KR102217376B1 - Touch Unit - Google Patents

Abstract

The present invention relates to a touch unit, in a touch unit that is held in a hand or carried and mounted on an object capable of contacting the human body and is to be touched on a capacitive touch screen provided in the device, which can be restored after contraction and is made of an electrostatic change inducing material. The plurality of touch units and the plurality of touch units are arranged and fixed according to the pre-designed touch order while the geometric positional relationship including the distance relationship and the angular relationship between the midpoints of the plurality of touch units are arranged and fixed in a pre-designed and unique geometrical positional relationship. A height of at least one of the plurality of touch units is provided at a different height in a design corresponding to the touch order so as to sequentially touch the capacitive touch screen.

Description

Touch Unit {Touch Unit}

The present invention provides a touch unit that is held in a hand or carried and mounted on an object capable of contact with the human body and is to be touched on a capacitive touch screen provided in the device, the plurality of touch units made of a material that can be restored after contraction and are made of a material that induces electrostatic changes, The plurality of touch units are sequentially arranged on the capacitive touch screen according to the pre-designed touch sequence while the geometric position relationship including the distance relationship and the angular relationship between the midpoints of the plurality of touch units are arranged and fixed in a pre-designed unique design geometric position relationship. The present invention relates to a touch unit including a frame unit having a height of at least one of the plurality of touch units to be touched at a different height in a design corresponding to the touch order.

A touch unit service is disclosed in which a plurality of touch units made of a static change inducing material are provided on a painted object, and the geometrical positional relationship formed by the plurality of touch units is used as various authentication means or identification means by touching them on a capacitive touch screen. .

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).

On the other hand, in order to use the geometrical positional relationship of a plurality of touch units provided in the touch unit as an authentication means or identification means, a plurality of touch units provided in at least two or more different touch units are formed by different geometrical positional relationships and all kinds of electrostatics It must have a recognizable recognition property on an expression touch screen.

However, in the case of a touch screen provided in some recently released smartphones, there is a touch screen that simultaneously supports both capacitive touch and pressure-based pressure-sensitive touch, not only capacitive touch using capacitance. In general, when a touch unit is touched on a touch screen, a predetermined pressure is applied, and such a touch screen does not recognize it as a capacitive type, but recognizes it as a pressure-sensitive type. However, the pressure-sensitive touch does not support multiple touches. Therefore, even though a plurality of touch units provided in the touch unit are touched on the touch screen, they are not recognized.

An object of the present invention for solving the above problems is, in a touch unit that is held in a hand or carried and mounted on an object capable of contact with the human body to be touched on a capacitive touch screen provided in the device, it is possible to restore after contraction and A plurality of touch units made of a change-inducing material and a geometric positional relationship including a distance relationship and an angular relationship between the midpoints of the plurality of touch units are arranged and fixed as a geometric positional relationship in a unique design. The object of the present invention is to provide a touch unit including a frame unit having a height of at least one of the plurality of touch units at a different height in a design corresponding to the touch order so as to sequentially touch the capacitive touch screen according to a designed touch order.

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The touch unit according to the present invention is a touch unit that is held in a hand or carried and mounted on an object capable of contacting the human body, and is to be touched on a capacitive touch screen provided in the device, and can be restored after contraction, A geometrical positional relationship including a distance relationship and an angular relationship between the touch unit of the touch unit and the midpoints of the plurality of touch units are arranged and fixed in a geometric positional relationship based on a pre-designed unique design, while the plurality of touch units are electrostatically configured according to a pre-designed touch sequence. And a frame unit having a height of at least one of the plurality of touch units at a different height in a design corresponding to the touch order so as to sequentially touch the touch screen.
In the touch unit according to the present invention, the plurality of touch units are characterized in that the specified capacitance is stored before being touched on the capacitive touch screen.
In the touch unit according to the present invention, the touch unit is characterized in that it comprises a cylindrical touch body that maintains a circular boundary of a contact surface in contact with the capacitive touch screen.
In the touch unit according to the present invention, the touch unit includes a touch body unit that maintains a polygonal boundary of a contact surface that contacts the capacitive touch screen.
In the touch unit according to the present invention, the plurality of touch units are characterized in that a capacitance of 100pF to 300pF by a human body is stored.
In a touch unit to be touched on a capacitive touch screen provided in a device, the touch unit according to the present invention includes a plurality of touch units made of a static change inducing material, and the plurality of touch units at a designated geometric positional relationship and a designated different height. A frame portion including a flat plate portion and a handle portion formed to be gripped by a human hand are provided, and the plurality of touch portions store a specified capacitance before being touched on the capacitive touch screen.

According to the present invention, the plurality of touch portions may be fixed to at least one touch portion at different heights based on the flat surface of the flat portion.

According to the present invention, the touch unit may further include a housing portion protecting the plurality of touch portions or flat portions.

According to the present invention, the housing portion may include a plate through groove through which the coupling portion of the plate portion passes, and a through guide portion that guides the coupling portion of the plate portion through the plate through groove.

According to the present invention, the housing part may include an adapter guide part for guiding the body of the adapter part coupled to the flat part. Meanwhile, the adapter guide part may include an inner guide part for guiding the inside of the adapter part, and an outer guide part for guiding the outside of the adapter part.

According to the present invention, the housing part may include a flat guide part for guiding the flat part. Meanwhile, the flat guide part includes a protruding flat guide part for guiding the flat plate in a state protruding from the inside of the housing part to the flat side, and a buried flat guide part for guiding by embedding a part protruding from the flat side inside the body of the housing part. And, the inside of the body of the housing unit may include one or more of the flat plate guides for guiding the flat plate.

According to the present invention, the touch unit may further include an adapter portion coupled to the flat plate portion and interfacing with the housing portion protecting the flat plate portion.

According to the present invention, the touch unit may further include a spring portion provided between an adapter portion coupled to the flat plate portion and a housing portion protecting the flat plate portion.

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

According to the present invention, the touch unit may include a touch body unit that maintains a polygonal boundary of a contact surface in contact with the capacitive touch screen.

According to the present invention, the touch unit may include a protrusion protruding from the center of the contact surface to the capacitive touch screen within a designated contact boundary.

According to the present invention, an empty space for inducing internal contraction may be formed inside the touch part.

According to the present invention, the touch unit may include one or more contraction grooves for inducing contraction of the capacitive touch screen in the vertical direction.

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

According to the present invention, the touch unit includes a capacitive power storage unit that stores and maintains a specified capacitance, 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, in a touch screen that simultaneously supports capacitive and pressure-sensitive touch by sequentially touching a plurality of touch units provided at different heights in a specified order on the capacitive touch screen, the first touch is recognized as a pressure-sensitive type. The remaining touches are recognized in a capacitive manner, and as a result, there is an advantage that all of the plurality of touch units provided in the touch unit are recognized on the touch screen.

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

According to the present invention, through the act of touching the touch unit 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 structure of a touch unit according to the present invention.
2 is a diagram illustrating a structure of a touch unit 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 the lower plate according to an embodiment of the present invention.
7 is a diagram showing the structure of an adapter unit according to an embodiment of the present invention.
8 is a view showing the structure of a housing according to an embodiment of the present invention.
9 is a view showing an assembly view of assembling a flat plate part, an adapter part, and a housing part according to an embodiment 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 structure of a touch unit 100 according to the present invention.

