KR102159405B1 - A Handstamp for Touch - Google Patents

Abstract

The present invention relates to a touch coating, in the touch coating to be touched on a capacitive touch screen, a plurality of touch units made of a conductive material capable of capacitive touch on the capacitive touch screen and formed to be held by a human hand, Unique geometrical positional relationship including a predesigned distance relationship and an angular relationship in which the center points of the tactile surfaces of the handle unit and the contact surfaces of the plurality of touch units are not overlapped for each touch coating, or having a contact unit made of a conductive material on at least one side And a flat plate part having a predetermined area arranged and fixed to be touch-recognized on the capacitive touch screen while forming, and a frame part having a structure electrically connecting the conductive material of the handle part and the plurality of touch parts, and the geometrical positional relationship Includes a relative coordinate relationship including a distance relationship and an angular relationship formed by a plurality of touch points recognized by touching the plurality of touch units disposed and fixed on the flat panel to a flat area of the capacitive touch screen, and the plurality of The touch unit of is charged with capacitance caused by the human body in contact with the handle unit before being touched on the capacitive touch screen.

Description

Touch painting{A Handstamp for Touch}

In the present invention, in the touch coating to be touched on a capacitive touch screen, a plurality of touch units made of a conductive material capable of capacitive touch on the capacitive touch screen and a plurality of touch units are formed to be held by a human hand, and are made of a conductive material or at least one side While forming a unique geometrical positional relationship including a predesigned distance relationship and an angular relationship in which the center points of the contact points of the plurality of touch parts and the handle part having a contact part made of a conductive material are not overlapped for each touch coating, It includes a flat plate part of a certain area arranged and fixed to be touch-recognized on a touch screen, and a frame part having a structure electrically connecting the conductive material of the handle part and the plurality of touch parts, and the geometrical positional relationship is And a relative coordinate relationship including a distance relationship and an angular relationship formed by a plurality of touch points recognized by touching the disposed and fixed touch units on a flat area of the capacitive touch screen, and the plurality of touch units include: It relates to a touch coating in which capacitance by a human body in contact with the handle is stored before being touched on the type touch screen.

A touch painting service is disclosed in which a plurality of touch parts made of a conductive material are provided on a painted object, and a geometric positional relationship formed by the plurality of touch parts is simultaneously touched on a capacitive touch screen as various authentication means or identification means.

Conventional capacitive touch screens are designed to use a touch by a user's finger as an input means, and are also optimized to do so. In the case of a recently released smartphone, the capacitive touch screen supports multiple touches and is designed to use multiple touches using a finger as an input means (eg, pinch to zoom).

Meanwhile, in order to use the geometrical positional relationship of a plurality of touch units provided in the touch seal as an authentication means or an identification means, a plurality of touch units provided in at least two or more different touch seals must have a uniqueness formed by different geometrical positional relationships. However, such uniqueness has a problem that makes it possible to invest a lot of effort and cost in mass production or quality control by designing various geometric positional relationships of touch paintings.

An object of the present invention for solving the above problems is, in a touch coating to be touched on a capacitive touch screen, a plurality of touch units made of a conductive material capable of capacitive touch on the capacitive touch screen and a human hand It is formed of a conductive material or includes a handle part having a contact part made of a conductive material on at least one side and a pre-designed distance relationship and an angular relationship in which the midpoints of the contact points of the plurality of touch parts do not overlap for each touch coating. A flat plate portion having a predetermined area arranged and fixed to be touch-recognized on the capacitive touch screen while forming a unique geometrical positional relationship, and a frame portion having a structure electrically connecting the conductive material of the handle portion and the plurality of touch portions, , The geometrical positional relationship is a relative coordinate relationship including a distance relationship and an angular relationship formed by a plurality of touch points recognized by touching the plurality of touch units disposed and fixed on the flat panel to a flat area of the capacitive touch screen. Including, the plurality of touch units is to provide a touch coating in which capacitance by a human body in contact with the handle is stored before being touched on the capacitive touch screen.

In the touch coating to be touched on the capacitive touch screen, the touch coating according to the present invention is formed to be held by a human hand and a plurality of touch units made of a conductive material capable of capacitive touch on the capacitive touch screen, and is made of a conductive material. A unique geometric positional relationship including a pre-designed distance relationship and an angular relationship in which the center points of the handle portion having a contact portion made of a conductive material or at least one side of the contact portion and the contact points of the plurality of touch portions do not overlap for each touch coating. A flat plate portion having a predetermined area disposed and fixed to be touch-recognized on the capacitive touch screen while being formed, and a frame portion having a structure electrically connecting the conductive material of the handle portion and the plurality of touch portions, and the geometrical positional relationship is , A relative coordinate relationship including a distance relationship and an angular relationship formed by a plurality of touch points recognized by touching the plurality of touch units disposed and fixed on the flat panel to a flat area of the capacitive touch screen, and the plurality of The touch unit is characterized in that before the capacitive touch screen is touched, capacitance by a human body in contact with the handle is stored.
In the touch coating according to the present invention, the frame portion is characterized in that it further comprises a housing portion housing a flat portion having a plurality of touch portions.
In the touch coating according to the present invention, it is characterized in that it further comprises an adapter for connecting the flat portion to the handle portion or the flat portion to the housing portion connected to the handle portion.
In the touch coating according to the present invention, the plurality of touch units include a cylindrical touch implementation unit that maintains a circular or polygonal boundary of a contact surface contacting the electrostatic touch screen.
In the touch coating according to the present invention, when the plurality of touch units touch the capacitive touch screen while being disposed and fixed on the flat plate, the capacitive touch screen starts from a midpoint of a contact surface that contacts the capacitive touch screen. It is characterized by having a contact surface of a shape that is protruded so as to be touched first to be rounded according to a predetermined curvature.
In the touch coating according to the present invention, the flat plate portion is characterized in that the plurality of touch portions are fixed to the same height, or at least one touch portion of the plurality of touch portions is fixed to a different height.
In the touch coating according to the present invention, the flat plate portion is formed of a predetermined area in which the plurality of touch portions are arranged in a designated geometrical positional relationship.
In the touch coating to be touched on the capacitive touch screen provided in the device, the touch coating according to the present invention includes a plurality of touch units made of a rubber-elastic conductive material, and a constant arrangement of the plurality of touch units in a designated geometrical positional relationship. A frame portion including a flat plate portion of an area, and a handle portion connected to the adapter portion and formed to be gripped by a human hand, and the plurality of touch portions store a specified capacitance before touching the touch panel.

According to the present invention, the frame portion may further include a housing portion housing a flat portion having a plurality of touch portions.

According to the present invention, the frame portion may further include an adapter portion connecting the flat portion to the handle portion. Alternatively, the frame portion may further include an adapter portion connecting the flat portion to the housing portion connected to the handle portion.

According to the present invention, the plurality of touch units may include a cylindrical touch implementation unit that maintains a circular boundary of a contact surface contacting the capacitive touch screen.

According to the present invention, the plurality of touch units may include a touch implementation unit that maintains a polygonal boundary of a contact surface contacting the capacitive touch screen.

According to the present invention, the plurality of touch units may have a contact surface of a shape that is rounded according to a predetermined curvature by protruding to first touch the capacitive touch screen from a midpoint of the contact surface within a designated contact boundary. have.

According to the present invention, the flat plate part may arrange the plurality of touch parts in a designated geometrical positional relationship.

According to the present invention, the flat panel may fix the plurality of touch parts to the same height, or fix one or more of the plurality of touch parts to different heights.

According to the present invention, the flat plate portion is a touch coating, characterized in that formed of a predetermined area arranged in a predetermined geometric positional relationship of the plurality of touch portions.

According to the present invention, the handle part may be made of a conductive material or may have a contact part made of a conductive material on at least one side.

According to the present invention, the plurality of touch portions may be electrically connected to a human body in contact with the handle portion.

According to the present invention, the plurality of touch portions may store capacitance corresponding to the capacitance of the human body by the human body in contact with the handle portion.

According to the present invention, the capacitance of the human body may be a capacitance based on a capacitance of 100pF to 300pF.

According to the present invention, a capacitive power storage unit for storing and maintaining a specified capacitance is provided, and the plurality of touch units may store the capacitance held by the capacitive power storage unit. Meanwhile, the capacitive power storage unit may include a super capacitor or a battery.

According to the present invention, by modularizing the configuration of the touch coating, there is an advantage in that it is possible to mass-produce touch coatings having various geometrical positional relationships with little cost and effort, or to manage to maintain quality above a certain level.

According to the present invention, through the act of touching the touch stamp on the capacitive touch screen provided in the user's wireless terminal, the user authenticates that the user has performed or is scheduled to perform a specified action at a specified location or place, and provides various services corresponding thereto. There is an advantage.

