 305 of the touch unit 105 has a contact area (eg, 38.465 mm 2 ) corresponding to the circular contact surface 305 of 7 mm (±0.5 mm). (+5.69㎟))) is preferably manufactured with a contact area not greater than. According to the embodiment of the present invention, as the contact area corresponding to the contact surface 305 of the touch unit 105 increases, the touch rate of the touch module 100 increases. However, in the touch module 100 of the present invention, a geometric relationship formed through a plurality of touch units 105 disposed on one side region 115 of the frame unit 110 (or a geometric relationship formed by a plurality of touch units 105 ) It is characterized in that the relationship and the geometric characteristic relationship that combines the touch characteristics occurring at the time of touch) are used as the identification means and/or the authentication means. Accordingly, as the number of touch units 105 disposed on one side region 115 of the frame unit 110 increases and/or as the area of one side region 115 of the frame unit 110 increases, the plurality of the plurality of touch units 105 increases. The number of cases of geometrical relationships formed through the touch units 105 increases, and the uniqueness of the touch module 100 (= the geometric relation for the plurality of touch units 105 disposed in each touch module 100 is each Each touch module (100) is arranged in a unique geometric relationship different from each other) is improved. However, the area of the capacitive touch screen to be touched by the touch module 100 is limited, and the area of one side region 115 of the touch module 100 to be touched by the capacitive touch screen is larger than the area of the capacitive touch screen. can't be big For example, if the horizontal/vertical length of the capacitive touch screen is 75 mm * 50 mm, the one side area 115 of the touch module 100 has a circular area within 50 mm in diameter, or a diagonal length of 50 mm. It must be manufactured with a smaller square area (however, instead of reducing the diagonal length to less than 50 mm by forming a groove in the corner of the square, the length of one side of the square can be expanded by the radius of the groove). That is, the area of the one side region 115 of the frame unit 110 provided in the touch module 100 is limited by the area of the capacitive touch screen. Accordingly, the uniqueness of the touch module 100 is variable according to the contact area of the contact surface 305 of the touch unit 105 disposed in the one side region 115 of the limited area, and corresponds to the contact surface 305 of the touch unit 105 . As the contact area decreases, the number of touch units 105 that can be disposed on one side area 115 of a limited area and/or the number of geometric relationships formed by the designated number of touch units 105 increases. Therefore, in the present invention, the maximum threshold value of the contact area formed by the contact surface 305 of the touch unit 105 is defined as a contact area that is not larger than the contact area corresponding to the circular contact surface 305 of 7 mm (± 0.5 mm). do.

Meanwhile, the minimum threshold value of the contact area formed by the contact surface 305 of the touch unit 105 may be different for each capacitive touch screen. Due to the characteristics of a capacitive touch screen that uses a single point touch using a human finger as an input means, the capacitive touch screen requires a touch area of a certain area or more corresponding to a finger touch to be a stable single point touch (here, a stable single point touch). This means a touch that provides a finger touch success rate of over 95% when there is no contamination or foreign substances on the surface of the capacitive touch screen. For manufacturers of devices equipped with capacitive touch screens, the minimum area for a stable one-point touch is not disclosed). In the case of some capacitive touch screens, it provides a stable one-point touch in a contact area greater than or equal to the area corresponding to the circular contact surface 305 with a diameter of 6 mm (± 0.5 mm), and in some other capacitive touch screens, a diameter of 3 mm (± It also provides a stable one-point touch even in a contact area of an area corresponding to the circular contact surface 305 of 0.5 mm).

A preferred embodiment of the electrical resistance of the touch unit 105 according to the present invention is as follows.

According to the embodiment of the present invention, the touch unit 105 has a contact surface 305 that is touched by the capacitive touch screen, and a predetermined contact portion that comes into contact with the conductive area of the frame unit 110 . The value of the resistance value of the touch unit 105 is the contact between the contact surface 305 and the farthest position (for example, the position furthest in the vertical direction based on the surface of the capacitive touch screen) using a predetermined resistance measuring instrument. It means a measured resistance value obtained by measuring the resistance between the part and the contact surface 305 .

According to the first resistance embodiment of the present invention, the electrical resistance of the touch unit 105 is preferably manufactured such that the measured resistance value of the touch unit 105 is 300Ω or less.

According to the second resistance embodiment of the present invention, the electrical resistance of the touch unit 105 is preferably manufactured such that the measured resistance value of the touch unit 105 is 250 Ω or less.

According to the third resistance embodiment of the present invention, the electrical resistance of the touch unit 105 is preferably manufactured such that the measured resistance value of the touch unit 105 is 200 Ω or less.

According to the fourth resistance embodiment of the present invention, the electrical resistance of the touch unit 105 is preferably manufactured such that the measured resistance value of the touch unit 105 is 150Ω or less.

According to the fifth resistance embodiment of the present invention, the electrical resistance of the touch unit 105 is preferably manufactured such that the measured resistance value of the touch unit 105 is 120Ω or less.

According to the sixth resistance embodiment of the present invention, the electrical resistance of the touch unit 105 is preferably manufactured such that the measured resistance value of the touch unit 105 is 100Ω or less.

According to the first to sixth resistance embodiments, the contact surface 305 of the touch unit 105 is preferably manufactured so that the measured resistance value does not exceed 300Ω. According to the embodiment of the present invention, the lower the electrical resistance of the touch unit 105, the higher the touch rate of the touch module 100. However, due to the characteristics of the conductive rubber constituting the touch unit 105 , if the mixing ratio of the conductive carbon is increased to lower the electrical resistance of the touch unit 105 , the hardness increases. Conversely, if the mixing ratio of rubber is increased to lower the hardness of the touch unit 105 , the electrical resistance of the touch unit 105 is increased. As described above, since the conductive rubber used in the conventional touch pen is used as a one-point touch-based input means, even if the resistance of the conductive rubber is high (eg, 1,000 Ω or more), there is no problem in using it. In addition, if the contact area of the conductive rubber used in the touch pen is increased (eg, a circular contact area of 12 mm or more in diameter), it can be used even if the resistance of the conductive rubber is very high (eg, 10^6Ω or more). However, in the touch module 100 of the present invention, a geometric relationship formed through a plurality of touch units 105 disposed on one side region 115 of the frame unit 110 (or a geometric relationship formed by a plurality of touch units 105 ) It is characterized in that the relationship and the geometric characteristic relationship that combines the touch characteristics occurring at the time of touch) are used as the identification means and/or the authentication means. Therefore, due to the characteristics of the capacitive touch screen using a series circuit structure for capacitive touch sensing, in order to touch the plurality of touch units 105 provided in the touch module 100 to the capacitive touch screen to recognize all touches, the touch unit The electrical resistance of (105) should be low. However, due to the characteristics of the conductive rubber manufactured by mixing conductive carbon and non-conductive rubber, the resistance of the touch unit 105 cannot be lowered to the level of conductive carbon. Based on the hardness range of the touch unit 105 according to the present invention, the minimum measured resistance value of the touch unit 105 may be 70Ω or more, but the present invention is not limited thereto. It can be lowered according to the method or the particle size of each powder. Meanwhile, the recognition of all touches for the plurality of touch units 105 is also correlated with the number of touch units 105 and/or a contact area corresponding to the contact surface 305 of the touch units 105 . For example, as the number of touch units 105 to be recognized for touch increases, the resistance of the touch unit 105 should be low, and as the contact area of the touch unit 105 increases, the resistance of the touch unit 105 may not be low. .