In more detail, FIG. 1 shows a structure of a touch unit 100 that sequentially touches a plurality of touch units 105 arranged in a designated geometric positional relationship to a capacitive touch screen in a designated order. The corresponding touch unit 100 includes a plurality of touch units 105 made of an electrostatic change inducing material that can be touched on a capacitive touch screen, and the plurality of touch units 105 are arranged in a specified geometric positional relationship to provide a capacitive touch. It includes a frame portion 110 including a flat plate portion 115 fixed to be touched on the screen, and a handle portion 120 formed to be held by a human hand and touched on the capacitive touch screen. That is, a plurality of touch units 105 made of electrostatic change inducing material, a frame unit 110 that arranges them in a designated geometrical position to be touchably fixed to the capacitive touch screen, and a handle unit 120 that can be held by hand. Articles having a belong to the scope of the right scope of the touch unit 100 of the present invention. For convenience of explanation, in the embodiment of the present invention, the touch unit 100 will be illustrated and described as a painting-type object, but the structural features of the touch unit 100 of the present invention are not limited thereto, and the present invention The touch unit 100 of is manufactured in the form of a module including a touch unit, excluding some components necessary for maintaining the painting form, and is mounted/embedded in various items (eg, cards, accessories, etc.) that can be held or carried in the hand. It should be clearly stated that it can be implemented in the form of various objects that can be held in the hand or carried in addition to objects in the form of stamps or stamps.

In the embodiment of the present invention, the term including the'pressing force'or'pressingforce' is a term applied when the touch unit 100 is a painting type object or a module mounted on a painting type object. , If the touch unit 100 is not a painted object or is not mounted on a painted object, it may not be applied.

Touching the plurality of touch units 105 provided in the touch unit 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 person's hand holds the handle 120 of the touch unit 100 and touches a plurality of touch units 105 provided on the flat plate 115 of the touch unit 100 by capacitive touch. Touch the screen, but the plurality of touch units 105 are touched by a specified number on the capacitive touch screen, and each of the touch units 105 touched on the capacitive touch screen forms a contact area equal to or greater than the calculated area. It is a touch to be touched on the capacitive touch screen.

According to an embodiment of the present invention, a plurality of touch portions 105 fixed to the flat portion 115 of the frame portion 110 provided in the touch unit 100 are based on the flat surface of the flat portion 115. At least one of the heights is fixed at different heights. In this case, the plurality of touch units 105 made of the electrostatic change inducing material sequentially touch the capacitive touch screen in a specified order (eg, height difference) (eg, sequentially touch from the highest touch unit 105) It has the characteristics of painting touch. For the sequential painting touch, a predetermined pressing force may be applied to the touch unit 100, and in this case, the pressing force may be applied through the handle 120. 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.

Paint touch using the touch unit 100 of the present invention has an element that is differentiated from a conventional multi-touch (Multi-Touch). Multi-touch is a touch that uses as an input means a touch point 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. This is a touch using the touch unit 100 as an identification means or an authentication means by authenticating whether it matches within an allowed error range.

In order to implement the painting touch according to the present invention, a plurality of touch units 105 made of a static change inducing material capable of capacitively touching the capacitive touch screen, and a flat plate having a predetermined area on at least one side thereof, A frame unit 110 including a flat plate unit 115 for arranging and fixing the units 105 in a designated geometrical positional relationship, and a plurality of touch units 105 fixed to the flat unit 115 are capacitive touch screens. An object having a handle portion 120 formed to be held by hand so as to be touched is required. Any object having the touch portion 105, the frame portion 110, and the handle portion 120 is required. It corresponds to the touch unit 100 of the invention.

The touch unit 105 is a generic term for a component that touches a capacitive touch screen among parts constituting the touch unit 100, is made of an electrostatic change inducing material, and a designated contact area to be touched on the capacitive touch screen (or (Area larger than the designated contact area), and the designated capacitance is stored before or during the touch of the capacitive touch screen.

According to the first capacitive power storage method of the present invention, the plurality of touch parts 105 may store electrostatic capacity of a human body holding the handle part 120. To this end, the handle part 120 may be made of a conductive material or may be plated (or coated) with a conductive material, or at least one side of the handle part 120 may be made of a conductive material or a conductive material may be plated (or A contact portion (not shown) applied) may be provided. The handle portion 120 (or 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 power storage method of the present invention, the plurality of touch units 105 may store the capacitance stored in the capacitive power storage unit (eg, a super capacitor or a battery) provided in the touch unit 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 material that induces electrostatic changes having a soft or semi-soft or semi-hard property. For example, the touch part 105 may be made of a conductive rubber material or a conductive plastic material having rubber elasticity.

According to the first touch part implementation method of the present invention, the touch part 105 may be manufactured using a conductive material having rubber elasticity of at least one of a conductive rubber material, a conductive plastic material, and a conductive silicone material. It may be manufactured to have a pre-designed hardness (eg, 80 or less based on a Shore A hardness tester) and electrical resistance (eg, a measurement resistance value of 300 Ω or less between a touched part and a part electrically connected to the human body). For example, when the touch part 105 of the first touch part embodiment is made of a conductive rubber material, the conductive rubber is mixed with conductive carbon (eg, conductive carbon or metal powder) and rubber in a calculated ratio. It may be manufactured, and hardness and electrical resistance may be determined according to the mixing ratio of the rubber and conductive carbon.

According to the second touch unit implementation method of the present invention, the touch unit 105 may be manufactured using a metallic material, and the metal material has a high electrical conductivity (eg, touched) such as gold, silver, copper, and aluminum. Any material may be used as long as the measured resistance between the part and the part electrically connected to the human body is less than 1Ω). Meanwhile, when the touch part 105 is made of a metallic material, the touch screen may be damaged at the time of touching the touch screen made of a glass material. Accordingly, a touch film made of a material capable of buffering the amount of impact (for example, 90 or less based on the Shore A hardness tester) may be formed between the metallic touch part 105 and the touch screen by transmitting the electrostatic change induction of the touch part 105. have. The touch film is manufactured in a form that is individually attached to each touch part 105, a designated number of touch parts 105 are attached to the touch film, or is spaced apart from each touch part 105 at a predetermined interval. Then, it may be manufactured in a structure in which the touch unit 105 and the touch film contact each other at the touch point. Preferably, the touch layer is preferably made of an opaque material.

According to the third method of implementing the touch unit of the present invention, the touch unit 105 may be manufactured by plating a metallic material on a non-conductive material. If the non-conductive material has a hardness sufficient to damage the touch screen (e.g., 90 or higher based on the Shore A hardness tester), the touch film is formed on the touch part 105 coated with a metallic material on the non-conductive material. I can.

According to the fourth method of implementing the touch unit of the present invention, the touch unit 105 may be manufactured by forming a metallic film made of a metallic material on the outside of an elastic buffer material. The cushioning material may be made of a foamable material such as sponge or polyurethane, and the metal film may be manufactured by plating a metallic material on the cushioning material and/or using a metallic material as yarn or cotton yarn. For example, the touch part 105 manufactured by forming a metal film of the buffer material may have a structure of a gasket for EMI shielding.

According to the fifth method of implementing the touch part of the present invention, the touch part 105 may be manufactured using a carbon fiber material including a carbon nanotube material or a single-walled carbon nanotube material, and preferably has a previously designed hardness ( For example, it can be manufactured with a Shoa A hardness tester standard of 80 or less).