1 is a diagram showing a conceptual configuration diagram of a touch coating according to the present invention.
2 is a diagram showing a structure of a touch coating according to an exemplary method of the present invention.
3 is a diagram illustrating a structure of a touch unit according to an exemplary method of the present invention.
4 is a view showing the structure of the upper plate according to the method of the present invention.
5 is a view showing the structure of a middle plate according to an exemplary method of the present invention.
6 is a view showing the structure of a middle plate according to another embodiment of the present invention.
7 is a view showing the structure of the lower plate according to an embodiment of the present invention.
8 is a view showing the structure of the lower plate according to another embodiment of the present invention.
9 is a view showing the structure of the bottom of the housing according to an embodiment of the present invention.
10 is a diagram illustrating the appearance of a touch coating manufactured according to an exemplary method of the present invention.

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

In addition, in the following description of the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted. In addition, 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 users or operators. Therefore, the definition should be made based on the contents throughout the present invention.

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

1 is a diagram showing a conceptual configuration diagram of a touch coating 100 according to the present invention.

In more detail, FIG. 1 shows the structure of a touch coating 100 for touching a plurality of touch units 105 arranged in a specified geometric positional relationship on a flat-panel capacitive touch screen in a designated touch method. According to the touch coating 100, a plurality of touch units 105 made of a conductive material of rubber elasticity that can be touched on a capacitive touch screen is provided, and the plurality of touch units 105 are assigned a geometrical positional relationship. A contact area in which a frame unit 110 including a flat plate portion 200 that is arranged to be touched on a flat panel structure capacitive touch screen and a plurality of touch units 105 fixed to the flat plate portion 200 are designated And a handle portion 115 for transmitting a predetermined pressing force and/or a capacitance of a human body to be touched on the capacitive touch screen. That is, a plurality of touch parts 105 made of a rubber elastic conductive material, a frame part 110 that arranges them in a designated geometrical position to be touchably fixed to a capacitive touch screen, and a handle part 115 that can be held by hand. Objects having) belong to the scope of the right of the touch coating 100 of the present invention.

Touching the plurality of touch units 105 provided in the touch coating 100 of the present invention on a capacitive touch screen is referred to as a'painting touch'. In the painting touch of the present invention, a plurality of touch parts 105 which are made of a rubber elastic conductive material by holding the handle part 115 with a human hand and arranged in a specified geometrical positional relationship on the flat plate part 200 are electrostatically applied. It is a touch that touches a touch screen, but allows the plurality of touch units 105 to be touched with an area equal to or larger than a designated contact area.

According to an embodiment of the present invention, when the plurality of touch parts 105 are fixed to the same height on the flat plate part 200 of the frame part 110 provided in the touch coating 100, the touch coating 100 The plurality of touch units 105 provided in may simultaneously touch the capacitive touch screen having a flat plate structure. If the plurality of touch units 105 provided on the touch coating 100 may be fixed at different heights, in this case, the touch units 105 having the highest height may be sequentially touched in a specified order by the pressing force. have. The coating touch of the present invention includes a simultaneous touch in which a plurality of touch units 105 are simultaneously touched, and a sequential touch due to a material characteristic of rubber elasticity of the plurality of touch units 105 and a pressing force. However, for convenience, the following embodiments describe the features of the present invention by focusing on the simultaneous touch of the painting touch of the present invention.

The coating touch implemented using the touch coating 100 of the present invention has an element that is differentiated from the conventional multi-touch. The multi-touch is a touch used as an input means by qualifying or quantifying touch points during a time when two or more touch points are maintained while two or more touch points are touched on a touch screen for a specific time. For example, pinch-to-zoom, which is used as an input value for zooming by using the direction and distance moved while two touch points are touched, is the most representative multi-touch. On the other hand, the painting touch of the present invention compares the geometric positional relationship formed by a plurality of touch points, that is, the geometrical positional relationship (e.g., distance, angle, etc.) formed by a plurality of touch points with a pre-designated (or registered) geometric positional relationship. It is a touch that authenticates whether it matches within an allowable error range and uses the touch coating 100 as an identification or authentication means.

In order to implement the simultaneous touch according to the present invention, a plurality of touch units 105 made of a rubber elastic conductive material capable of capacitively touching the capacitive touch screen having a flat plate structure, and a flat plate having a predetermined area on at least one side are provided. The frame portion 110 including the flat plate portion 200 for arranging and fixing the plurality of touch portions 105 in a specified geometrical positional relationship, and the frame portion 110 to which the plurality of touch portions 105 are fixed. An object with a handle 115 that transmits a pressing force for a painting touch and/or a capacitance of the human body to the flat plate side is required, and includes the touch part 105, the frame part 110, and the handle part 115 A single object corresponds to the touch coating 100 of the present invention, even if it has any shape.

The touch part 105 is capable of storing a designated capacitance that will induce a change in capacitance of the capacitive touch screen among the parts constituting the touch coating 100, is made of a conductive material having rubber elastic properties, and a designated contact area ( Or an area equal to or larger than a designated contact area) is formed, and a designated capacitance is stored in the designated contact area before or during a touch on the capacitive touch screen.

According to the first capacitive power storage method of the present invention, the plurality of touch parts 105 may store the capacitance of a human body holding the handle part 115. To this end, the handle part 115 is made of a conductive material, or a conductive material is plated (or coated), or at least one side of the handle part 115 is made of a conductive material or a conductive material is plated (or applied) A contact portion (not shown) may be provided, and the handle portion 115 (or the contact portion) is electrically connected to the plurality of touch portions 105. The capacitance of the human body may vary from 100pF to 4,000pF. Preferably, the present invention can use a value between 100pF and 300pF as the human body capacitance. For example, in the present invention, 200pF can be defined and used as a human body capacitance.

According to the second capacitive storage method of the present invention, the plurality of touch units 105 may store the capacitive capacity stored in the capacitive power storage unit (eg, a super capacitor or a battery) provided in the touch coating 100. I can. To this end, the capacitive power storage unit is electrically connected to the plurality of touch units 105.

According to an exemplary embodiment of the present invention, the material of the touch part 105 may be made of a rubber-elastic conductive material having soft or semi-soft or semi-rigid properties. For example, the touch part 105 may be made of a conductive rubber material or a conductive plastic material having rubber elasticity.

According to an exemplary method of the present invention, the touch unit 105 is preferably formed to include a contact surface 300 having a designated contact area to be touched on the capacitive touch screen. The contact surface 300 of the touch part 105 is a part formed in a direction to be touched on the capacitive touch screen while being fixed to the frame part 110 among the parts of the touch part 105, and has a designated geometric shape ( For example, polygonal or circular). Preferably, the contact surface 300 may be manufactured in a geometric shape of a square shape having a predetermined area.

According to an exemplary embodiment of the present invention, the contact area of the touch unit 105 is correlated with the touch sensitivity of the capacitive touch screen to which the touch coating 100 is to be touched. According to an exemplary method of the present invention, it is assumed that the touch coating 100 is touched on a capacitive touch screen provided in two or more designated heterogeneous devices. In this case, the touch sensitivity of the capacitive touch screen of each device may be different for each device (or each touch screen). Since the capacitive touch screen of each device is basically set to use the capacitance of the human body as an input means, the touch sensitivity of the capacitive touch screen of each device can be expressed as a function of the touch area based on the capacitance of the human body. .

According to the first contact area implementation method of the present invention, the contact area of the touch unit 105 is a contact area corresponding to the lowest recognizable touch sensitivity based on the capacitance of the human body among the touch sensitivity of two or more capacitive touch screens. Can be included. Here, among the touch sensitivities of two or more capacitive touch screens, the lowest touch sensitivity may be obtained from information on specifications published by each device manufacturer or experimentally. For example, the touch sensitivity of the capacitive touch screen (a) of the designated device (a) is 25 mm2, the touch sensitivity of the capacitive touch screen (b) of the designated device (b) is 45 mm2, and the designated device (c If the touch sensitivity of the capacitive touch screen c of) is 80 mm 2, the contact area of the touch unit 105 includes a contact area of 80 mm 2 corresponding to the lowest touch sensitivity among the 25 mm 2, 45 mm 2 and 80 mm 2 By doing so, it is possible to enable touch recognition on each capacitive touch screen of the device (a), device (b) and device (c). Here, the contact area of the touch unit 105 is set as the contact area corresponding to the lowest touch sensitivity that can be recognized based on the capacitance of the human body among the touch sensitivity of two or more capacitive touch screens, provided in the touch coating 100 This is because the geometric positional relationship formed by the plurality of touch units 105 is used as an authentication means or an identification means. That is, if the number of touch units 105 is the same and the area of the frame unit 110 to which each touch unit 105 is fixed is the same, the smaller the contact area of each touch point, the same number of touches fixed to the same area. The number of geometric positional relationships that can be deduced through the unit 105 increases. Therefore, it is possible to recognize a touch even if the contact area of the touch unit 105 exceeds the area corresponding to the lowest touch sensitivity that can be recognized based on the capacitance of the human body among the touch sensitivity of two or more capacitive touch screens. In order to maximize the number of cases with respect to the geometrical positional relationship that can be deduced through the touch unit 105 of, the contact area of the touch unit 105 is based on the capacitance of the human body among the touch sensitivity of two or more capacitive touch screens. It is desirable to set the area corresponding to the lowest recognizable touch sensitivity.