A preferred embodiment of the electrical resistance of the touch units 105 in consideration of the number of touch units 105 to be recognized for touch is as follows.

According to the first number-resistance embodiment of the present invention, when the number of touch units 105 to be recognized for touch is 3 to 5, the electrical resistance of the touch unit 105 is measured by the touch unit 105 . The resistance value may be manufactured to be 300 Ω or less, and for a stable touch rate of 95% or more, it is preferable to manufacture the measured resistance value of the touch unit 105 to 250 Ω or less. For example, when the number of touch units 105 to be recognized for touch is 3 to 5, slight contamination (eg, between the capacitive touch screen and the touch unit 105 ) occurring in the capacitive touch screen in a living environment. In order to provide a touch rate of 95% or more stable even by the degree of contamination with fingerprints), it is preferable to manufacture the measured resistance value of the touch unit 105 to 250Ω or less, and the capacitive touch screen is in a clean state (= If a touch rate of 95% or more is provided in the state of no contamination) or a touch rate of less than 95% (preferably, 80% or more) is provided in the contamination of the living environment, the measured resistance value of the touch unit 105 is 300Ω It can be manufactured as follows. However, when the measured resistance value of the touch unit 105 is manufactured to exceed 300 Ω, the touch rate sharply decreases to less than 20% due to living environment pollution on the capacitive touch screen, so the measured resistance value of the touch unit 105 is It is preferable to manufacture at 300 Ω or less.

According to the second number-resistance embodiment of the present invention, when the number of touch units 105 to be recognized for all touches is four or more (however, in this case, the maximum number of touch units 105 is the maximum of each capacitive touch screen). (including the number of multi-touch), the electrical resistance of the touch unit 105 may be manufactured such that the measured resistance value of the touch unit 105 is 200 Ω or less, and for a touch rate of 95% or more, the touch unit 105 It is preferable to make the measured resistance value of 150Ω or less. For example, when the number of touch units 105 to be recognized for touch is 4 or more, the measured resistance value of the touch unit 105 is set to 150Ω or less in order to provide a stable touch rate of 95% or more even due to environmental pollution. Preferably, the capacitive touch screen provides a touch rate of 95% or more in a clean state (= no contamination state) or a touch rate of less than 95% (preferably 80% or more) in pollution of the living environment If provided, the measured resistance value of the touch unit 105 may be manufactured to be 200Ω or less. On the other hand, when the number of the touch units 105 is 4 or 5, a touch rate of 95% or more can be provided for the capacitive touch screen in a clean state up to the measured resistance value of the touch unit 105 is 300 Ω, but the touch When the measured resistance value of the part 105 is manufactured to exceed 300 Ω, the touch rate is sharply reduced to less than 20% due to pollution of the living environment for the capacitive touch screen.

According to the third number-resistance embodiment of the present invention, when the number of touch units 105 to be recognized for all touches is 5 or more (however, in this case, the maximum number of touch units 105 is the maximum of each capacitive touch screen) (including the number of multi-touches), the electrical resistance of the touch unit 105 may be manufactured such that the measured resistance value of the touch unit 105 is 120Ω or less. For example, when the number of touch units 105 to recognize all touches is 5 or more, the measured resistance value of the touch units 105 is set to 120Ω or less in order to provide a stable touch rate of 95% or more even due to environmental pollution. It is preferable to manufacture On the other hand, when the number of the touch units 105 is 5, a touch rate of 95% or more can be provided for the capacitive touch screen in a clean state up to the measured resistance value of the touch unit 105 is 300 Ω, but the touch unit ( 105), when the measured resistance value exceeds 300Ω, the touch rate drops to less than 20% due to pollution of the living environment for the capacitive touch screen.

In the first to third number-resistance embodiments, the contact surface 305 of the touch unit 105 has a contact area corresponding to the circular contact surface 305 of 7 mm (±0.5 mm) (eg, 38.465 mm 2 (+5.69)). mm2))), and the contact area exceeding this is excluded from the consideration of the measured resistance value.

Meanwhile, according to a preferred embodiment of the electrical resistance of the touch unit 105 in consideration of the hardness of the touch unit 105, under the condition that the hardness of the touch unit 105 is 70 (±5) or less based on the Shoa A hardness scale, life The electrical resistance of the touch unit 105 to provide a stable touch rate of 95% or more even in environmental pollution is preferably manufactured so that the measured resistance value is 120Ω or less. When the measured resistance value of the touch unit 105 is 120Ω or less, a stable touch rate may be provided regardless of the number of touch units 105 .

In an embodiment of the present invention, for convenience, the characteristics of the present invention will be described by assuming that the number of the plurality of touch units 105 provided in the touch module 100 is N, which is made of a conductive rubber material that satisfies the above conditions. , the number N of the touch units 105 is not limited to a specific value. For example, in the embodiment of FIG. 1A , the number of touch parts 105 made of conductive rubber provided in the touch module 100 is 'N=5', and in the embodiment of FIG. 1B , a plurality of touch units provided in the touch module 100 are 'N=5'. The number of touch units 105 is 12, but among them, the number of touch units 105 made of a conductive rubber material is 'N<12'.

2a to 2h are diagrams illustrating a manufacturing process of the touch module 100 according to an embodiment of the present invention.