According to the sixth method of implementing the touch unit of the present invention, the touch unit 105 may be manufactured using a dielectric material consisting of a solid dielectric material or a liquid dielectric material and a container storing the same. Dielectric material is a generic term for materials in which polarization is generated by a voltage or electric field and constrained charges are generated on the surface.Polarization is generated by a voltage or electric field applied to the surface of the touch screen, thereby generating constrained charges that can induce electrostatic changes. It is preferable that it contains a ferroelectric material (eg, barium titanate or Rossel salt) having a dielectric constant to be generated.

On the other hand, the embodiment of the touch unit 105 of the present invention is by no means limited to the case of the first to sixth touch unit embodiments, and is made of a material that is electrically connected to the human body and induces electrostatic change of the capacitive touch screen. If so, it is clearly stated that any material falls within the scope of the present invention.

According to an exemplary method of the present invention, it is preferable that the touch unit 105 includes a contact surface 300 having a designated contact area to be touched on a capacitive touch screen. The contact surface 300 of the touch unit 105 is a portion formed in a direction to be touched on the capacitive touch screen among the portions of the touch unit 105 and is formed in a designated geometric shape (eg, polygonal or circular), It has a calculated contact area. Preferably, the contact surface 300 may be manufactured in a geometric shape of a square shape or a geometric shape of a circular shape having the calculated contact area.

According to an exemplary method 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 unit 100 is to be touched. Preferably, it is assumed that the touch unit 100 touches 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 49 mm2, and the designated device (c If the touch sensitivity of the capacitive touch screen (c) of) is 81mm2, the contact area of the touch part 105 is calculated as 81mm2 corresponding to the lowest touch sensitivity among the 25mm2, 49mm2, and 81mm2. As a result, it is possible to enable touch recognition on each capacitive touch screen of the device (a), device (b) and device (c). Here, the touch unit 100 is provided with the contact area of the touch unit 105 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. 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 49 mm2, and the designated device (c If the touch sensitivity of the capacitive touch screen c of) is 81 mm 2, the contact area of the touch unit 105 includes a contact area of 81 mm 2 or more corresponding to the lowest touch sensitivity among the 25 mm 2, 49 mm 2 and 81 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).

According to the third contact area implementation method of the present invention, when a capacitive power storage unit is provided in the touch unit 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 unit 100, the contact area of the touch unit 105 is the blackout 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.

The contact surface 300 of the touch unit 105 must be touched with a contact area (or a contact area equal to or greater than the calculated area) calculated at the time when the capacitive touch screen is touched, and for this purpose, the contact surface 300 is basically It has a flat structure. Meanwhile, when the contact surface 300 of the touch unit 105 has a flat structure, the surface that is first touched on the capacitive touch screen according to the method in which the touch unit 100 is touched (for example, an oblique touch method) is a contact surface. It may be a boundary portion of 300, and in this case, the boundary portion in the opposite direction of the contact surface 300 may not be touched. In this case, the capacitive touch screen is the center of the entire contact surface 300 of the touch unit 105 Instead of recognizing as a touch point, the focus may be determined based on the touched boundary portion and recognized as a touch point. In this way, when the touch unit 105 is touched on the capacitive touch screen, the movement of the focus from the calculated touch point position (that is, the center position of the touch unit 105) is a plurality of touches provided in the touch unit 100. The geometrical positional relationship formed by the parts 105 is used as an authentication means or an identification means, which acts as a disturbing factor (however, the shift of the midpoint of the allowed error range can be corrected).

According to the embodiment of the present invention, in order to prevent the movement of the center as described above, the contact surface 300 of the touch unit 105 has a geometrical planar structure designated so that the contact area calculated on the capacitive touch screen is touched. Basically included, and in a state in which the planar structure is maintained (ie, a boundary of a geometric shape is maintained), the central portion of the contact surface 300 protrudes in a direction to be touched on the capacitive touch screen ( 305) is preferably produced. For example, if the geometric shape of the contact surface 300 is circular, the protrusion 305 of the contact surface 300 protrudes in a conical shape with the circle as a bottom surface, or protrudes in a hemispherical shape with a predetermined curvature. Can be. The protrusion 305 prevents movement of the center of the touched surface on the capacitive touch screen by always allowing the central portion of the contact surface 300 to first touch the capacitive touch screen, or at least moves within an allowable error range. Process. Through this, a plurality of touch units 105 provided in the touch unit 100 are touched on a capacitive touch screen to stably use the geometrical positional relationship formed by the plurality of touch units 105 as an authentication means or an identification means. I can.

The touch unit 105 is one or more of compression, bending, and torsion (compression in most cases) by a pressing force (or earth gravity) applied through the handle unit 120 at the time of touching the capacitive touch screen. This is applied, and the touch part 105 is deformed by the external force. However, even by the deformation by such an external force, the area of the touched surface on the capacitive touch screen must be maintained above the calculated contact area of the touch unit 105, and in particular, the capacitive touch screen is affected by the deformation by the external force. The midpoint of the touched surface should not move.

According to the implementation method of the present invention, the touch unit 105 is empty inside the touch unit 105 in order to induce the deformation of the touch unit 105 due to the external force to a contraction deformation toward the inside of the touch unit 105. It is manufactured so that the space 330 is formed. In a state in which the contact surface 300 of the touch unit 105 (for example, the protrusion 305 of the contact surface 300) is touched on the capacitive touch screen, the touch unit 105 When a compressive external force in the vertical direction is applied, the contact surface 300 of the touch part 105 (for example, the protrusion 305 of the contact surface 300) is caused by the empty space 330 formed inside the touch part 105. )) is contracted and deformed into the empty space 330, whereby the contact area of the touched surface on the capacitive touch screen is maintained, and the midpoint of the touched surface does not move. Alternatively, even if an external bending force or an external torsional force is applied while the contact surface 300 of the touch unit 105 touches the capacitive touch screen, drag the touch unit 105 while touching the capacitive touch screen ( Unless dragged), the contact area of the surface touched on the capacitive touch screen is maintained, and the midpoint of the touched surface does not move.

According to an exemplary method of the present invention, the touch unit 105 prevents deformation of the touch unit 105 due to an external force (for example, one or more of compression, bending, and twisting) applied while touching the capacitive touch screen. It may be manufactured to form a contraction groove 325 that induces vertical deformation of the capacitive touch screen. Preferably, the contraction groove 325 is preferably manufactured to include at least one, but a plurality of contraction grooves 325 are formed in proportion to the height at which the touch part 105 is exposed to the outside of the flat part 115. It can be made to contain. When a compressive external force in the vertical direction of the touch screen is applied to the touch unit 105 by a pressing force while touching the contact surface 300 of the touch unit 105 to the capacitive touch screen, the touch unit 105 ) By the contraction groove 325, the touch part 105 is contracted and deformed in the vertical direction of the capacitive touch screen, whereby the contact area of the surface touched on the capacitive touch screen is maintained, and the touched surface The midpoint of does not move.