According to the second contact area implementation method of the present invention, the contact area of the touch unit 105 is greater than or equal to an area corresponding to the lowest recognizable touch sensitivity based on the capacitance of the human body among the touch sensitivity of two or more capacitive touch screens. May include area. For example, the touch sensitivity of the capacitive touch screen (a) of the designated device (a) is 25 mm2, the touch sensitivity of the capacitive touch screen (b) of the designated device (b) is 45 mm2, and the designated device (c If the touch sensitivity of the capacitive touch screen c of) is 80 mm 2, the contact area of the touch unit 105 includes a contact area of 80 mm 2 or more corresponding to the lowest touch sensitivity among the 25 mm 2, 45 mm 2 and 80 mm 2. By doing so, it is possible to enable touch recognition on each capacitive touch screen of the device (a), device (b) and device (c). Here, making the contact area of the touch unit 105 equal to or greater than the area corresponding to the lowest recognizable touch sensitivity based on the capacitance of the human body among the touch sensitivities of two or more capacitive touch screens is the authentication of the touch coating 100 In addition to the geometrical positional relationship of the plurality of touch units 105 to be used as means or identification means, other authentication elements are additionally used (e.g., an NFC chip (not shown) and an antenna (not shown) on the touch coating 100) A chip module (not shown) and a sound output unit that use a unique code or a disposable code included in the radio wave signal transmitted from the NFC chip through the antenna as an authentication element or generate a sound signal on the touch seal 100 (Not shown) is provided and the DTMF signal of the sound signal output through the sound output unit by the chip module or a unique code or a disposable code encoded in the sound signal is used as an authentication factor).

According to the third contact area implementation method of the present invention, when a capacitive power storage unit is provided in the touch coating 100, the contact area of the touch unit 105 is a human body outage among the touch sensitivity of two or more capacitive touch screens. A contact area corresponding to the lowest recognizable touch sensitivity based on capacity and a contact area corresponding to a proportional equation of capacitance provided through the capacitive power storage unit may be included. For example, when the capacitance of the human body is 200 pF and the contact area corresponding to the minimum touch sensitivity is 90 mm 2, the contact area may be 30 mm 2 if the capacitance provided through the capacitance storage unit is 600 pF.

According to the fourth contact area implementation method of the present invention, when a capacitive power storage unit is provided in the touch coating 100, the contact area of the touch unit 105 is the electrostatic capacity of the human body among the touch sensitivity of two or more capacitive touch screens. A contact area corresponding to the lowest recognizable touch sensitivity based on capacity and a contact area equal to or larger than an area corresponding to a proportional equation of capacitance provided through the capacitive power storage unit may be included. For example, if the capacitance of the human body is 200pF and the contact area corresponding to the minimum touch sensitivity is 90mm2, the contact area may be 45mm2 or more if the capacitance provided through the capacitance storage unit is 400pF.

According to an embodiment of the present invention, the contact surface 300 of the touch unit 105 may include a shape that is rounded according to a predetermined curvature in a direction to be touched on the capacitive touch screen. In this case, the The contact surface 300 to be touched on the capacitive touch screen forms a curved structure rather than a flat surface. Forming the contact surface 300 of the touch unit 105 in a curved structure having a predetermined curvature, the geometrical positional relationship formed by the plurality of touch units 105 provided in the touch coating 100 is an authentication means or This is because it is used as a means of identification. In order to use the geometrical positional relationship formed by the plurality of touch units 105 having the designated contact area as authentication means or identification means, the center of the contact area of each touch unit 105 touched on the capacitive touch screen (or each The relative coordinate relationship between the coordinate values of the touch units 105 first touched on the capacitive touch screen) should always be constant within a specified error range. If the heights of the touch parts 105 fixed to the flat part 200 are the same, the touch parts 105 must simultaneously touch the capacitive touch screen. Meanwhile, if at least one of the heights of the touch units 105 fixed to the flat panel 200 is different, the corresponding touch units 105 may sequentially touch the capacitive touch screen from the touch unit 105 having the highest height. . However, even though the heights of the touch units 105 fixed to the flat panel 200 are the same, any of the touch units 105 touched on the capacitive touch screen may have a contact surface 300. Each touch touched on the capacitive touch screen is touched from the corner of the geometric shape to be formed, and one side of the other touch part 105 is touched first, and the other touch part 105 touches the contact surface 300 Each time the relative coordinate relationship with the coordinate values of the units 105 is touched, the error range is out of the range, and as a result, it cannot be used as a reliable authentication means or identification means. Therefore, by making the contact surface 300 of the touch unit 105 in a curved shape, each touch unit 105 touches the capacitive touch screen, inducing a painting touch to the capacitive touch screen within a certain error range. The relative coordinates of the touched touch units 105 are induced to be kept constant.

The frame unit 110 is a generic term for fixing a plurality of touch units 105 to be touched on a flat-panel capacitive touch screen among parts constituting the touch coating 100 in a designated geometrical positional relationship, and the plurality of It includes a flat area of a predetermined area for fixing the touch unit 105 to a designated geometrical positional relationship. One side of the frame unit 110 is connected to the handle unit 115 to transmit a pressing force applied through the handle unit 115 to the touch unit 105.

When the human body's capacitance is stored by the touch part 105, the frame part 110 is conductive to transmit the human body's capacitance in contact with the handle part 115 (or the contact part) to the touch part 105. Made of a material or a conductive material may be plated (or coated). Alternatively, electrical wiring for transferring the capacitance of the human body to the touch unit 105 may be printed (or included).

Alternatively, even when the capacitance of the capacitive storage unit is stored by the touch unit 105, the frame unit 110 is made of a conductive material or made of a conductive material to transfer the capacitance of the capacitive storage unit to the touch unit 105. It can be plated (or applied). Alternatively, electrical wiring for transferring the capacitance of the capacitive power storage unit to the touch unit 105 may be printed (or included).

According to the implementation method of the present invention, the frame unit 110 includes a flat plate part 200 including a flat area of a predetermined area in which the plurality of touch parts 105 are arranged in a designated geometrical positional relationship. Accordingly, it may include an adapter part 220 connecting the flat part 200 to the handle part 115. If the flat plate part 200 is directly connected to the handle part 115 or if the flat part 200 has a structure corresponding to the adapter part 220, the adapter part 220 may be omitted.

The handle 115 is a generic term of a component formed to be held by a person's hand among the parts constituting the touch coating 100, and receives a pressing force applied through the hand of the person and transmits it to the frame 110. . One side of the handle part 115 is connected to the frame part 110. Alternatively, the handle portion 115 and the frame portion 110 may be formed of respective modules that can be assembled, or may be manufactured integrally.

When the capacitance of the human body is stored by the touch part 105, the handle part 115 is made of a conductive material, or a conductive material is plated (or coated), or at least one side of the handle part 115 is conductive. A contact part made of a material or plated (or coated) with a conductive material may be provided.

According to an implementation method extending from the present invention, the touch coating 100 may include a housing part 225 housing the frame part 110. If the frame part 110 is provided with a structure that serves as a housing, the housing part 225 may be omitted.

On the other hand, the geometrical positional relationship of the plurality of touch units 105 provided in the touch stamp 100 is used as one of important authentication factors for using the touch stamp 100 as an authentication means or an identification means. It is preferable that the geometric positional relationship of the part 105 has uniqueness that does not overlap. However, according to another embodiment extending from the present invention, other authentication elements are additionally used in addition to the geometrical positional relationship formed by the plurality of touch units 105 (e.g., an NFC chip (not shown) and an antenna (not shown) in the touch coating 100) Chip module (not shown) is provided and uses a unique code or a disposable code included in the radio wave signal transmitted through the antenna from the NFC chip as an authentication element, or generates a sound signal on the touch seal 100 (not shown) And a sound output unit (not shown) is provided, and a DTMF signal of a sound signal output through the sound output unit by the chip module or a unique code or a disposable code encoded in the sound signal is used as an authentication factor) Even if some of the geometrical positional relationships formed by the touch units 105 are the same, the present invention includes such an embodiment as its scope.