In more detail, FIGS. 2a to 2h show the process of manufacturing the touch module 100 by arranging N touch parts 105 made of a conductive rubber material in a specified geometric relationship and arranging them on the frame part 110, Those of ordinary skill in the art to which the present invention pertains will be able to infer various implementation methods for the manufacturing process of the touch module 100 by referring to and/or modifying the drawings 2a to 2h, The invention is made including all the implementation methods inferred above, and the technical characteristics are not limited only to the implementation methods shown in Figs. 2a to 2h. Therefore, the present invention includes all implementation methods of manufacturing the touch module 100 by selectively combining the configuration of two or more implementation methods among the implementation methods shown in FIGS. 2a to 2h or omitting some configurations as the scope of the right. to make it clear that

The touch module 100 according to the present invention includes N touch units 105 made of a conductive rubber material, and a frame unit 110 for fixing the N touch units 105 by arranging and fixing the N touch units 105 in a specified geometric relationship. When the touch module 100 (or an object on which the touch module 100 is mounted) comes into contact with the human body, the frame unit 110 transfers the capacitance stored in the human body to the touch unit 105 . A conductive region is provided on at least one side as much as possible.

Referring to the embodiment of FIG. 2A , the frame part 110 includes a top plate 200 supporting the N touch parts 105 and a middle plate part for embedding the N touch parts 105 in a specified geometric relationship ( 205) and a lower plate 210 exposing the N touch units 105 to the outside according to a specified geometric relationship.

The top plate 200 is a generic name for a plate supporting the N touch parts 105 disposed on the frame part 110 in a specified geometric relationship, and the N touch parts 105 are designed in a geometrical relationship with a capacitive touch. Support to touch the screen. Preferably, the upper plate 200 is made of a conductive material or includes a conductive region on at least one side. The conductive material or conductive region of the upper plate 200 is preferably electrically connected to the touch part 105 .

The middle plate part 205 is a generic term for plates on which the N touch parts 105 disposed on the frame part 110 are arranged in a specified geometric relationship, and is disposed between the upper plate part 200 and the lower plate part 210, and an embedded groove for embedding the N touch units 105 in a specified geometric relationship.

The touch unit 105 is a generic term for components that induce an electrostatic change in the capacitive touch screen when the touch module 100 is touched to the capacitive touch screen, and may preferably be made of a conductive rubber material.

The lower plate part 210 is a generic term for a plate that exposes the N touch parts 105 in a specified geometric relationship, and is disposed below the middle plate part 205 and sets the N touch parts 105 in a specified geometric relationship. It is made to include an exposure groove exposed to. The touch part 105 may protrude to the outside of the lower plate part 210 at a height designed through the exposure groove, or may be manufactured at the same height as the lower plate part 210 .

In the embodiment of FIG. 2a, the touch module 100 prepares an upper plate 200, a middle plate 205, a touch part 105 and a lower plate 210 as shown in FIG. 2a (a), and FIG. 2a. After laminating the upper plate 200 and the middle plate 205 as shown in (B), the touch part 105 is embedded in the recess of the middle plate 205 as shown in (C) of FIG. 2A, and then ( D), the lower plate part 210 is laminated to the middle plate part 205 so that the touch part 105 embedded in the embedding groove of the middle plate part 205 is exposed through the exposure groove of the lower plate part 210 as shown in the drawing. It can be manufactured as in (E) of 2a. The upper plate portion 200, the middle plate portion 205, and the lower plate portion 210 may be bonded through an adhesive (eg, a conductive adhesive, etc.), or may be laminated through a thermal bonding method or bolt assembly.

Referring to the embodiment of FIG. 2b , the touch module 100 includes N touch parts 105 made of a conductive rubber material and a touch plate part made of a touch plate made of a conductive rubber material integrally, The frame part 110 includes an upper plate part 200 supporting the touch plate part, and a lower plate part 210 exposing the N touch parts 105 provided in the touch plate part to the outside.

The top plate 200 is a generic term for plates supporting the N touch parts 105 disposed on the frame part 110 in a specified geometric relationship, and is preferably made of a conductive material, or includes a conductive region on at least one side. is done The conductive material or conductive region of the upper plate 200 is preferably electrically connected to the touch part 105 .

The touch plate unit is integrally manufactured by integrating the N touch units 105 made of a conductive rubber material and a touch plate made of a conductive rubber material, and the N touch units 105 are arranged in a specified geometric relationship. The touch plate part may be manufactured by cutting a conductive rubber plate of a certain thickness, or may be manufactured by compression molding.

The lower plate part 210 is a generic term for a plate that exposes the N touch parts 105 in a specified geometric relationship, is disposed below the touch plate part, and exposes the N touch parts 105 in a designated geometric relationship. It consists of an exposure groove. Preferably, the lower plate part 210 is made of a non-conductive material, or at least one side area 115 to which the touch unit 105 is exposed through the exposure groove includes a non-conductive material or a non-conductive area. .

In the embodiment of this figure 2b, the touch module 100 prepares the upper plate part 200, the touch plate part and the lower plate part 210 as shown in (a) of figure 2b, and the upper plate part 200 as shown in (b) of figure 2b. ) and the touch plate, the lower plate 210 is laminated to the touch plate so that the touch part 105 of the touch plate is exposed through the exposed groove of the lower plate 210 as shown in (c) of FIG. 2b. It can be manufactured as in (D) of 2b. The upper plate 200, the touch plate, and the lower plate 210 may be bonded through an adhesive (eg, a conductive adhesive, etc.) or may be laminated through bolt assembly.

Referring to the embodiment of FIG. 2c , the touch module 100 includes N touch parts 105 made of a conductive rubber material and a touch plate part made of a touch plate made of a conductive rubber material integrally, The frame part 110 includes an upper plate part 200 supporting the touch plate part.

The top plate 200 is a generic term for plates supporting the N touch parts 105 disposed on the frame part 110 in a specified geometric relationship, and is preferably made of a conductive material, or includes a conductive region on at least one side. is done The conductive material or conductive region of the upper plate 200 is preferably electrically connected to the touch part 105 .

The touch plate unit is integrally manufactured by integrating the N touch units 105 made of a conductive rubber material and a touch plate made of a conductive rubber material, and the N touch units 105 are arranged in a specified geometric relationship. The touch plate part may be manufactured by cutting a conductive rubber plate of a certain thickness, or may be manufactured by compression molding.

In the embodiment of Fig. 2c, the touch module 100 prepares the top plate 200 and the touch plate as shown in Fig. 2b (a), and laminates the top plate 200 and the touch plate as shown in Fig. 2c (b). can be manufactured by The upper plate 200, the touch plate, and the lower plate 210 may be bonded through an adhesive (eg, a conductive adhesive, etc.) or may be laminated through bolt assembly.