The frame unit 110 is a component that fixes a plurality of touch units 105 to be touched on the capacitive touch screen among the parts constituting the touch unit 100 in a specified geometric positional relationship and connects them to the handle unit 120 Alternatively, as a generic term for a combination of constituent parts, it includes a flat plate 115 having a predetermined area and a designated geometric shape for fixing the plurality of touch parts 105 in a designated geometric positional relationship. One side of the frame unit 110 is connected to the handle unit 120 to transmit a pressing force applied through the handle unit 120 and/or a capacitance of the human body 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 120 (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 an exemplary method of the present invention, the frame unit 110 includes a flat plate area having a predetermined area in which the plurality of touch units 105 are arranged in a designated geometrical positional relationship, and a flat plate unit having a designated geometric shape forming the flat plate area. 115, and an adapter unit 230 that interfaces with the housing unit 215 so that the plurality of touch units 105 touch the capacitive touch screen while accommodating the flat plate unit 115, or It may be combined with the adapter unit 230. The flat plate portion 115 and the adapter portion 230 may be formed of respective modules that can be assembled, or may be manufactured as an integral type.

The handle part 120 is a generic term of a component formed to be held by a person's hand among parts constituting the touch unit 100, and receives a pressing force applied through the hand of the person and transmits it to the frame part 110. . One side of the handle part 120 is connected to the frame part 110. Alternatively, the handle portion 120 and the frame portion 110 may be formed of each module capable of being assembled, or may be manufactured integrally.

When the capacitance of the human body is stored by the touch part 105, the handle part 120 is made of a conductive material, or a conductive material is plated (or coated), or at least one side of the handle part 120 is conductive. A contact part made of a material or plated (or coated) with a conductive material may be provided.

The touch unit 100 according to the present invention protects the plurality of touch units 105 fixed to the frame unit 110 from being contaminated or damaged in a specified geometric positional relationship in a state in which no pressing force is applied, and/ Alternatively, a housing part 215 for guiding the plurality of touch parts 105 fixed to the frame part 110 to touch the capacitive touch screen by a pressing force applied through the handle part 120 is provided.

When the touch unit 105 of the touch unit 100 faces downward and is stored so that it touches the floor, the touch unit 105 exposed to the outside is contaminated by a foreign substance to reduce touch sensitivity or cause a touch error. I can. Alternatively, when the bottom surface is rough or when external energy is applied to the exposed touch portion 105, the exposed touch portion 105 may be physically damaged. In addition, external energy may damage or deform the frame unit 110. To prevent this, the housing part 215 accommodates the touch part 105 and the frame part 110 therein to protect the touch part 105 and the frame part 110 from contamination or damage. Preferably, the housing part 215 includes at least one spring part () so that the touch part 105 is separated from the floor at a predetermined height even when the touch part 105 of the touch unit 100 is stored downward. 225) may be provided.

The plurality of touch units 105 provided in the touch unit 100 are a flat panel structured touch screen by a pressing force applied through the handle unit 120 while being fixed to the frame unit 110 including the flat area. Is touched on. In order for the plurality of touch units 105 to touch the touch screen having a flat structure, the flat region of the frame unit 110 must be touched while maintaining a parallel relationship with the capacitive touch screen, and the housing unit 215 One or more guide units 220 may be provided to guide the flat region of the frame unit 110 to which the plurality of touch units 105 are fixed to be touched while maintaining a parallel relationship with the capacitive touch screen.

According to another embodiment of the present invention, the spring portion 225 and/or the guide portion 220 may be omitted, and a state in which the plurality of touch portions 105 are exposed to the outside of the housing portion 215 may be maintained.

Meanwhile, since the geometrical positional relationship of the plurality of touch units 105 provided in the touch unit 100 is used as one of important authentication factors for using the touch unit 100 as an authentication means or an identification means, the touch unit ( It is preferable that the geometric positional relationship of 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 unit 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 in the touch unit 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 provides the touch unit 100 to maintain mass production and quality control of the touch unit 100 while maintaining the uniqueness of the geometrical positional relationship with respect to the plurality of touch units 105 provided in the touch unit 100. May be manufactured through embodiments implemented through the following drawings and description. However, the embodiment of the touch unit 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 unit 100 of the present invention is It is clear that this applies.

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

In more detail, FIG. 2 shows that among various implementation methods for designing and manufacturing the touch unit 100 shown in FIG. 1, a plurality of touch units 105 can be designed and arranged in various geometric arrangement structures, and mass production and quality control are possible. It shows the internal cutting structure of the touch unit 100 manufactured through an easy embodiment. For those of ordinary skill in the art to which the present invention belongs, various implementation methods for the structure of the touch unit 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.

Referring to Fig. 2 according to an exemplary method of the present invention, the touch unit 100 includes a plurality of touch units 105 made of a material that induces electrostatic changes that can be touched on a capacitive touch screen, and the plurality of touch units A frame unit 110 including a flat plate 115 that arranges 105 in a designated geometrical positional relationship to be touched on a capacitive touch screen, and a plurality of touch units 105 fixed to the flat plate 115 ) Has a handle portion 120 formed to be held by hand so as to touch the capacitive touch screen, protects the plurality of touch portions 105 and the frame portion 110, and is fixed to the frame portion 110 A housing portion 215 for guiding a plurality of touch portions 105 to be touched on the capacitive touch screen, and an interface between the housing portion 215 while coupling the frame portion 110 and the handle portion 120 It includes an adapter unit 230.

The touch part 105 manufactured according to the implementation method of this drawing 2 is a generic term for a component that touches the capacitive touch screen among the parts constituting the touch unit 100, and is made of a material that induces electrostatic change, and the capacitive touch Includes a designated contact area to be touched on the screen (or an area greater than or equal to the designated contact area), and before or during the touch of the capacitive touch screen, according to at least one of the first or second capacitive power storage methods described in FIG. 1 Capacity can be stored.

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, it may be formed in a polygonal or circular shape), and may be manufactured to have a contact area corresponding to at least one of the first to fourth contact area implementation methods described in FIG. 1. The contact area of the touch unit 105 is an area correlated with the touch sensitivity of each capacitive touch screen to which the touch unit 100 is to be touched.

The contact surface 300 of the touch unit 105 basically includes a planar structure of a geometric shape designated so that the contact area calculated on the capacitive touch screen is touched, and a state in which the planar structure is maintained (i.e. While the boundary of the shape is maintained), the central portion of the contact surface 300 is manufactured including a protrusion 305 protruding in a direction to be touched on the capacitive touch screen.

The touch part 105 is manufactured to form an empty space 330 that induces deformation by an external force to internal contraction, and the touch part 105 is the empty space even when one or more external forces of compression, bending, and torsion are applied. Due to the internal contraction by 330, the contact area of the surface touched on the capacitive touch screen is maintained and the midpoint does not move.

The touch part 105 manufactured as described above is fixed to the flat part 115 of the touch unit 100 according to the designed geometrical positional relationship, and is fixed to a height calculated based on the flat surface of the flat part 115. . Preferably, in the implementation method of the present invention, the plurality of touch parts 105 fixed to the flat plate 115 are fixed at different heights, at least one having a different height based on the flat surface of the flat plate 115 do.

According to the implementation method of the present invention, the touch unit 105 is contracted to induce deformation of the touch unit 105 due to an external force applied while touching the capacitive touch screen into a vertical deformation of the capacitive touch screen. The groove 325 may be manufactured to be formed. For example, a plurality of touch units 105 fixed to the flat plate 115 are fixed at different heights, whereby the heights at which the touch units 105 must contract while touching the capacitive touch screen When is different, by providing the contraction groove 325 in the touch portion 105 fixed to the flat portion 115 to a height equal to or higher than a specified height, the capacitive touch screen is applied by an external force applied while touching the capacitive touch screen. It can be easily induced to contract in the vertical direction of the touch screen. The touch unit 105 maintains the contact area of the surface touched on the capacitive touch screen due to vertical contraction by the contraction groove 325 even when one or more external forces among compression, bending, and torsion are applied, and the center does not move. Will not be.