The present invention is to maintain the uniqueness of the geometrical positional relationship with respect to the plurality of touch units 105 provided in the touch coating 100, the touch coating 100 to maintain mass production and quality control of the touch coating 100. May be manufactured through embodiments implemented through the following drawings and description. However, the embodiment of the touch coating 100 of the present invention is by no means limited to the following embodiments, and if it supports some of the configurations shown or described in FIG. 1, the configuration of the touch coating 100 of the present invention is It is clear that this applies.

2 is a diagram showing the structure of a touch coating 100 according to an exemplary method of the present invention.

In more detail, FIG. 2 shows an embodiment of a cut surface of the internal structure of the touch coating 100 manufactured based on the structure of the touch coating 100 shown in FIG. 1, and a plurality of touch units 105 ) Is arranged in a variety of geometrical positional relationships, and mass production is possible, and quality control is possible, according to an embodiment of the structure of the touch coating 100. For those of ordinary skill in the art to which the present invention belongs, various implementation methods for the structure of the touch coating 100 by referring and/or modifying the drawings shown in the embodiments of the present invention (eg, some components are omitted or , Or modified, or an integrated implementation method), but the present invention includes all of the above inferred implementation methods, and the technical features of the present invention are by no means limited only to the implementation methods shown below. I want to make it clear. That is, the drawings shown below are only one of many embodiments of manufacturing the touch coating 100 of the present invention, and the touch coating 100 of the present invention is by no means limited only to the embodiments of the drawings shown below.

Referring to FIG. 2, the touch coating 100 includes a plurality of touch units 105 made of a rubber-elastic conductive material touchable on a capacitive touch screen, and the plurality of touch units 105 are designated geometrically. A frame portion 110 having a flat plate portion 200 that is arranged in an array structure and fixed to be touched on a flat panel structure capacitive touch screen, and a plurality of touch portions 105 fixed to the flat plate portion 200 are designated. A contact area is provided and a handle 115 for transmitting a predetermined pressing force and/or a capacitance of the human body to be touched on the capacitive touch screen, and the adapter 220 and the housing 225 are provided according to the implementation method. Can be equipped.

The touch part 105 is a generic term for a component made of a conductive material in which a designated capacitance to induce a change in capacitance of a capacitive touch screen is stored among parts constituting the touch coating 100 and a designated contact area is formed. It is made of a soft, semi-soft, or semi-rigid conductive material for elasticity, and the capacitance of the human body or the capacitance stored in the capacitive power storage unit can be stored in the designated contact area before or during the touch to the capacitive touch screen. .

The contact surface 300 of the touch part 105 is a part formed in a direction to be touched on the capacitive touch screen while being fixed to the frame part 110 among the parts of the touch part 105, and has a designated geometric shape ( For example, polygonal or circular). Preferably, the contact surface 300 may be manufactured in a circular shape of a predetermined area.

According to an exemplary embodiment of the present invention, the contact area of the touch unit 105 is correlated with the touch sensitivity of the capacitive touch screen to which the touch coating 100 is to be touched. According to an exemplary method of the present invention, it is assumed that the touch coating 100 is touched on a capacitive touch screen provided in two or more designated heterogeneous devices. In this case, the touch sensitivity of the capacitive touch screen of each device may be different for each device (or each touch screen). Since the capacitive touch screen of each device is basically set to use the capacitance of the human body as an input means, the touch sensitivity of the capacitive touch screen of each device can be expressed as a function of the touch area based on the capacitance of the human body. .

According to the first contact area implementation method of the present invention, the contact area of the touch unit 105 is a contact area corresponding to the lowest recognizable touch sensitivity based on the capacitance of the human body among the touch sensitivity of two or more capacitive touch screens. Can be included. Here, among the touch sensitivities of two or more capacitive touch screens, the lowest touch sensitivity may be obtained from information on specifications published by each device manufacturer or experimentally.

According to the second contact area implementation method of the present invention, the contact area of the touch unit 105 is greater than or equal to an area corresponding to the lowest recognizable touch sensitivity based on the capacitance of the human body among the touch sensitivity of two or more capacitive touch screens. May include area.

According to the third contact area implementation method of the present invention, when a capacitive power storage unit is provided in the touch coating 100, the contact area of the touch unit 105 is a human body outage among the touch sensitivity of two or more capacitive touch screens. A contact area corresponding to the lowest recognizable touch sensitivity based on capacity and a contact area corresponding to a proportional equation of capacitance provided through the capacitive power storage unit may be included.

According to the fourth contact area implementation method of the present invention, when a capacitive power storage unit is provided in the touch coating 100, the contact area of the touch unit 105 is the electrostatic capacity of the human body among the touch sensitivity of two or more capacitive touch screens. A contact area corresponding to the lowest recognizable touch sensitivity based on capacity and a contact area equal to or larger than an area corresponding to a proportional equation of capacitance provided through the capacitive power storage unit may be included.

According to an embodiment of the present invention, the contact surface 300 of the touch unit 105 may include a shape that is rounded according to a predetermined curvature in a direction to be touched on the capacitive touch screen. In this case, the By manufacturing the contact surface 300 to be touched on the capacitive touch screen to form a curved structure rather than a flat surface, coordinate values corresponding to the geometric arrangement structure formed by the plurality of touch units 105 provided in the touch coating 100 are The relative coordinate relationship is always kept constant within the specified error range.

According to an exemplary method of the present invention, the touch part 105 forms a geometric structure having a designated height in a contact area made of a designated geometric shape. If the height of the touch part 105 fixed to the flat part 200 is designed and manufactured to be the same, each of the touch parts 105 is simultaneously touched on the capacitive touch screen having a flat structure. If at least one of the heights of the touch parts 105 fixed to the flat part 200 is designed and manufactured differently, each of the touch parts 105 is in the order of design from the touch part 105 having the highest height. It is touched sequentially. At this time, the time interval for sequentially touching is not considered as a condition for authenticating the touch because the method and size of the pressing force are different for each person.

The frame unit 110 is a generic term for fixing a plurality of touch units 105 to be touched on a flat-panel capacitive touch screen among the parts constituting the touch coating 100 in a designated geometric arrangement structure, and is made of a conductive material. Or a conductive material may be plated (or coated). Alternatively, electrical wiring for transferring the capacitance of the human body to the touch unit 105 may be printed (or included).

Referring to FIG. 2 corresponding to the implementation method of the present invention, the frame unit 110 includes a flat plate portion 200 including a flat area of a predetermined area in which the plurality of touch units 105 are arranged in a designated geometric arrangement structure. ), and an adapter unit 220 for interfacing the flat plate portion 200 with the handle portion 115.

The flat plate part 200 includes (or combines) the adapter part 220, and holds the plurality of touch parts 105 against the pressing force applied through the handle part 115 and supports it It includes a top plate portion 205 corresponding to the support frame including the region.

The flat plate part 200 includes a middle plate part 210 corresponding to a buried frame in which a plurality of touch parts 105 supported by the upper plate part 205 are embedded to form a geometrical positional relationship of a designated pattern.

The flat plate part 200 protrudes to be exposed to a designated position according to the geometrical positional relationship of a designated pattern while a plurality of touch parts 105 supported by the upper plate part 205 are embedded in the middle plate part 210 It includes a lower plate portion 215 corresponding to the protruding frame.

At least one of the upper plate portion 205, the middle plate portion 210, and the lower plate portion 215 may be made of a conductive material or may be plated (or coated) with a conductive material. Alternatively, electrical wiring for transferring the capacitance of the capacitive power storage unit to the touch unit 105 may be printed (or included).

The flat plate portion 200 is supported by the upper plate portion 205, while the upper plate portion 205, the middle plate portion 210, and the lower plate portion 215 are divided into layers, and has a geometrical arrangement structure designated by the middle plate portion 210. It accommodates a plurality of touch portions 105 that are embedded and protrude in a geometrical arrangement designated by the lower plate portion 215. The upper plate portion 205, the middle plate portion 210, and the lower plate portion 215 may be partitioned by an adhesive, and/or partitioned by screw assembly. The adhesive may include a conductive adhesive.

Referring to Figure 2 corresponding to the implementation method of the present invention, the handle part 115 is a generic term of a component formed to be held by a human hand among parts constituting the touch coating 100, and is applied through a human hand. The pressing force is input and transmitted to the frame unit 110. The adapter unit 220 of the frame unit 110 shown in Fig. 2 corresponding to the method of implementing the present invention is connected to the housing unit 225 through screw assembly, and the housing unit 225 is connected to the handle unit 115 and It is connected through an adhesive. When the capacitance of the human body is stored by the touch part 105, the adhesive may include a conductive adhesive so that the capacitance of the human body holding the handle part 115 is transmitted to the touch part 105.