Referring to the embodiment of FIG. 2D , the frame unit 110 includes the upper plate 200 and the N touch units 105 that support the N touch units 105 by embedding them in a specified geometric relation in a specified geometric relation. It is made to include a lower plate portion 210 exposed to the outside according to the.

The top plate 200 is a generic name of a plate that supports the N touch parts 105 disposed on the frame part 110 in a specified geometric relationship and at the same time arranges the N touch parts 105 in a specified geometric relationship, Preferably, it is made of a conductive material, or includes a conductive region on at least one side. The conductive material or conductive region of the upper plate 200 is preferably electrically connected to the touch part 105 . The top plate 200 includes an embedding groove for embedding the N touch parts 105 in a specified geometric relationship.

The touch unit 105 is a generic term for components that induce a change in the electrostatic capacity of the capacitive touch screen when the touch module 100 is touched on the capacitive touch screen, and is preferably made of a conductive rubber material.

The lower plate part 210 is a generic name of a plate that exposes the N touch parts 105 in a specified geometric relationship, and is disposed below the upper plate part 200 and sets the N touch parts 105 in a specified geometric relationship. It consists of an exposure groove for exposing. Preferably, the lower plate part 210 is made of a non-conductive material, or at least one side area 115 to which the touch unit 105 is exposed through the exposure groove includes a non-conductive material or a non-conductive area. .

In the embodiment of FIG. 2d, the touch module 100 prepares the upper plate 200, the touch part 105 and the lower plate 210 as shown in (a) of FIG. 2d, and as shown in (b) of FIG. 2d. After embedding the touch unit 105 in the recess of the upper panel 200, the touch unit 105 is embedded in the recess of the upper panel 200 through the exposed groove of the lower panel 210 as shown in FIG. 2d (c). ) by laminating the lower plate part 210 to the upper plate part 200 to expose it, it can be manufactured as shown in (D) of FIG. 2D. The upper plate 200 and the lower plate 210 may be bonded through an adhesive (eg, a conductive adhesive, etc.), or may be laminated through a thermal bonding method or bolt assembly.

Referring to the embodiment of FIG. 2E or FIG. 2F , the frame unit 110 includes the upper plate 200 supporting the N touch units 105 in a specified geometric relation and the N touch units 105 in a specified geometric relation. and a lower plate 210 exposed to the outside in accordance with the .

The top plate 200 is a generic term for plates supporting the N touch parts 105 disposed on the frame part 110 in a specified geometric relationship, and is preferably made of a conductive material, or includes a conductive region on at least one side. is done The conductive material or conductive region of the upper plate 200 is preferably electrically connected to the touch part 105 .

The touch unit 105 is a generic term for components that induce a change in the electrostatic capacity of the capacitive touch screen when the touch module 100 is touched on the capacitive touch screen, and is preferably made of a conductive rubber material.

The lower plate part 210 is a generic name of a plate that exposes the N touch parts 105 in a specified geometric relationship, and is disposed below the upper plate part 200 and sets the N touch parts 105 in a specified geometric relationship. It consists of an exposure groove for exposing. Preferably, the lower plate part 210 is made of a non-conductive material, or at least one side area 115 to which the touch unit 105 is exposed through the exposure groove includes a non-conductive material or a non-conductive area. .

In the embodiment of Fig. 2e or Fig. 2f, the touch module 100 prepares the upper panel 200, the touch unit 105 and the lower panel 210 as shown in Fig. 2e or 2f (a), and Fig. 2e. Alternatively, while supporting the touch unit 105 on the upper plate 200 as shown in (B) of FIG. 2F, the upper plate 200 is supported through the exposed groove of the lower plate 210 as shown in FIG. 2E or 2F (C). By laminating the lower plate part 210 so that the touch part 105 is exposed, it may be manufactured as shown in (d) of FIG. 2e or 2f. The upper plate 200 and the lower plate 210 may be bonded through an adhesive (eg, a conductive adhesive, etc.), or may be laminated through a thermal bonding method or bolt assembly.

Referring to the embodiment of FIG. 2G or 2H, the frame part 110 includes a top plate part 200 that supports the N touch parts 105 by embedding them in a specified geometric relationship.

The top plate 200 is a generic name of a plate that supports the N touch parts 105 disposed on the frame part 110 in a specified geometric relationship and at the same time arranges the N touch parts 105 in a specified geometric relationship, Preferably, it is made of a conductive material, or includes a conductive region on at least one side. The conductive material or conductive region of the upper plate 200 is preferably electrically connected to the touch part 105 . The top plate 200 has an embedded groove for embedding the N touch parts 105 in a specified geometric relationship. The embedded groove may be implemented through cutting.

The touch unit 105 is a generic term for components that induce a change in the electrostatic capacity of the capacitive touch screen when the touch module 100 is touched on the capacitive touch screen, and is preferably made of a conductive rubber material.

In the embodiment of Fig. 2g or Fig. 2h, the touch module 100 prepares the top plate 200 and the touch unit 105 as shown in Fig. 2g or Fig. 2h (a), and in Fig. 2g or Fig. 2h (b). ), by embedding the touch unit 105 in the recess of the upper plate 200, it can be manufactured as shown in (c) of FIG. 2g or 2h. The touch part 105 may maintain a state embedded in the buried groove due to the elasticity of the conductive rubber material, or may maintain a state embedded and fixed in the upper plate part 200 through a conductive adhesive.

In the embodiment of FIGS. 2A to 2H , the N touch units 105 fixed to the frame unit 110 of each touch module 100 form a unique geometric relationship that is different for each touch module 100 . It is preferable to have However, in addition to the geometric relationship formed by the N touch units 105 , identification and/or authentication characteristics are provided to the touch module 100 , or the touch module 100 (or the touch module 100 ) is mounted. When an authentication means associated with the geometric relationship of the N touch units 105 is provided in one object or a place where the touch module 100 is operated, etc.), the geometric shape formed by the N touch units 105 is provided. The uniqueness of the relationship is not necessarily preserved.

Meanwhile, the area of one side region 115 of the frame unit 110 provided in the touch module 100 is finite, and the N touch units 105 disposed in the one side region 115 also have a size calculated by design. Since it has a contact area, the number of cases in which the N touch units 105 can be arranged in different geometrical relationships on the one side area 115 is limited. According to the present invention, in the process of designing a position for arranging the N touch units 105 in the one side area 115 of the touch module 100 , the N touch units 105 within a finite area of the one side area 115 . ), the minimum distinguishing recognition distance is set to derive the maximum number of cases that can be placed in different geometric relationships.