The frame unit 110 is a component that fixes a plurality of touch units 105 to be touched on the capacitive touch screen among the parts constituting the touch unit 100 in a specified geometric positional relationship and connects them to the handle unit 120 Alternatively, as a generic term for a combination of components, it includes a conductive material for transferring the capacitance of the human body input to the handle 120 or the capacitance stored in the capacitance storage unit to the touch unit 105. However, among the constituent parts of the frame part 110, the part that is touched on the capacitive touch screen together with the touch part 105 is made of a non-conductive material or is coated with a non-conductive material. It is made not to disturb the touch.

Referring to FIG. 2 according to an exemplary method of the present invention, the frame unit 110 includes a flat plate portion 115 including a flat area of a predetermined area in which the plurality of touch units 105 are arranged in a designated geometrical positional relationship. And, the flat plate portion 115 includes an upper plate portion 200 corresponding to a support frame supporting a plurality of touch portions 105 and a plurality of touch portions 105 supported by the upper plate portion 200 The middle plate part 205 corresponding to the embedded frame, which is embedded and maintained to be arranged in a designed geometrical positional relationship, and a plurality of touch parts 105 supported by the upper plate part 200 and embedded in the middle plate part 205 are designated. It includes a lower plate part 210 that is exposed to the outside by a specified height according to the geometrical positional relationship to be touched on the capacitive touch screen.

The upper plate part 200 includes a coupling part 405 coupled to the adapter part 230, and a plurality of touch parts 105 are applied to the capacitive touch screen for the pressing force applied through the handle part 120. It includes a flat plate that supports to be touched.

The middle plate part 205 is supported by the upper plate part 200 and the plurality of touch parts 105 are arranged so that the plurality of touch parts 105 exposed through the lower plate part 210 are arranged according to a specified geometrical positional relationship. It comprises a flat plate having a buried groove 505 for embedding them.

The lower plate part 210 is supported by the upper plate part 200 and has a protruding groove 605 that allows the plurality of touch parts 105 embedded in the middle plate part 205 to protrude outward according to a specified geometrical positional relationship. It consists of including the equipped plate.

At least one of the upper plate part 200, the middle plate part 205, and the lower plate part 210 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). However, the lower plate part 210 (at least the flat area protruding the touch part 105 from the lower plate part 210 to the outside) may be made of a non-conductive material or a conductive material may be applied.

The flat plate portion 115 is supported by the upper plate portion 200 while the upper plate portion 200, the middle plate portion 205, and the lower plate portion 210 are divided into layers, and is supported by the middle plate portion 205 in a geometrical positional relationship. It accommodates a plurality of touch portions 105 that are embedded and protrude in a geometrical positional relationship designated by the lower plate portion 210. The upper plate portion 200, the middle plate portion 205, and the lower plate portion 210 may be partitioned by an adhesive and/or partitioned by screw assembly. The adhesive may include a conductive adhesive.

Referring to Figure 2 according to the implementation method of the present invention, the adapter unit 230 is coupled to the flat plate 115 and includes a body that interfaces with the housing unit 215, the coupling portion of the upper plate 200 ( A coupling induction groove 710 for guiding the 405 to be coupled to the flat plate 115 may be provided. The adapter part 230 accurately positions the coupling part 405 of the upper plate part 200 at a designated position through the coupling induction groove 710 to couple with the flat plate part 115. Depending on the implementation method, the coupling induction groove 710 may be omitted.

The adapter unit 230 and the flat plate 115 may be coupled through an adhesive (eg, conductive adhesive) and/or through screw assembly. Preferably, the flat plate part 115 is coupled to the adapter part 230 through the adhesive in a state guided to a designated position of the adapter part 230 through the coupling guide groove 710, and/or It may be coupled to the adapter unit 230 through screw assembly.

When the adapter unit 230 and the flat plate 115 are coupled through screw assembly, the adapter unit 230 may have a bolt through groove 705 through which a bolt for screw assembly passes, and the upper plate unit The coupling portion 405 of 200 may be provided with a screw groove 410 for assembling the screw. When the adapter part 230 and the flat part 115 are not coupled by screw assembly, the bolt through groove 705 of the adapter part 230 and the screw groove 410 of the upper plate part 200 may be omitted.

The adapter part 230 interfaces with the housing part 215 while the flat part 115 is coupled. Referring to Fig. 2 according to an embodiment of the present invention, the housing part 215 includes a body for accommodating the flat plate 115, and the coupling part 405 of the flat plate 115 is attached to the adapter part. In a state in which a flat plate through groove 800 penetrated to be coupled to 230 is provided, and the flat plate portion 115 coupled with the adapter unit 230 through the flat plate through groove 800 is directed toward the floor. The portion 115 (or the touch portion 105 provided on the flat portion 115) is provided with at least one spring portion 225 for maintaining a predetermined height away from the floor. The spring part 225 does not include only a spring made of a wire as in the example of FIG. 2, and any material having repulsive elasticity (eg, a sponge) may be used as the spring part 225.

Referring to Figure 2 according to the implementation method of the present invention, when a pressing force is applied by the handle part 120, the housing part 215 moves the adapter part 230 and the flat part 115 in a designated direction. At least one guide unit 220 is provided to guide the plurality of touch units 105 provided on the flat panel 115 to be touched to the capacitive touch screen by guiding them to be spaced apart from each other. The guide part 220 may guide the plurality of touch parts 105 fixed to the flat part 115 at different heights to sequentially touch the capacitive touch screen in a specified order.

The housing part 215 includes a through guide part 220 for guiding the coupling part 405 of the flat part 115 penetrating through the flat through groove 800 and a body of the adapter part 230. An adapter guide part 220 and at least one guide part 220 of the flat guide part 220 guiding the flat part 115 are provided. Preferably, the adapter guide part 220 may include an inner guide part 220 for guiding the inside of the adapter part 230 and an outer guide part 220 for guiding the outside of the adapter part 230. According to the implementation method, the flat guide part 220 includes a protruding flat guide part 220 for guiding the flat part 115 in a state protruding from the inside of the body of the housing part 215 toward the flat plate, and the housing part ( A buried flat guide part 220 (not shown) for guiding a part protruding from the flat side inside the body of the body 215 (not shown), and a straight flat guide part for guiding the flat plate inside the body of the housing part 215 ( 220) may include at least one flat guide unit 220.

Referring to Fig. 2 according to the implementation method of the present invention, the handle part 120 is a generic term of a component formed to be held by a human hand among parts constituting the touch unit 100, and the pressure applied through the hand of the person Manpower is input and transmitted to the frame unit 110 through the adapter unit 230. One side of the handle part 120 is connected to the adapter part 230. The handle unit 120 and the adapter unit 230 may be connected through an adhesive or through screw assembly. When the capacitance of the human body is stored by the touch unit 105, the adhesive may include a conductive adhesive so that the capacitance of the human body holding the handle unit 120 is transmitted to the touch unit 105.

On the other hand, when the touch unit 100 of the present invention uses an additional authentication element other than the geometrical positional relationship with respect to the plurality of touch units 105, a component corresponding to the additional authentication element (e.g., NFC A chip (not shown) and an antenna (not shown), or a chip module (not shown) and a sound output unit (not shown) for generating a sound signal may be provided on the handle unit 120. Alternatively, a component corresponding to the additional authentication element may be provided in the frame portion 110 and/or the housing portion 215.