On the other hand, when the touch coating 100 of the present invention uses an additional authentication element other than the geometrical arrangement structure for the plurality of touch units 105, a component corresponding to the additional authentication element (for example, NFC A chip (not shown) and an antenna (not shown), or a chip module (not shown) for generating a sound signal, and a sound output unit (not shown), etc. may be provided in the handle 115. Alternatively, a component corresponding to the additional authentication element may be provided in the frame portion 110 and/or the housing portion 225.

3 is a diagram illustrating a structure of a touch unit 105 according to an exemplary method of the present invention.

In more detail, this figure 3 shows an embodiment of the touch part 105 supported by the upper plate part 205, embedded in the middle plate part 210, and protruding to the outside by the lower plate part 215. For those of ordinary skill in the art to which the invention belongs, various implementation methods for the structure of the touch unit 105 by referring and/or modifying the drawings shown in the embodiments of the present invention (eg, some components are omitted, Or modified or integrated implementation method), but the present invention is made including all of the above inferred implementation methods, and the technical features of the present invention are by no means limited only to the implementation methods shown below. I have to make it clear.

The plurality of touch parts 105 provided in the touch coating 100 of the present invention are on the buried plate 305 of a certain area embedded in the middle plate part 210, and through the lower plate part 215, a contact surface ( It is manufactured in the form of forming a cylindrical touch implementation part 310 exposing 300 to the outside. It is preferable that the buried plate 305 and the touch implementation unit 310 are made of a soft, semi-soft, or semi-rigid conductive material through an injection molding process or an extrusion molding process. If the contact surface 300 is a polygon (eg, a quadrangle), the touch implementation unit 310 may be implemented in a polyhedron shape maintaining the polygonal structure.

The buried plate 305 fixes the cylindrical touch implementation part 310 to one surface, and is made of a plate having a designated figure shape having an area larger than that of the contact surface 300.

The buried plate 305 may be formed of a plate in the form of a figure including at least three sides formed of a straight line such that at least two angled portions or a protruding portion of a predetermined area exist in an outer side portion of the cylinder, and/or The buried plate 305 fixes the cylindrical touch realization part 310 to one surface, and is formed of a curved part of a certain curvature or a curved part such that a protruding part of a certain area exists on the outer side of the cylinder. It may be made of a plate in the form of a shape including. For example, the buried plate 305 has a square as a basic figure as in the plan view of this figure 3, but three sides may be made of a straight side, and the other side may be made of a circle having a certain curvature. .

According to the implementation method of the present invention, the buried plate 305 is a side surface of a cylinder that implements the touch implementation unit 310 as shown in the example of FIG. 3 in order to fix the touch implementation unit 310 with a minimum area. It is preferable that it is formed in contact with at least three sides provided in the buried plate 305. Depending on the implementation method, the buried plate 305 may have a polygon having an area larger than a contact area, or at least one side of the polygon having a circular shape having a predetermined curvature. Regardless of the shape of the buried plate 305, the cylindrical touch-implementing part 310 is fixed to one surface, and at least two angled portions or lead-out portions are present on the outer side of the cylinder. If it is a figure shape including at least three sides or a curved portion made of a straight line, all belong to the scope of the present invention.

The thickness of the buried plate 305 is formed to have the same thickness as the plate thickness of the middle plate portion 210, or slightly larger than the plate thickness of the middle plate portion 210 (for example, the material of the buried plate 305 is It is preferable that it is compressed by the soft or semi-soft or semi-rigid property to have a thickness capable of bonding the middle plate part 210 and the lower plate part 215 to each other.

It is preferable that the area of the buried plate 305 is formed to be larger than the contact area of the touch implementation unit 310 or that an area protrudes to the outside of the contact area based on a plan view. In this case, the touch part 105 is in a state where the touch part 105 faces downward without bonding the contact part between the buried plate 305 and the upper plate part 205 with an adhesive (for example, a conductive adhesive). 200) can be kept fixed. If the buried plate 305 is adhered to the upper plate portion 205 through an adhesive, the area of the buried plate 305 may be equal to or smaller than the contact area of the touch implementation unit 310.

The touch implementation unit 310 includes a contact surface 300 having a designated contact area in a circular shape, and a cylinder having a predetermined height to expose the contact surface 300 to the outside through the lower plate portion 215 Is formed in a shape. Depending on the implementation method, the touch implementing unit 310 may be formed in a polyhedral shape implemented in a pillar shape.

The height of the touch implementation part 310 is formed to be greater than the thickness of the lower plate part 215, whereby the contact surface 300 of the touch implementation part 310 is exposed to the outside of the lower plate part 215 It will be.

According to the first contact area implementation method of the present invention, the contact area of the touch implementation unit 310 is a contact area corresponding to the lowest touch sensitivity that can be recognized based on the capacitance of the human body among the touch sensitivity of two or more capacitive touch screens. May contain.

According to the second contact area implementation method of the present invention, the contact area of the touch implementation unit 310 is equal to or greater than an area corresponding to the lowest touch sensitivity that can be recognized based on the capacitance of the human body among the touch sensitivity of two or more capacitive touch screens. It may include a contact area.

According to the third contact area implementation method of the present invention, when a capacitive power storage unit is provided in the touch coating 100, the contact area of the touch implementation unit 310 is the touch sensitivity of two or more capacitive touch screens. A contact area corresponding to the lowest recognizable touch sensitivity based on the capacitance and a contact area corresponding to a proportional equation of the capacitance provided through the capacitive power storage unit may be included.

According to the fourth contact area implementation method of the present invention, when a capacitive power storage unit is provided in the touch coating 100, the contact area of the touch implementation unit 310 is a human body among touch sensitivity of two or more capacitive touch screens. A contact area corresponding to the lowest recognizable touch sensitivity based on the capacitance and a contact area greater than or equal to an area corresponding to a proportional equation of the capacitance provided through the capacitance capacitor may be included.

In the contact surface 300 of the touch implementation unit 310, the central portion of the contact surface 300 protrudes to first touch the capacitive touch screen within the boundary of a designated circular shape and is rounded according to a predetermined curvature. In this case, the contact surface 300 to be touched on the capacitive touch screen forms a curved structure within the boundary of a circular shape rather than a flat surface, and is applied to the capacitive touch screen by the paint touch according to the present invention. When touched, the central portion of the rounded contact surface 300 is first touched, and the rounded portion is contracted by the pressing force, and touched while forming a designated contact area to the circular boundary portion. According to the present invention, since the central portion of the contact surface 300 is first touched by the round treatment of the contact surface 300 and the entire contact surface 300 is touched with a designated contact area, the paint touch according to the present invention While touching the contact surface 300 of the touch unit 105 to the capacitive touch screen, the possibility that the center of the touch surface touched on the capacitive touch screen is moved (or changed) is blocked. Depending on the implementation method, the boundary of the contact surface 300 may be manufactured in an oval or polygonal shape.

An empty space may be formed inside the touch implementation part 310, thereby making it more soft than the soft, semi-soft, or semi-hard properties of the conductive material constituting the touch part 105. I can. Even though the contact surface 300 of the touch implementation part 310 has a curvature structure by such softening, a pressure less than the soft, semi-soft or semi-hard elastic force of the conductive material constituting the touch part 105 An area corresponding to the contact area may be induced to touch the capacitive touch screen even by manpower. It is preferable that the empty space is formed by connecting to the buried plate 305.

Referring to Figure 3 corresponding to the implementation method of the present invention, the touch unit 105, through the buried plate 305 having a certain area embedded in the middle plate portion 210, and the lower plate portion 215 It is formed to include a touch implementation part 310 having a circular contact surface 300 that is exposed to the outside.

The thickness of the buried plate 305 is the same as or slightly larger than the thickness of the middle plate portion 210, and the area of the buried plate 305 is larger than the contact area of the touch implementing portion 310 It is formed in a circular shape with an area.

The touch implementation part 310 is formed on a buried plate 305 in which one side of a square has a circular shape having a predetermined curvature. The touch implementation unit 310 includes a contact surface 300 having a circular boundary of the contact surface 300 contacting the capacitive touch screen, and the contact surface is exposed to the outside through the lower plate portion 215. The length of each side of the circular contact surface provided on the touch implementation unit 310 is determined to have a designated contact area, and is rounded in a direction contacting the capacitive touch screen while maintaining the circular shape. The touch implementation part 310 is formed in a cylindrical shape having a height greater than the thickness of the lower plate part 215. An empty space is formed inside the cylindrical-shaped touch implementation part 310, whereby the circular shape is made by a pressing force smaller than the soft, semi-soft, or semi-rigid elastic force of the conductive material constituting the touch part 105. The contact surface 300 of is in contact with the capacitive touch screen. The empty space may be formed by extending to the buried plate 305 and thus by injection molding or extrusion molding.