The minimum discrimination recognition distance can be recognized by distinguishing the touch points by the two or more touch units 105 as different touch points on the capacitive touch screen when two or more touch units 105 are touched on the capacitive touch screen. including the minimum separation distance. For example, on a capacitive touch screen, if the distance between two touch points multi-touched is within 7 mm, the two touch points are recognized as one touch point, and if the distance between the two touch points is 7.5 mm or more, the two touch points are different touch points. If it is recognized by distinguishing the dots, it is preferable that the minimum distinguishing recognition distance includes 7.5 mm. On the other hand, if there are two or more capacitive touch screens corresponding to the object to be touched by the touch module 100, the minimum discrimination recognition distance is the minimum that can be recognized to distinguish two touch points multi-touched on two or more capacitive touch screens. may be set to a larger separation distance among the separation distances of .

According to the embodiment of the present invention, the minimum discrimination recognition distance is a value that correlates with the contact area of the touch unit 105 . That is, the minimum discrimination recognition distance may be a value set in the capacitive touch screen, but is a value experimentally obtained using a threshold value assumed based on an allowable error. For example, even with the same capacitive touch screen, minimum discrimination recognition when the contact area of the touch unit 105 is an area of 25 mm 2 (eg, a contact surface 305 made in a square shape of 5 mm * 5 mm). When the distance and the contact area of the touch unit 105 are larger than 38 mm 2 (eg, the contact surface 305 manufactured in a circular shape with a diameter of 7 mm), the minimum discrimination recognition distance may be different. Therefore, the minimum discrimination recognition distance is preferably set based on experimental data for a plurality of capacitive touch screens based on the contact area of the touch unit 105 . In this case, the minimum discrimination recognition distance is preferably set to the distance between the outline and the outline of the figure implementing the contact surface 305 of the touch unit 105, but is not limited thereto. The distance between the central portion of the contact surface 305 of the 105 and the central portion may be set.

According to the present invention, the different geometrical relationships formed by the N touch units 105 provided in each of the same type of touch modules 100 can be identified by different geometrical relationships even when the capacitive touch screen is touched. should have A touch on a capacitive touch screen is a surface touch, not a point touch, and the operating system of a device equipped with a capacitive touch screen calculates the midpoint of the touch surface as a touch point. count as Therefore, the minimum identification distance is set so that the N touch units 105 having different geometrical relationships on the frame part 110 of the touch module 100 can be identified with different geometrical relationships even in a state where they are touched on the capacitive touch screen. is set

The minimum identification distance is designed to have different geometric relationships so that the N touch parts 105 disposed on the frame part 110 of the touch module 100 are identified by different geometric relationships even in a state where they are touched on the capacitive touch screen. In order to do this, the distance between the N touch units 105 provided in the different touch modules 100 is included. For example, when the touch surface of the same area is moved by 3.5 mm or more and the capacitive touch screen is touched, if the operating system of the device having the capacitive touch screen recognizes the touch surface moved by 3.5 mm or more as different touch points, The minimum identification distance may be set to a value greater than or equal to 3.5 mm. Here, it is preferable that the minimum identification distance includes a distance between the centers of the comparison target touch units 105 provided in one side area 115 of the frame unit 110 provided in another touch module 100 of the same type.

According to the embodiment of the present invention, the minimum identification distance may be a value set in the capacitive touch screen, but is a value experimentally obtained using a threshold value assumed based on an allowable error. On the other hand, if there are two or more capacitive touch screens corresponding to the object to be touched on the touch module 100, the minimum identification distance is more among the minimum separation distances that can detect the central movement of the touch surface on the two or more capacitive touch screens. It can be set to a large separation distance.

According to the present invention, the touch module 100 touches the touch module 100 even if the N touch units 105 provided in the frame unit 110 are arbitrarily touched without the need to align the N touch units 105 in a specific direction or a specific area of the capacitive touch screen. ), as long as the N touch parts 105 provided in the capacitive touch screen are touched and the N touch points are recognized, the geometric relationship formed by the N touch points is the geometric relationship in the design according to the previously designed bar and the specified tolerance range It must have verifiable readability that matches within

For readability of the N touch units 105 provided in the touch module 100 of the present invention, the N touch units 105 are touched on the capacitive touch screen to rotate the coordinates for the recognized N touch points. must be accompanied, and the geometric relationship for the N touch points must not be changed or distorted even by the coordinate rotation. To this end, it should be possible to identify at least one touch point, which is a reference for reading a geometric relationship or a coordinate rotation, among the N touch points by using the N touch points touched on the capacitive touch screen. However, in a situation in which the touch module 100 is arranged in a specific direction of the capacitive touch screen to be touched in advance, or in a situation in which the touch module 100 is not pre-determined to touch a specific area, always the same touch point among N touch points that are randomly touched It is technically very difficult to always specify the same reference point.

In the present invention, in order to specify at least one pre-designated reference point among the N touch points even when the N touch units 105 provided in the touch module 100 are touched in any direction of the capacitive touch screen, the touch module At least one general touch unit 105 that is not a reference point among the N touch units 105 provided in 100 is provided in one area 115 of the touch module 100 under the same conditions, but at least one The designated touch unit 105 is provided on one side area 115 of the touch module 100 under different conditions from other general touch units 105, so that it is provided under different conditions among the N touch points touched on the capacitive touch screen. It is characterized in that at least one touch point is detected and specified as a reference point. Here, the reference point specification condition for specifying the reference point among the N touch points is the condition of having the designated touch unit 105 serving as the reference point in one area 115 of the frame unit 110 and the remaining general touch unit 105 ) condition to design and manufacture differently, and/or conditions for designing and manufacturing the geometric characteristics of the designated touch unit 105 itself to be distinguished from the geometric characteristics of other general touch units 105 (eg, the specified touch unit ( 105) and the conditions for designing and manufacturing different shapes or areas of the general touch unit 105, etc.).