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 through the upper plate part 200, embedded in the middle plate part 205, and protruding to the outside through the lower plate part 210. 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. For convenience, this drawing 3 illustrates an embodiment in which the contact surface 300 of the touch unit 105 is circular, but the contact surface 300 of the touch unit 105 is not limited to a circle, and even if it is circular, It is obvious that it can be transformed into a shape, and can be implemented in the form of various polygons (eg, squares, etc.) other than a circle.

A plurality of touch units 105 provided in the touch unit 100 of the present invention are geometric shapes designated through the lower plate unit 210 on the buried plate 310 of a certain area embedded in the middle plate unit 205 It is manufactured in a form of forming a touch body 320 corresponding to a body exposing the contact surface 300 of (eg, polygonal or circular) to the outside, and the buried plate 310 and the touch body 320 An empty space 330 is formed in the interior, and a central portion of the contact surface 300 includes a protrusion 305 protruding in a direction to be touched.

The buried plate 310 is a generic term for a configuration embedded in the buried groove 505 provided in the middle plate of the flat portion 115 among the configurations of the touch portion 105, and is manufactured in a plate shape, and the touch body portion ( 320) is fixed to one surface, and has a designated geometric shape having an area larger than the contact area of the contact surface 300 at least.

Referring to Figures 3a, 3b, and 3c according to the implementation method of the present invention, the buried plate 310 is an angled buried portion 315 and/or a curved buried portion on the outer side of the touch implementation portion. It is made of a plate including 315, and according to an implementation method (eg, an implementation method of fixing the buried plate 310 through an adhesive), the recessed portion 315 may be omitted.

The buried portion 315 of the buried plate 310 is supported through the upper plate portion 200, embedded in the middle plate portion 205, and the touch portion 105 protruding to the outside through the lower plate portion 210 is a lower plate portion. It is caught in 210 and serves to hold the lower plate part 210 so as not to be separated from the outside. Accordingly, the touch part 105 is fixed to a designated position of the flat plate part 115 without using an adhesive (eg, a conductive adhesive).

The thickness of the buried plate 310 is formed to have the same thickness as the plate thickness of the middle plate portion 205, or a thickness slightly larger than the plate thickness of the middle plate portion 205 (for example, the material of the buried plate 310 is It is preferable that the buried plate 310 is formed to have a thickness that can be compressed and bonded to the middle plate portion 205 between the upper plate portion 200 and the lower plate portion 210 due to the soft or semi-soft or semi-rigid properties.

The area of the buried plate 310 is formed in an area larger than the contact area of the touch body 320 based on a plan view, or there is an embedded portion 315 protruding out of the contact area based on the plan view. It is preferably formed. In this case, the touch portion 105 is placed in a flat plate portion with the touch portion 105 facing downward without bonding the contact portion between the buried plate 310 and the upper plate portion 200 with an adhesive (for example, a conductive adhesive). 115) can be kept fixed. If the buried plate 310 is adhered to the upper plate 200 through an adhesive, the area of the buried plate 310 may be formed to be equal to or smaller than the contact area of the touch body 320.

The touch body part 320 is a generic term for a body that forms a contact surface 300 protruding outward through the lower plate part 210 of the touch part 105, and is a designated geometric shape (for example, a polygon Or, it is manufactured in the form of a pillar exposing the contact surface 300 of (circular, etc.) to the outside. For example, if the contact surface 300 is circular, the touch body 320 may be manufactured in a cylindrical shape, and if the contact surface 300 is rectangular, the touch body 320 may be manufactured in a rectangular parallelepiped shape. .

The height of the touch body 320 is manufactured to a height greater than the thickness of the lower plate part 210, whereby the contact surface 300 having a designated contact area provided on one side of the touch body 320 It is exposed to the outside of the lower plate portion 210 through the protruding groove 605 of the lower plate portion 210. The contact area of the contact surface 300 provided on one side of the touch body 320 is manufactured to have a contact area corresponding to at least one of the first to fourth contact area implementation methods described in FIG. 1, and the The touch body 320 is manufactured in the form of a pillar including a sagittal contact area and a height.

The contact surface 300 of the touch body 320 is a generic term for a configuration that is touched on a capacitive touch screen among the parts of the touch body 105, and is basically a plane of a designated geometric shape (eg, polygonal or circular). A protrusion 305 made of a structure and protruding in a direction in which the central portion of the contact surface 300 is touched on the capacitive touch screen in a state in which the planar structure is maintained (ie, a boundary of a geometric shape is maintained) It is produced including.

The protrusion 305 of the contact surface 300 always causes the central portion of the contact surface 300 to first touch the capacitive touch screen to prevent movement of the center of the touched surface on the capacitive touch screen, or at least allow It is processed to move within the error range. Even if the protrusion 305 is deformed by an external force, it is preferable that the protrusion 305 protrudes to a height that does not deform the contact area of the contact surface 300. For example, the protrusion 305 may protrude between 0.1 mm and 1 mm based on the boundary between the contact surface 300 and the touch body 320.

The touch body 320 and the buried plate 310 are manufactured by forming an empty space 330 that induces deformation by an external force to internal contraction. When an external force is applied while the contact surface 300 of the touch unit 105 (for example, the protrusion 305 of the contact surface 300) touches the capacitive touch screen, the empty space 330 is Induces the deformation due to the internal contraction corresponding to the empty space 330, whereby the contact area of the touched surface on the capacitive touch screen is maintained, and the midpoint of the touched surface does not move.

Referring to Figures 3b and 3c according to the implementation method of the present invention, between the touch body 320 and the embedded plate 310, the contact surface 300 is applied while touching the capacitive touch screen. A contraction groove 325 for inducing deformation by an external force to contraction in the vertical direction of the capacitive touch screen is provided. Preferably, the contraction groove 325 is preferably manufactured to include at least one, but a plurality of contraction grooves 325 are formed in proportion to the height at which the touch part 105 is exposed to the outside of the flat part 115. It can be made to contain.

When a contraction groove 325 is provided between the touch body 320 and the buried plate 310, the empty space 330 formed inside the touch body 320 and the buried plate 310 is In order to compensate for the thickness of the pillar of the touch body 320 that is thinned by the contraction groove 325, a portion protruding into the empty space 330 may be formed to exist.

According to the implementation method of the present invention, the touch part 105 is integrally composed of the touch body part 320 and the buried plate 310, and may be manufactured by injection molding or extrusion molding a material that induces electrostatic change. .

3C is a diagram illustrating a side view and a side cutaway view of an embodiment of the touch unit 105 manufactured at different heights. Referring to the example of Figure 3c, even if the height of the touch portion 105 is manufactured at different heights, the height of the protrusion 305 and the height of the buried plate 310 are constant, and the height of the touch body 320 is different. It is desirable to be. When the touch part 105 is manufactured at different heights, it is preferable to provide at least one contraction groove 325 between the touch body part 320 of the touch part 105 and the buried plate 310.

Figure 4 is a diagram showing the structure of the upper plate 200 according to an embodiment of the present invention.