Figure 4 is a diagram showing the structure of the upper plate portion 205 according to an embodiment of the present invention.

In more detail, Figure 4 shows the structure of the upper plate portion 205 of the flat plate portion 200 of the frame portion 110, specifically, Figure 4a shows a plan view of the top plate portion 205, Figure 4b is the top plate ( 205 shows a side view, and FIG. 4c shows a bottom view of the upper plate portion 205. For those of ordinary skill in the art to which the present invention belongs, various implementation methods for the structure of the upper plate 205 by referring and/or modifying the drawings shown in the embodiments of the present invention (for example, some components are omitted, Or modified or integrated implementation method), but the present invention is made including all of the above inferred implementation methods, and the technical features of the present invention are by no means limited only to the implementation methods shown below. I have to make it clear.

Referring to Figure 4a corresponding to the implementation method of the present invention, the upper plate portion 205 is for connecting the flat plate region supporting the plurality of touch portions 105 and the flat plate portion 200 to the handle portion 115. The adapter unit 220 is provided, and the adapter unit 220 includes a screw groove for screw assembly.

The flat area of the upper plate part 205 is an area that supports the plurality of touch parts 105 among the parts of the upper plate part 205 and is coupled to the middle plate part 210.

Referring to Figures 4b and 4c corresponding to the implementation method of the present invention, the upper plate portion 205, the middle plate portion 210 and the recessed portion 505 of the lower plate portion 215 is inserted into the upper plate portion 205, the middle plate The portion 210 and the lower plate portion 215 are provided with a protrusion 400 that guides the assembly in an aligned state.

The protrusion 400 of the upper plate part 205 is the upper plate part 205, the middle plate part through a process in which the recessed part 505 of the middle plate part 210 is inserted and the concave part 505 of the lower plate part 215 is inserted. Each side and corner portions of the 210 and lower plate portions 215 are accurately aligned and coupled to each other.

5 is a view showing the structure of the middle plate part 210 according to an exemplary method of the present invention.

In more detail, FIG. 5 shows the structure of the middle plate part 210 of the flat plate part 200 of the frame part 110, and specifically, FIG. 5A is a bottom view of the middle plate part 210 in which the buried groove 500 is formed. Figure 5b shows a state in which the touch part 105 is embedded in the recess 500 of the middle plate part 210, and figure 5c shows the upper plate part 205 and the middle plate part 210 are assembled. It shows a side view of the state. For those of ordinary skill in the art to which the present invention belongs, various implementation methods for the structure of the middle plate 210 by referring and/or modifying the drawings shown in the embodiments of the present invention (eg, some components are omitted or , Or modified, or an integrated implementation method), but the present invention includes all of the above inferred implementation methods, and the technical features of the present invention are by no means limited only to the implementation methods shown below. I want to make it clear.

The middle plate portion 210 includes a plurality of buried grooves 500 into which buried plates 305 of the plurality of touch portions 105 are embedded. According to the implementation method of the present invention, the position and direction of each buried groove 500 to be provided in the middle plate part 210 is calculated or designed through a program provided in a designated computer, and is manufactured through a designated production device accordingly. At this time, a key element determining the position and direction of the buried groove 500 provided in the middle plate part 210 is a touch part that protrudes to the outside through the lower plate part 215 after being embedded in the middle plate part 210 This is a geometrical positional relationship formed by a plurality of touch points when the contact surface 300 of 105 is touched on the capacitive touch screen. And this geometrical positional relationship is distinguished recognition that a plurality of touch points touched through the same touch coating 100 should be distinguished and recognized as respective unique touch points, and a plurality of touched points touched through different touch coatings 100 The geometric positional relationship formed by the touch points must have a discrimination that different touch positional relationships are formed for each of the touch coatings 100.

The computer program satisfies the discrimination recognition that the plurality of touch points touched through the touch coating 100 having the same geometrical positional relationship formed by the plurality of touch points should be distinguished and recognized as respective unique touch points. For this purpose, the minimum distinguishing recognition distance for each device (or for each capacitive touch screen) is inputted, or the minimum distinguished recognition distance for each device (or for each capacitive touch screen) is experimentally input and the design corresponding to the maximum value is received. The minimum discrimination recognition distance can be determined.

When two or more touch points are multi-touched on a capacitive touch screen of a designated device, the minimum discrimination recognition distance is recognized by distinguishing two or more touch points touched by the device (or capacitive touch screen) as different touch points. Include the smallest possible separation distance. For example, if the distance between two touch points multi-touched on a designated device (or capacitive touch screen) is within 6 mm, the two touch points are recognized as one touch point, and if it is more than 7 mm, two touch points When distinguishing and recognizing by different touch points, the minimum discrimination recognition distance is preferably 7 mm. On the other hand, if there are two or more designated devices (or capacitive touch screens) corresponding to objects to be touched with the touch coating 100, the minimum discrimination recognition distance is two or more multi-touched by two or more designated devices (or capacitive touch screens). It may be set as a larger separation distance among the minimum recognizable separation distances for distinguishing touch points.

According to an exemplary embodiment of the present invention, the minimum discrimination recognition distance is a value correlated with a contact area of the touch unit 105. That is, the minimum discrimination recognition distance may be a value set in a designated device (or capacitive touch screen), but is a value obtained experimentally. For example, even with the same device (or capacitive touch screen), the contact area of the touch unit 105 is 25 mm2 (eg, the contact surface 300 manufactured in a square shape of 5 mm*5 mm) The minimum discriminant recognition distance in the case of is and the minimum discrimination recognition distance in the case where the contact area of the touch part 105 is larger than 38 mm2 (eg, the contact surface 300 manufactured in a circular shape with a diameter of 7 mm) may be different. have. Therefore, the minimum discrimination recognition distance is preferably set based on experimental data on a plurality of devices (or capacitive touch screens) based on the contact area of the touch unit 105. In this case, the minimum discrimination recognition distance is set as a distance between the central portion and the central portion of the contact surface 300 of the touch unit 105, or of a figure that implements the contact surface 300 of the touch unit 105. It can be set as the distance between the outline and the outline.

In the computer program, the geometrical positional relationship formed by the plurality of touchpoints touched through the touch coatings 100 having different geometrical positional relationships formed by the plurality of touch points is different for each touch coating 100. In order to satisfy the identification that a positional relationship should be formed, the minimum identification distance in the design to be applied to the design of the touch coating 100 is input, or the minimum identification distance for each device (or capacitive touch screen) is input experimentally. It can receive and determine the minimum discrimination recognition distance in the design corresponding to the maximum value.

The minimum identification distance is the minimum distance that can identify the two or more touch points as different touch points when touching one area on the capacitive touch screen of the designated device twice or more while moving a little while touching another location. Includes distance. For example, the first touch point is touched on the coordinate value (51, y1) corresponding to a region on the capacitive touch screen of the specified device, and the second touch point is touched on the coordinate value (52, y2), When the third touch point is touched on the coordinate value (53, y3), the device (or capacitive touch screen) makes the touch point of the coordinate value (51, y1) and the coordinate value (52, y2) to the same touch point. On the other hand, if the touch points of the coordinate values (51, y1) and the coordinate values (53, y3) are recognized as different touch points, the distance between the coordinate values (51, y1) and the coordinate values (52, y2) is It corresponds to a separation distance smaller than the minimum identification distance, and the distance between the coordinate values 51 and y1 and the coordinate values 53 and y3 corresponds to a separation distance equal to or greater than the minimum identification distance.

According to an exemplary method of the present invention, the minimum identification distance may be a value set in a designated device (or capacitive touch screen), but is a value obtained experimentally. For example, the minimum identification distance is based on information about a touch point obtained by repeatedly touching the designed and manufactured touch unit 105 by 0.1 mm in any one area on the capacitive touch screen of one or more designated devices. Can be determined. On the other hand, if there are two or more designated devices (or capacitive touch screens) corresponding to the object to be touched with the touch coating 100, the minimum identification distance is twice in any one area in two or more designated devices (or capacitive touch screens). It may be set as a larger separation distance among minimum separation distances capable of identifying two or more touch points that have been touched abnormally.

According to the present invention, one or more of the touch units 105 of the touch units 105 provided in the flat areas of the different flat units 200 of the different touch coatings 100 are provided spaced apart by the minimum identification distance or more. As a result, the geometric positional relationship between the plurality of touch units 105 provided on the flat panel 200 of each touch coating 100 has discernability identified by different geometrical positional relationships within a range of the calculated cases.