According to a preferred embodiment of the present invention, one side area 115 of the touch module 100 is divided into a smaller number of divided areas 400 than N in order to specify at least one reference touch point among the N touch points. After (here, the divided area 400 is a divided area 400 divided in a grid structure, a divided area 400 divided in a concentric circle structure based on the center point of the one side area 115, and the center point Divided regions 400 divided at a specified angle, etc.), and a specified number (eg, one per divided region 400) at the calculated positions on each divided region 400 ) of general touch units 105, The designated touch unit 105 serving as a reference point is provided at a designated location (eg, a corner portion, etc.) on any one of the divided areas 400 among the divided areas 400 , so that one side area 115 of the touch module 100 is provided. The condition of having the designated touch unit 105 serving as a reference point in the , and the condition of having the rest of the general touch unit 105 can be designed and manufactured differently, and the touch units 105 exceeding the specified number among the divided areas 400 . ), it is possible to specify the touch unit 105 provided at a designated position on the divided area 400 as a reference point for reading a geometric relationship or rotating a coordinate. For example, when the touch module 100 is manufactured by including N touch units 105 in one area 115 of the touch module 100, the one side area 115 is n (2≤n) in design. After dividing into <N divided regions 400 , each of the general touch units 105 is provided at the calculated positions on the n divided regions 400 , and one of the n divided regions 400 is provided. By setting the area of ' to the designated area 405 , the frame unit 110 may be manufactured by having one designated touch unit 105 at a designated position (eg, a corner portion, etc.) of the designated area 405 . At this time, the touch authentication module that certifies the geometric relationship formed by the N touch points and the geometric relationship in the design is the component values of the N touch points that touched the designed and manufactured touch module 100 on the capacitive touch screen as described above. After matching with the structure of the n divided areas 400 in the design, at least one designated area 405 in which two touch points exist among the n divided areas 400 is determined, and the determined designated area 405 is determined. It is possible to determine a touch point existing at a designated position of , as a reference touch point.

3 is a view showing the structure of the touch unit 105 according to the embodiment of the present invention.

In more detail, FIG. 3 shows the structure of the touch unit 105 disposed in a specified geometric relationship on the frame unit 110 of the touch module 100, and those of ordinary skill in the art to which the present invention pertains. , various implementation methods for the structure of the touch unit 105 can be inferred by referring to and/or modifying this FIG. 3, but the present invention includes all the inferred implementation methods, and is shown in FIG. The technical characteristics are not limited only to the implementation method described.

The touch unit 105 of the present invention is provided in the touch module 100 to induce a change in electrostatic on the capacitive touch screen, and is a generic term for components recognized as touch points, and is disposed on the frame unit 110 in a designed geometrical relationship. do.

The touch unit 105 is designed and manufactured to have a contact surface 305 in the form of a designated figure (eg, polygon, circle, or oval). The contact surface 305 of the touch unit 105 has a contact area calculated by design to effectively touch the capacitive touch screen. The contact area corresponds to a touch sensitivity capable of recognizing a capacitive touch using the touch unit 105 as one effective touch point on a plurality of capacitive touch screens corresponding to the touch target based on the capacitance of the human body. It is designed with an area greater than or equal to the area. When the touch unit 105 of the touch module 100 is designed to be effectively touched on all capacitive touch screens of different types (or mounted on different models), the touch sensitivity of each capacitive touch screen is different. If so, the contact area of the touch unit 105 is larger than or equal to the larger area (that is, the area corresponding to the smaller touch sensitivity) among the areas corresponding to each touch sensitivity recognizable on each capacitive touch screen. It is preferable to calculate

The side structure of the touch part 105 is manufactured in a 'T' shape by having the touch body 300 in the center of the embedded part 310 as shown in (A) of FIG. 3, or (B) of FIG. As shown in Fig. 3, the touch body 300 is provided with the touch body 300 biased toward one side as shown in Fig. 3, or the touch body 300 without a separate embedded part 310 as shown in Fig. 3 (c). It can be manufactured in the form of 'I', including

The embedding part 310 of the touch part 105 is named as a part to be embedded in the embedding groove among the configurations of the touch part 105 when an embedding groove is provided in the frame part 110, and the touch part ( The touch body 300 of 105 is named for the body constituting the contact surface 305 to be touched on the capacitive touch screen.

In the embodiment of (A) or (B) of Figure 3, the embedding part 310 is supported by the upper plate part 200 in embodiments such as Figures 2a, 2d, Figures 2e and 2g, or the part that is embedded in the embedding groove. As a component including a, when the lower plate 210 having an exposed groove is laminated as shown in FIGS. 2a, 2d, and 2e, the touch part 105 is adhered using a separate adhesive or the touch part ( Even if the touch unit 105 is not fixed due to the elasticity of the material of the 105 , the touch unit 105 serves to be fixed to the frame unit 110 . In particular, the buried part 310 may play a role of enabling a stable capacitive touch by expanding the contact area between the touch part 105 made of a conductive rubber material and the conductive region provided on the upper plate part 200 .

The touch part 105 is preferably manufactured with a hardness of 30 or more and less than 90 based on a Shore A hardness scale having a predetermined elasticity, and the central portion of the contact surface 305 maintains the specified shape while maintaining the shape. It is a structure that protrudes convexly according to a certain curvature above the boundary of the shape and can be manufactured by rounding. When the thus-fabricated touch unit 105 is touched on the capacitive touch screen, the capacitive touch screen is first touched from the central portion protruding convexly with a predetermined curvature among the contact surfaces 305 of the touch unit 105. When a constant pressing force is applied to the touch unit 105 in this state, the central portion is retracted by the pressing force, and as a result, the entire contact surface 305 of the touch unit 105 forms a calculated contact area, and the capacitive touch screen is touched on The midpoint (= touch point) of the touch surface touched on the capacitive touch screen by the touch unit 105 corresponds to the central portion of the contact surface 305 formed on the touch unit 105 or at least within the calculated error range. corresponds to the central portion of the contact surface 305 . On the other hand, the round processing may be omitted depending on the implementation method, and the present invention is not limited thereto.

The touch unit 105 may be manufactured by forming an empty space inside the touch body 300 (or including the embedded unit 310 ). The empty space inside the touch unit 105 provides a space in which the center portion of the contact surface 305 convexly protruding with a predetermined curvature is contracted into the touch unit 105 while being retracted by the pressing force. Since the touch module 100 is touched to the capacitive touch screen in a state of being held by a person's hand, the pressing force applied to the touch unit 105 by the human hand is a vertical component of the capacitive touch screen. not only exist, but also a horizontal component. At this time, in the empty space inside the touch unit 105 , even if a horizontal component exists in the pressing force, the contact surface 305 of the touch unit 105 is not distorted by the horizontal component and is not distorted in a vertical direction. by induced to contract into the touch unit 105 . If the contact surface 305 of the touch unit 105 is distorted in one of the horizontal direction components by the pressing force, as a result, the midpoint of the surface touched on the capacitive touch screen is also shifted in the distorted direction by that much, so that a plurality of touch The error of the geometric relationship formed by the points increases. An empty space inside the touch unit 105 prevents or minimizes such an error.