In more detail, FIG. 4 shows an embodiment of the structure of the upper plate part 200 among the flat part 115 of the frame part 110, and in detail, FIG. 4A shows a plan view of the upper plate part 200, and FIG. 4B Is a side view of the top plate 200, Figure 4c shows a bottom view of the top plate 200. For those of ordinary skill in the art to which the present invention belongs, various implementation methods for the structure of the upper plate 200 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 according to the embodiment of the present invention, the upper plate part 200 includes a support plate 400 supporting a plurality of touch parts 105, and a flat plate through groove 800 of the housing part 215. A coupling part 405 which penetrates through and is coupled to the adapter part 230 is provided, and when the upper plate part 200 and the adapter part 230 are screwed together, a screw groove 410 for assembling the screw is provided.

The support plate 400 of the upper plate part 200 supports a plurality of touch parts 105 among the portions of the upper plate part 200 and is a component part that is coupled to the middle plate part 205. One side of the upper plate part 200 includes a coupling part 405 that passes through the flat plate through groove 800 of the housing part 215 and is coupled to the adapter part 230, and the coupling part 405 is a housing After passing through the flat plate through groove 800 of the part 215 and guided into the coupling guide groove 710 of the adapter part 230, the adapter and the upper plate part 200 (= flat plate part 115) are coupled.

When the upper plate part 200 and the adapter part 230 are screwed together, the coupling part 405 has a screw groove 410 for screw assembly, and the screw groove 410 is a bolt of the adapter part 230 The adapter portion 230 and the upper plate portion 200 (= flat plate portion 115) are screwed together through the through hole 705.

Referring to Figure 4a according to the implementation method of the present invention, the upper plate portion 200, the protruding flat guide portion 220 provided in the housing portion 215 is toward the top plate portion 200 (= flat plate portion 115). It is provided with a guide groove 415 for guiding to be guided in a buried form.

In the embodiment of FIG. 4, the guide groove 415 is formed at each corner of the support plate 400 of the upper plate part 200. Meanwhile, according to another embodiment of the present invention, the guide groove 415 may be formed on each side of the support plate 400 of the upper plate part 200, and in this case, the protruding flat plate of the housing part 215 The guide part 220 may be formed at a position inside the body of the housing part 215 embedded in the guide groove 415 formed at each side of the support plate 400 of the upper plate part 200.

Meanwhile, according to another implementation method of the present invention, a buried flat guide part 220 may be formed in an inner edge region or each side region of the body of the housing part 215, in this case, the edge region of the upper plate part 200 Alternatively, a guide guide portion (not shown) protruding to be guided in a form embedded in the embedded flat guide portion 220 may be formed in each side area.

Referring to Figures 4b and 4c according to the implementation method of the present invention, the upper plate portion 200, the middle plate portion 205 and the recessed portion 510 of the lower plate portion 210 is inserted into the upper plate portion 200, the middle plate portion (205) and the lower plate portion 210 is provided with a protrusion portion 420 for guiding to be assembled in an aligned state.

The protrusion portion 420 of the upper plate portion 200 is the upper plate portion 200, the middle plate portion through a process in which the groove portion 510 of the middle plate portion 205 is inserted and the concave portion 510 of the lower plate portion 210 is inserted. Each side and corner of the 205 and the lower plate 210 are accurately aligned and coupled.

5 is a view showing the structure of the middle plate portion 205 according to an exemplary method of the present invention.

In more detail, FIG. 5 shows an embodiment of the structure of the middle plate part 205 among the flat plate parts 115 of the frame part 110. Specifically, FIG. 5A shows the middle plate part 205 in which the buried groove 505 is formed. ) Shows a bottom view, and Figure 5b shows a state in which the touch part 105 is embedded in the recess 505 of the middle plate part 205, and FIG. 5c shows the upper plate part 200 and the middle plate part 205 ) 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 middle plate 205 by referring and/or modifying the drawings shown in the embodiments of the present invention (e.g., 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. For convenience, FIG. 5C illustrates and describes an embodiment of the middle plate portion 205 in which the touch portion 105 having the contraction groove 325 is embedded, as illustrated in FIGS. 3A and 3C. However, the touch portion 105 embedded in the middle plate portion 205 is by no means limited to the examples of FIGS. 3A and 3C, and the touch portion 105 of FIG. 3B may be embedded according to an implementation method.

The middle plate portion 205 includes a plurality of buried grooves 505 into which buried plates 310 of the plurality of touch portions 105 are embedded. According to the implementation method of the present invention, the position and direction of each embedding groove 505 to be provided in the middle plate part 205 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 that determines the position and direction of the buried groove 505 provided in the middle plate part 205 is a plurality of touches protruding to the outside through the lower plate part 210 after being embedded in the middle plate part 205 This is a geometrical positional relationship formed by a plurality of touch points when the contact surface 300 of the part 105 is touched on the capacitive touch screen. In addition, the geometrical positional relationship is distinguished by recognition that a plurality of touch points touched through the same touch unit 100 must be recognized as distinct touch points, and a plurality of touch points touched through different touch units 100 The geometrical positional relationship formed by the touch points must have a discrimination that different touch positional relationships are formed for each touch unit 100.

In the computer program, when the contact surface 300 of the plurality of touch units 105 provided in the touch unit 100 is touched on the capacitive touch screen, the geometrical positional relationship formed by the plurality of touch points is distinguished and recognized. In order to be satisfied, the minimum discrimination recognition distance in the design to be applied to the design of the touch unit 100 is input, or the minimum discrimination recognition distance for each device (or for each capacitive touch screen) experimentally is input and the maximum value is It is possible to determine the minimum discrimination recognition distance on the corresponding design.

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 designating devices (or capacitive touch screens) corresponding to the object to be touched by the touch unit 100, the minimum discrimination recognition distance is two or more multi-touched by two or more designated devices (or capacitive touch screens). Among the recognizable minimum separation distances for distinguishing touch points, a larger separation distance may be set.

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 may be 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 for 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.

According to the implementation method of the present invention, the computer program calculates or designs the geometrical positional relationship for fixing the plurality of touch units 105 to the flat plate 115, the protruding groove 605 of the lower plate 210 ) Is calculated and designed so that the contact surfaces 300 of the plurality of touch units 105 protruding through are separated from each other by more than the minimum discrimination recognition distance, and based on the geometric positional relationship of the calculated and designed contact surfaces 300 The optimum buried groove 505 position and direction for embedding the buried plate 310 of the touch portion 105 shown in FIG. 3 in the buried flat plate 500 of the middle plate portion 205 is calculated and designed.

In the computer program, when the contact surfaces 300 of the plurality of touch units 105 provided in different touch units 100 are touched on the capacitive touch screen, each geometrical positional relationship formed by the plurality of touch points is In order to satisfy the identification, the minimum identification distance in the design to be applied to the design of the touch unit 100 is input, or the minimum identification distance for each device (or for each capacitive touch screen) experimentally is input and the maximum value is The minimum identification distance on the corresponding design can be determined.

The minimum identification distance is when different touch units 100 having a plurality of touch units 105 designed in different geometric positional relationships are touched on the capacitive touch screen, each geometrical positional relationship is different from each other. In order to be identified, a distance between the plurality of touch units 105 provided in different touch units 100 must be separated from each other with respect to the corresponding touch units 105. Preferably, the minimum identification distance is a distance for sensing movement of the center of the touched surface when a designated contact area is touched on the capacitive touch screen.