The computer program calculates the positions of the touch units 105 exposed by the lower plate unit 215 based on the minimum discrimination recognition distance and the minimum discrimination distance in the design, and the contact area of each touch unit 105, A design geometrical positional relationship with respect to the touch unit 105 is determined.

The geometrical position relationship in the design is a coordinate value for checking the touch position relationship (e.g., distance or angle) when the plurality of touch units 105 are touched on the capacitive touch screen in the form of coordinate values on a predetermined coordinate system. Including a coordinate relationship including a value, and/or a distance relationship between a specified touch point and each remaining touch point based on a coordinate value on a specified coordinate system, and based on a specified touch point on a specified coordinate system. It may include an angular relationship formed by the remaining touch points. Here, the designated coordinate system is a coordinate system that serves as a reference for analyzing the geometric positional relationship between the designated touch point and n touch points, and preferably, a coordinate system composed of metrological units (e.g., µm, mm, cm) or designated logical units in the real world. It is preferable to include. However, it is possible to include a coordinate system set on the capacitive touch screen according to the implementation method.

After or after the process of determining the geometrical positional relationship of the design for the plurality of touch units 105, the program of the computer is buried groove 500 for realizing the geometrical positional relationship of the design to the plurality of touches 105 ) To determine the location and direction.

According to the implementation method of the present invention, the location and direction of the buried groove 500 may be classified into three areas. Preferably, the buried groove 500 provided in the middle plate portion 210 is a first type buried groove formed in the form of a closed shape in which the buried plate 305 of the touch portion 105 is embedded in the flat area. 500 and the buried plate 305 of the touch unit 105 by contacting the touch implementation unit 310 or the contact surface of the touch unit 105 with the outer edge of the flat area based on the plan view of the flat area The second type buried groove 500 formed in the form of embedding and the touch implementation part 310 or the contact surface of the touch part 105 on the basis of the plan view of the flat area contact one side of the outer side of the flat area, or Alternatively, it may include a third type buried groove 500 formed in the form of embedding the buried plate 305 of the touch part 105 in contact with a design division line for dividing the flat area into a plurality of divided areas.

Referring to FIG. 5A corresponding to the method of the present invention, the middle plate part 210 is a type 1 buried groove for embedding the buried plate 305 of the touch portion 105 in the form of a closed shape on the flat plate area. 500 and a second type buried groove for embedding the buried plate 305 of the touch portion 105 so that the touch implementation portion 310 or the contact surface of the touch portion 105 is in contact with the outer edge of the flat plate area. 500).

The first type buried groove 500 may be implemented in a vertical direction or a horizontal direction as in the implementation method of FIG. 5A, and according to the implementation method, a specific angle (e.g., 45 degrees, etc.) based on a specific side of the flat plate area It can be implemented at an angle.

The second type buried groove 500 is formed of the buried plate 305 as in the implementation method of FIG. 5A in order to contact the touch implementing portion 310 or the contact surface of the touch portion 105 at the outer edge of the flat area. It is preferable that the angled portion is implemented so as to contact the outer edge portion of the flat plate area.

Referring to Figure 5a corresponding to the implementation method of the present invention, the middle plate part 210 is inserted into the protrusion 400 of the upper plate part 205 to align the upper plate part 205 and the middle plate part 210 in a line. It has a concave portion 505 to be coupled. The groove portion 505 is formed with a diameter into which the protrusion portion 400 of the upper plate portion 205 can be inserted.

Referring to Figure 5b corresponding to the implementation method of the present invention, the first type buried groove 500 and the second type buried groove 500 of the middle plate portion 210, in accordance with the direction of the buried groove 500 The buried plate 305 of 105 is embedded, and the contact surfaces 300 of the touch portion 105 embedded in each buried groove 500 (or the midpoint of the contact surfaces 300 of the touch portion 105) Forms geometric positional relationships in the design.

Referring to Figure 5c corresponding to the method of the present invention, the groove portion 505 of the middle plate portion 210 is arranged in a form inserted into the protrusion portion 400 of the top plate portion 205, and the upper plate portion 205 and The middle plate part 210 is coupled.

6 is a view showing the structure of the middle plate 210 according to another embodiment of the present invention.

In more detail, FIG. 6 shows an embodiment in which the first type buried groove 500 is provided based on the embodiment of the middle plate part 210 shown in FIG. 5. For those of skill in the art, various implementation methods for the structure of the middle plate 210 by referring and/or modifying the drawings shown in the embodiments of the present invention (e.g., some components are omitted, modified, or integrated implementation) Method) may be inferred, but the present invention is made including all of the above inferred implementation methods, and it is obvious that the technical features of the present invention are not limited only by the implementation methods shown below.

Referring to Figure 6a corresponding to the implementation method of the present invention, the middle plate portion 210 is provided with the first type buried groove 500 and the second type buried groove 500 shown in Figure 5, touch A third type buried groove 500 for embedding the buried plate 305 of the touch portion 105 may be provided by contacting the touch implementation portion 310 or the contact surface of the portion 105 with one side of the outer side of the flat plate area. have. Alternatively, when the flat plate area is divided into a plurality of divided areas by design, the middle plate part 210 is in contact with a design division line for dividing the flat area into a plurality of divided areas, and the buried plate of the touch unit 105 ( A third type buried groove 500 for embedding 305 may be provided.

In the third type buried groove 500, the position and direction of the buried groove 500 is determined so that one side of the buried plate 305 is in contact with one side of the outer side of the flat plate area or the division line in design.

Referring to Figure 6a corresponding to the implementation method of the present invention, the middle plate part 210 is inserted into the protruding part 400 of the upper plate part 205 to align the upper plate part 205 and the middle plate part 210 in a line. It has a concave portion 505 to be coupled. The groove portion 505 is formed with a diameter into which the protrusion portion 400 of the upper plate portion 205 can be inserted.

Referring to Figure 6c corresponding to the implementation method of the present invention, the groove portion 505 of the middle plate portion 210 is aligned in a form inserted into the protrusion portion 400 of the upper plate portion 205, and the upper plate portion 205 and The middle plate part 210 is coupled.

7 is a view showing the structure of the lower plate portion 215 according to an exemplary method of the present invention.

In more detail, FIG. 7 shows the structure of the lower plate part 215 for protruding the contact surface 300 of the touch part 105 embedded in the middle plate part 210 shown in FIG. 5 to the outside. FIG. 7A is a bottom view of the lower plate part 215 in which the protruding groove 700 protruding outwardly protrudes the contact surface 300 of the touch part 105 embedded in the middle plate part 210 shown in FIG. 5 7B shows a state in which the touch part 105 protrudes through the protruding groove 700 of the lower plate part 215, and FIG. 7c shows the upper plate part 205, the middle plate part 210, and the lower plate part ( 215) shows a side view of the assembled state. For those of ordinary skill in the art to which the present invention belongs, various implementation methods for the structure of the lower plate part 215 by referring and/or modifying the drawings shown in the embodiments of the present invention (eg, some components are omitted or , Or modified, or an integrated implementation method), but the present invention includes all of the above inferred implementation methods, and the technical features of the present invention are by no means limited only to the implementation methods shown below. It is clearly stated.

The lower plate part 215 includes a plurality of protruding grooves 700 through which the touch implementation parts 310 of the plurality of touch parts 105 protrude. According to the implementation method of the present invention, the position of each protruding groove 700 to be provided on the lower plate portion 215 is calculated or designed through a program provided in a designated computer, and accordingly, is produced through a designated production device. At this time, a key element determining the position and direction of the protruding groove 700 provided in the lower plate part 215 is the contact surface 300 of the touch part 105 protruding through the lower plate part 215. It is a geometrical positional relationship formed by a plurality of touch points when the touch screen is touched. And this geometrical positional relationship is distinguished recognition that a plurality of touch points touched through the same touch coating 100 should be distinguished and recognized as respective unique touch points, and a plurality of touched points touched through different touch coatings 100 The geometric positional relationship formed by the touch points must have a discrimination that different touch positional relationships are formed for each of the touch coatings 100.

According to the present invention, the middle plate part 210 and the lower plate part 215 are manufactured as one set based on the geometrical positional relationship formed by the plurality of touch parts 105 provided in the touch coating 100. The geometrical positional relationship formed by the plurality of touch parts 105 protruding through the protruding groove 700 provided in the lower plate part 215, and the minimum discrimination recognition distance and minimum discrimination for satisfying discrimination recognition and discrimination for this For a description of the distance, refer to the description of FIG. 5.