4 is a diagram illustrating the geometrical relationship of the touch unit 105 provided in the touch module 100 according to the embodiment of the present invention.

In more detail, FIG. 4 exemplifies the geometrical relationship of disposing a plurality of touch units 105 on one side area 115 of the frame unit 110 based on the touch module 100 shown in FIG. 1A . Those of ordinary skill in the art to which the invention pertains may refer to and/or modify this FIG. 4 to obtain various implementation methods for the geometrical relationship of the touch unit 105 (eg, some components are omitted or subdivided, or , or a combined implementation method) may be inferred, but the present invention is made including all the inferred implementation methods, and the technical characteristics are not limited only to the implementation method illustrated in FIG. 4 .

According to the present invention, the touch module 100 touches the touch module 100 even if the N touch units 105 provided in the frame unit 110 are arbitrarily touched without the need to align the N touch units 105 in a specific direction or a specific area of the capacitive touch screen. ), as long as the N touch parts 105 provided in the capacitive touch screen are touched and the N touch points are recognized, the geometric relationship formed by the N touch points is the geometric relationship in the design according to the previously designed bar and the specified tolerance range It must have verifiable readability that matches within Such readability can be ensured by a rule that sets any one of the N touch units 105 as a reference point even when the N touch units 105 are touched in any direction on the capacitive touch screen. there is.

According to the embodiment of the present invention, one side area 115 of the touch module 100 is n (2≤n<N) smaller than N in order to ensure readability of the geometrical relationship of the N touch units 105 . After dividing into four divided regions 400 (here, the divided region 400 is a divided region 400 divided in a grid structure, a divided region divided in a concentric circle structure based on the central point of the one side region 115 ( 400), divided regions 400 divided at a specified angle based on the central point, etc.), the number specified at the calculated positions on each divided region 400 (eg, one per division 400). The touch module is provided with a touch unit 105, but the designated touch unit 105 serving as a reference point is provided at a designated position (eg, a corner portion, etc.) on any one of the divided areas 400 among the divided areas 400 . A condition in which the designated touch unit 105 serving as a reference point is provided in one region 115 of 100 and a condition in which the remaining general touch unit 105 is provided may be designed and manufactured differently.

In the embodiment of FIG. 4 , after dividing one area 115 of the touch module 100 into n lattice structures in design, n touch units 105 at n divided areas 400 at designally calculated positions. (i.e., one touch unit 105 per divided area 400), but at a design-designated location (eg, a corner portion) on any one designated area 405 among the n divided areas 400 ) shows an embodiment having one designated touch unit 105 . However, the embodiment of the present invention is not limited to the embodiment shown in Fig. 4, it can be variously modified or applied, and it is clearly stated that the present invention includes all such embodiments within the scope of the rights.

Referring to the embodiment of FIG. 4 , in the process of designing a position for arranging N touch units 105 in one area 115 of the frame unit 110 provided in the touch module 100 , the touch module One side region 115 of (100) is divided into n divided regions 400 in design (however, divided regions 400 exist in design and are actually on one side region 115 of the frame unit 110). Even if it is not displayed) In each of the n divided areas 400 , one touch unit 105 is disposed at a position calculated by design to form a geometric relationship, and in any one designated area 405 of the n divided areas 400 , It is designed to arrange one touch unit 105 corresponding to a reference point at a design-designated position. That is, one touch unit 105 is disposed in each of (n-1) divided areas 400 among the n divided areas 400 , and two touch units 105 are disposed in one designated area 405 . designed to place Preferably, the designated position may be designated at a position in contact with the figure outline of the one area 115 or at a position at a corner of the figure outline.

When touching the capacitive touch screen by arranging the N touch units 105 in the n divided areas 400 as described above, the touch authentication module includes the n divided areas ( 400) is matched with the N touch points to identify any one designated area 405 in which two touch points are recognized among the n divided areas 400, and is provided at a designated location on the identified designated area 405. A touch point may be determined as a reference point of the N touch points. And when the coordinates are rotated based on the confirmed reference point, even if the N touch units 105 are touched in any direction on the capacitive touch screen, it is possible to compare with the geometrical relationship of pre-registered touch authentication conditions.

Referring to the embodiment of FIG. 4 , when one side area 115 of the frame unit 110 provided in the touch module 100 is divided into n divided areas 400 , each divided area 400 and A certain blank space may exist between the divided regions 400 . Preferably, the blank space includes an interval equal to the minimum recognition distance, and in this case, no matter where the touch unit 105 is provided on each divided area 400 , it is arranged in each divided area 400 . The touch units 105 are always kept apart from each other by at least the minimum discrimination recognition distance. Meanwhile, as in the embodiment of FIG. 4 , when a blank space is provided between the divided areas 400 by design, the area of the one side area 115 at which the N number of touch units 105 can be calculated is reduced. do. According to another embodiment of the present invention, in order to secure an area in which the N touch units 105 are to be located, the blank space is omitted and the divided area 400 is divided, and then the N touch units 105 are arranged. In the process of calculating the position, each of the touch units 105 may be calculated to be separated by more than a minimum discrimination recognition distance.

5A and 5B are diagrams illustrating an embodiment using the touch module 100 according to an embodiment of the present invention.

In more detail, the drawings 5a and 5b show an embodiment of a touch painting in which the touch module 100 is mounted on a painting-type object, and those of ordinary skill in the art to which the present invention pertains Various implementation methods using the touch module 100 (eg, some components are omitted, subdivided, or combined) can be inferred by referring to and/or modifying 5a and 5b, but the present invention is It is made including all the implementation methods inferred above, and the technical characteristics are not limited only to the implementation methods shown in FIGS. 5A and 5B.

The touch module 100 of the present invention is equipped with a card-shaped object by forming a thin thickness of each plate and a height of the touch unit 105, or a touch card manufactured in the form of a card, or having a handle unit 500. It may be mounted on various types of objects or manufactured in various forms, such as mounted on a painting-type object or a touch painting produced in a painting-type object, and Figures 5a and 5b show that the touch module 100 is It shows an embodiment of a touch painting mounted on an object or manufactured in the form of a painting.

FIG. 5a shows a process of manufacturing a touch painting including the touch module 100, and FIG. 5b illustrates a cross-section of the touch painting manufactured including the touch module 100 through the process of FIG. 5a. .