Referring to FIG. 7A corresponding to the method of implementing the present invention, the lower plate portion 215 includes a touch portion corresponding to the buried plate 305 embedded in the first type buried groove 500 shown in FIG. 5 ( The first type protruding groove 700 protruding the touch implementation part 310 or the contact surface 300 of 105), and the buried plate 305 embedded in the second type buried groove 500 shown in FIG. 5 A second type protruding groove 700 protruding from the touch implementation unit 310 or the contact surface 300 of the touch unit 105 corresponding to is provided.

Referring to Figure 7a corresponding to the method of the present invention, the lower plate part 215 is inserted into the protruding part 400 of the upper plate part 205 so that the upper plate part 205, the middle plate part 210, and the lower plate part 215 are inserted. ) Is provided with a concave groove portion 505 to align and combine in a line. The groove portion 505 is formed with a diameter into which the protrusion portion 400 of the upper plate portion 205 can be inserted.

Referring to Figure 7c corresponding to the implementation method of the present invention, the groove portion 505 of the lower plate portion 215 is arranged in a form inserted into the protrusion portion 400 of the upper plate portion 205, and the upper plate portion 205 and The middle plate part 210 and the lower plate part 215 are coupled, and each touch part 105 protrudes in the first type protruding groove 700 and the second type protruding groove 700 of the lower plate part 215, respectively. do.

8 is a view showing the structure of the lower plate portion 215 according to another embodiment of the present invention.

In more detail, FIG. 8 shows the structure of the lower plate part 215 for protruding the contact surface 300 of the touch part 105 embedded in the middle plate part 210 shown in FIG. 6 to the outside. FIG. 8A is a bottom view of the lower plate part 215 in which the protruding groove 700 protruding outwardly protrudes the contact surface 300 of the touch part 105 embedded in the middle plate part 210 shown in FIG. 6 Figure 8b shows a state in which the touch part 105 protrudes through the protruding groove 700 of the lower plate part 215, and figure 8c shows the upper plate part 205, the middle plate part 210, and the lower plate part ( 215) shows a side view of the assembled state. For those of ordinary skill in the art to which the present invention belongs, various implementation methods for the structure of the lower plate part 215 by referring and/or modifying the drawings shown in the embodiments of the present invention (eg, some components are omitted or , Or modified, or an integrated implementation method), but the present invention includes all of the above inferred implementation methods, and the technical features of the present invention are by no means limited only to the implementation methods shown below. It is clearly stated.

Referring to FIG. 8A corresponding to the method of the present invention, the lower plate part 215 is a touch part corresponding to the buried plate 305 embedded in the first type buried groove 500 shown in FIG. 6 ( The first type protruding groove 700 protruding the touch implementation part 310 or the contact surface 300 of 105), and the buried plate 305 embedded in the second type buried groove 500 shown in FIG. 6 The second type protruding groove 700 protruding from the touch implementation unit 310 or the contact surface 300 of the touch unit 105 corresponding to and embedded in the third type buried groove 500 shown in FIG. 6 A third type protruding groove 700 for protruding the touch implementation part 310 or the contact surface 300 of the touch part 105 corresponding to the embedded plate 305 is provided.

Referring to Figure 8a corresponding to the method of the present invention, the lower plate part 215 is inserted into the protruding part 400 of the upper plate part 205 so that the upper plate part 205, the middle plate part 210, and the lower plate part 215 are inserted. ) Is provided with a concave groove portion 505 to align and combine in a line. The groove portion 505 is formed with a diameter into which the protrusion portion 400 of the upper plate portion 205 can be inserted.

Referring to Figure 8c corresponding to the implementation method of the present invention, the groove portion 505 of the lower plate portion 215 is aligned in a form inserted into the protrusion portion 400 of the upper plate portion 205, and the upper plate portion 205 and The middle plate part 210 and the lower plate part 215 are coupled, and each of the first type protruding groove 700, the second type protruding groove 700, and the third type protruding groove 700 of the lower plate part 215 Each of the touch parts 105 protrudes.

9 is a view showing the structure of the bottom of the housing unit 225 according to the embodiment of the present invention.

In more detail, FIG. 9 shows the structure of the bottom surface of the housing part 225 housing the flat plate part 200, and those of ordinary skill in the art to which the present invention pertains, shown in the embodiment of the present invention. Various implementation methods for the structure of the housing part 225 may be inferred by referring to and/or modifying the drawings (e.g., some components are omitted, or modified, or an integrated implementation method), but the present invention It is made including all the implementation methods, and it is obvious that the technical features of the present invention are not limited only by the implementation methods shown below.

Referring to Figure 9 corresponding to the implementation method of the present invention, the housing unit 225, in order to imprint the touch coating 100 on the capacitive touch screen, the bottom surface of the housing unit 225 is attached to the capacitive touch screen. A non-slip part 900 is provided to prevent the housing part 225 from slipping in a contact state. Preferably, the anti-slip unit 900 is a non-conductive material (for example, a non-conductive material (eg, a glass material, a transparent plastic material, etc.) that prevents slipping as the friction coefficient is greater than a specified reference value for the material of the capacitive touch screen. It is preferable to include a non-conductive rubber material, a non-conductive silicone material). The non-slip part 900 may be attached to the bottom surface of the housing part 225 by an adhesive.

The non-slip part 900 is at least one of the straight non-slip part 900 attached to the side area of the bottom area of the housing part 225 and the circular non-slip part 900 attached to a certain area. It may include a part 900.

According to the implementation method of the present invention, when the bottom of the housing part 225 is in contact with the capacitive touch screen in order to imprint the touch coating 100 on the capacitive touch screen, the non-slip part 900 By preventing the touch coating 100 from slipping on the capacitive touch screen, errors or errors do not occur in the recognition and interpretation of touch points for the geometric arrangement structure of multiple touch points by simultaneous touch of the present invention. This gives reliability to the touch coating 100 of the present invention to be used as an authentication means or identification means.

FIG. 10 is a diagram illustrating the appearance of a touch coating 100 manufactured according to an exemplary method of the present invention.

In more detail, FIG. 10A illustrates the side surface of the touch coating 100, and FIG. 10B illustrates the bottom surface of the touch coating 100. Those of ordinary skill in the art to which the present invention pertains will be able to infer various implementation methods for the appearance of the touch coating 100 by referring and/or modifying the drawings shown in the embodiments of the present invention. The present invention is made including all of the above inferred implementation methods, and it is obvious that the technical features of the present invention are not limited only by the following implementation methods.

100: touch coating 105: touch part
110: frame portion 115: handle portion
200: flat plate 205: upper plate
210: middle plate 215: lower plate
220: adapter part 225: housing part

Claims (16)

In the touch coating to be touched on the capacitive touch screen,
A plurality of touch units made of a conductive material capable of capacitive touch on the capacitive touch screen;
A handle portion formed to be gripped by a human hand and having a contact portion made of a conductive material or at least one side of a conductive material; And
While forming a unique geometrical positional relationship including a pre-designed distance relationship and an angular relationship in which the midpoints of the point contact surfaces of the plurality of touch units do not overlap for each touch coating, It includes a flat plate portion, the frame portion having a structure that electrically connects the conductive material of the handle portion and the plurality of touch portions; and,
The geometrical positional relationship includes a relative coordinate relationship including a distance relationship and an angular relationship formed by a plurality of touch points recognized by touching the plurality of touch units disposed and fixed on the flat panel to a flat area of the capacitive touch screen. and,
The plurality of touch units, wherein before being touched on the capacitive touch screen, the capacitive capacitance caused by a human body in contact with the handle is stored.
The method of claim 1, wherein the frame unit,
Touch coating, characterized in that it further comprises a housing portion housing a flat portion having a plurality of touch portions.
The method of claim 1,
And an adapter for connecting the flat portion to the handle portion or the flat portion to the housing portion connected to the handle portion.
delete The method of claim 1, wherein the plurality of touch units,
A touch coating comprising a cylindrical touch implementation unit that maintains a boundary of a contact surface in contact with the capacitive touch screen in a circular or polygonal shape.
delete The method of claim 1, wherein the plurality of touch units,
When touching the capacitive touch screen in the state of being disposed and fixed on the flat plate, the center portion of the contact surface that contacts the capacitive touch screen is protruded to touch the capacitive touch screen first, and then rounded according to a predetermined curvature. Touch coating, characterized in that it comprises a contact surface of a shaped shape.
delete The method of claim 1, wherein the flat plate portion,
And fixing the plurality of touch units to the same height or fixing at least one touch unit of the plurality of touch units to different heights.
The method of claim 1, wherein the flat plate portion,
Touch coating, characterized in that comprising a predetermined area arranged in a predetermined geometrical positional relationship of the plurality of touch units.
delete delete delete delete delete delete

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