Referring to FIG. 5A , touch painting is performed by manufacturing a touch module 100 in which a plurality of touch units 105 are arranged in a designed geometric relationship on a frame unit 110, but the frame unit 110 of the touch module 100 After the coupling part 520 to be connected to the handle part 500 is provided on the handle, the coupling part 520 is inserted into the groove of the housing part 515 to assemble the adapter part 505 and the adapter part 505 at the same time. ) and the housing unit 515 by providing a spring unit 510 so that the touch module 100 floats in the air at a predetermined distance or more from the floor inside the housing unit 515, and then the adapter unit 505 ) is manufactured by combining the handle portion 500.

The touch module 100 is manufactured through at least one manufacturing process of FIGS. 2a to 2h or a manufacturing process applying the same, and preferably the frame part 110 of the touch module 100 (eg, the top plate 200). ) is provided with a coupling part 520 to be coupled with the handle part 500 (or the adapter part 505) of the touch painting.

The housing unit 515 protects the touch unit 105 or the frame unit 110 provided in the touch module 100 from external impact, and at the same time, the touch unit 105 provided in the touch module 100 ( For example, as a generic term for protecting the contact surface 305 of the touch unit 105 from external impact damage and various contaminations that impair the sensitivity of the capacitive touch, referring to FIG. 5A , the housing unit 515 has a groove into which the coupling part 520 of the touch module 100 is to be inserted and an area in which the spring part 510 is fixed.

The adapter part 505 is a generic term for components that are coupled to the coupling part 520 of the touch module 100 inserted into the groove of the housing part 515 and connect the touch module 100 to the handle part 500 . As an example, by providing a spring part 510 between the adapter part 505 and the housing part 515 , the touch module is in a state in which the touch painting is erected with the touch part 105 of the touch module 100 facing the floor. The touch part 105 of 100 maintains a state floating in the air at a certain height to be protected from external impact or contamination.

The coupling part 520 inserted into the groove of the housing part 515 is assembled with the adapter part 505 by bolt assembly (or bonding using an adhesive is possible), and the handle part 500 is attached to the adapter part 505 . ) to produce a touch painting as shown in Fig. 5b. The adapter part 505 and the handle part 500 may be screwed together or adhered by an adhesive. According to the embodiment of the present invention, the handle part 500 and the housing part 515 may be designed and manufactured in various types of designs.

Figure 5b (a) exemplifies the touch coating produced through the process of Figure 5a, and Figure 5b (b) shows that the touch unit 105 of the touch module 100 provided in the touch coating is a capacitive touch. It exemplifies the state touched on the screen. Referring to the example of (B) of FIG. 5B , in order for the touch unit 105 of the touch module 100 provided in the touch painting to touch the capacitive touch screen, a force greater than the elastic force of the spring unit 510 (eg, pressure) must be applied. However, the pressing force applied to the touch painting is only a force for touching the touch unit 105 of the touch module 100 floating on the capacitive touch screen inside the housing by the spring unit 510 to the capacitive touch screen, It should be clarified that the pressing force itself does not induce a touch (ie, it is not a pressure-sensitive touch unless the capacitive touchscreen supports the pressure-sensitive touch).

100: touch module 105: touch unit
110: frame part 115: one side area
200: upper plate 205: middle plate
210: lower plate 300: touch body
205: contact surface 310: recessed part
400: partition area 405: designated area

Claims (22)

In the capacitive touch module to be touched on the capacitive touch screen,
a plurality of touch units made of a conductive rubber material and having contact surfaces to be capacitively touched on the capacitive touch screen; and
The geometric relationship between the plurality of touch parts formed by connecting the midpoints of the contact surfaces of the plurality of touch parts is arranged in a unique geometric relationship so as not to overlap with each other for each touch module of the same type in one area of a designated area, and the capacitance of the human body is set above and a frame part having at least one conductive area on one side that transmits to the touch part;
The contact surface of the touch unit maximizes the number of cases in which a plurality of touch units provided within a designated area of the one side area are arranged in a unique geometric relationship that does not overlap with each other, and includes a plurality of touch units arranged in the unique geometric relationship. A circular contact surface of diameter 4 mm (±0.5 mm) to 7 mm (± 0.5 mm) or a contact area corresponding to the circular contact surface is used to maintain the touch rate recognized by touching the capacitive touch screen over a preset reference ratio. Capacitive touch module, characterized in that it is manufactured in the shape of an oval or polygon with

According to claim 1, wherein the contact surface of the touch unit,
For a designated capacitive touch screen, a circular contact surface with a diameter of 4 mm (±0.5 mm) or more, or a contact area corresponding to a circular contact surface with a diameter of 4 mm (± 0.5 mm) or more for an effective capacitive touch based on human capacitance Capacitive touch module, characterized in that it is manufactured in the shape of an oval or polygon with
According to claim 1, wherein the contact surface of the touch unit,
A circular contact surface with a diameter of 7 mm (±0.5 mm) or less, or a diameter of 7 mm (±0.5 mm) or less, in order to keep the number of cases of disposing a specified number of touch parts in different geometric relationships within a specified area more than the specified number A capacitive touch module, characterized in that it is manufactured in an oval or polygonal shape having a contact area corresponding to a circular contact surface.
delete delete delete delete delete delete delete delete delete According to claim 1, wherein the hardness of the touch portion,
A capacitive touch module, characterized in that it is manufactured with a hardness of 60 (±5) to 70 (±5) based on Shore A hardness scale.
delete The method of claim 1 , wherein the geometric relationship is
The capacitive touch module, characterized in that it includes a geometric relationship that excludes a line arrangement structure in which three or more touch units are arranged in a line among the plurality of touch units.
The method of claim 1 , wherein the geometric relationship is
The capacitive touch module, characterized in that it comprises an arbitrary arrangement structure in which three or more touch units are not arranged in a line among the plurality of touch units.
The method of claim 1,
The geometrical relationship is obtained by disposing at least one touch unit among a plurality of touch units disposed on one side region of the frame unit provided in each touch module of the same type at another position spaced apart by at least a minimum identification distance of at least 3.5 mm to each touch module of the same type. It includes a geometric relationship in which the geometric relationship of the touch unit provided in the
The minimum identification distance is a capacitive touch module, characterized in that it comprises a distance between the centers of the comparison target touch unit provided in one area of the frame unit provided in another touch module of the same type.
delete The method of claim 1 , wherein the geometric relationship is
One side area of the frame part is divided into divided areas having a number less than the number of touch units, and one touch unit is respectively disposed at an arbitrary calculated position on each divided area, and at least at a designated position on at least one designated area among the divided areas. A capacitive touch module, characterized in that it comprises a geometric relationship for further arranging one touch unit.
delete delete delete

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