According to the implementation method of the present invention, the minimum identification distance for a specific device (or capacitive touch screen) can be measured experimentally. Preferably, the minimum identification distance is when the device (or capacitive touch screen) identifies two or more touch points as different touch points when a certain area on the capacitive touch screen of the specified device is touched twice or more and slightly moved. Includes the minimum perceived separation 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 may be a value obtained experimentally as described above. 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 objects to be touched by the touch unit 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 on the buried flat plate 500 of the different flat units 115 of the different touch units 100 are provided spaced apart from the minimum identification distance or more. It is preferable that the geometrical positional relationship between the plurality of touch units 105 provided on the flat panel 115 of each touch unit 100 is identified by different geometrical positional relationships within the calculated number range. Will have.

According to an embodiment of the present invention, the computer program calculates or designs a geometric positional relationship for fixing the plurality of touch units 105 to the flat panel 115 provided in the plurality of touch units 100, Each of the contact surfaces 300 of the plurality of touch units 105 protruding through the protruding grooves 605 of the lower plate portion 210 of each touch unit 100 is corresponding to the contact surface 300 of the touch unit 105 The touch unit shown in Fig. 3 is calculated and designed to be separated from each other by more than the minimum identification distance, and is placed on the embedded flat plate 500 of the middle plate unit 205 based on the geometric positional relationship of the calculated and designed contact surface 300 Calculate and design the optimal buried groove 505 position and direction in which the buried plate 310 of 105 can be embedded.

As a result, according to the implementation method of the present invention, the program of the computer is a touch exposed by the lower plate part 210 based on the minimum discrimination recognition distance and the minimum discrimination distance in the design, and the contact area of each touch part 105 The positions of the parts 105 are calculated to determine the geometrical positional relationship in the design, and based on the determined geometrical positional relationship in the design and the geometrical shape of the buried plate 310 of the touch unit 105 shown in FIG. The direction and position of the buried groove 505 for embedding the buried plate 310 of the touch portion 105 in the middle plate portion 205 is determined.

According to an embodiment of the present invention, the geometrical positional relationship in the design is a geometrical positional relationship (e.g., distance or distance) when the plurality of touch units 105 are touched on the capacitive touch screen in the form of coordinate values on a preset coordinate system. Angle, etc.), and/or when the plurality of touch units 105 are touched on the capacitive touch screen based on the coordinate values on the designated coordinate system. A distance relationship between one reference point and each touch point, and an angular relationship formed by each touch point based on any one reference point on a designated coordinate system may be included. Here, the reference point may be a designated touch point determined by designating any one of the plurality of touch points, or may include an origin on the designated coordinate system (or a reference point designated on the coordinate system). The designated coordinate system is a generic term for a coordinate system that serves as a reference for analyzing the geometrical positional relationship when the plurality of touch units 105 are touched on a capacitive touch screen, preferably in real world metrological units (e.g., μm, mm, Cm) or a coordinate system composed of a designated logical unit, and according to an implementation method, it is possible to include a touch screen coordinate system set on the capacitive touch screen to which the plurality of touch units 105 are to be touched.

According to the implementation method of the present invention, the position and direction of the buried groove 505 provided in the middle plate portion 205 may be classified into three areas. Preferably, the buried groove 505 provided in the middle plate part 205 has a first closed shape in which the buried plate 310 of the touch part 105 is embedded in the buried flat plate 500 The touch body part 320 or the contact surface of the touch part 105, based on the type buried groove 505 and the bottom view of the buried flat plate 500, is in contact with the outer edge of the buried flat plate 500, and the touch A second type buried groove 505 in the form of embedding the buried plate 310 of the portion 105, and the touch body 320 of the touch portion 105 based on the bottom view of the buried flat plate 500 Alternatively, the buried plate 310 of the touch part 105 in contact with a contact surface on one side of the outer side of the buried flat plate 500 or a design division line for dividing the buried flat plate 500 into a plurality of division areas It may include a third type buried groove 505 made in the form of embedding.

Referring to Figure 5a according to the implementation method of the present invention, the middle plate part 205 is a first type in which the embedded plate 310 of the touch part 105 is embedded in the form of a closed figure on the embedded flat plate 500. The buried plate 310 of the touch portion 105 is embedded so that the buried groove 505 and the touch body 320 or the contact surface of the touch portion 105 are in contact with the outer edge portion of the buried flat plate 500. The two-type buried groove 505 and the touch body 320 or the contact surface of the touch portion 105 are in contact with one side of the outer side of the buried flat plate 500, or the buried flat plate 500 is divided into a plurality of divided areas One or more protruding grooves 605 among the third type buried grooves 505 for embedding the buried plate 310 of the touch part 105 may be provided in contact with the dividing line of the design divided into.

The first type buried groove 505 may be implemented in a vertical direction or a horizontal direction, and may be implemented at an angle (for example, a 45 degree direction) based on a specific side of the buried flat plate 500 according to an implementation method. I can.

The second type buried groove 505 is an angled buried portion of the buried plate 310 in order to contact the touch body 320 of the touch portion 105 or the contact surface at the outer edge of the buried flat plate 500 ( It is preferable that 315 be implemented to come into contact with the outer edge of the buried flat plate 500. According to the example of this drawing 5a, the type 2 buried groove 505 is formed in a position spaced apart by the guide groove 415.

According to an embodiment of the present invention, the contact surface 300 of the touch part 105 embedded in the second type buried groove 505 is used to analyze the geometrical positional relationship formed by the plurality of touch parts 105. Can be used as a reference point.

The third type buried groove 505 may be implemented in a portion in which the touch body 320 or the contact surface of the touch portion 105 is in contact with one side of the outer side of the buried flat plate 500, and the buried flat plate 500 In order to contact the touch body 320 of the touch part 105 or the contact surface on one side of the outer side of the angular recess 315 of the embedding plate 310, the angled recessed part 315 of the embedding plate 500 contacts one side of the embedded flat plate 500 It is desirable to be implemented.

According to an embodiment of the present invention, in the case of including the plurality of touch parts 105 of the flat part 115, the area to be provided with the plurality of touch parts 105 is divided by design, and each of the divided Each of the divided regions may include one touch unit 105. In this case, the third type buried groove 505 is in order to contact the touch body portion 320 or the contact surface of the touch portion 105 with a design division line that divides the buried flat plate 500 into a plurality of division areas. It is preferable that the angular recessed portion 315 of the buried plate 310 is implemented to come into contact with the dividing line in the design corresponding to the divided area of the buried flat plate 500.

According to a preferred implementation method of the present invention, a total of five touch portions 105 are provided on the flat portion 115 of the touch unit 100, and the flat portion 115 is divided into four divided areas by design, Each of the four divided areas includes four touch units 105, one for each, and one touch unit 105 at a designated location on at least one of the four divided areas (hereinafter, for convenience, a'designated touch unit (105)'.) may be further provided. Here, the positions of the four touch units 105 provided in each of the four divided areas of the design are each touch unit 100 (or the flat plate 115) to maintain identification corresponding to the minimum identification distance. At least one location is calculated or designed differently for each, and an area (hereinafter referred to as a'designated area' for convenience) further includes one touch unit 105 at a designated location among the four divided areas in the design. A total of two touch units 105 may be provided by further providing one touch unit 105. Generalizing this embodiment of the present invention, the flat portion 115 of the touch unit 100 includes a total of N (N≥3) touch portions 105, and the flat portion 115 has n It is divided into (2≤n<N) divided areas, and each of the n divided areas includes n touch units 105, one for each, and one designated touch at at least one designated area among the n divided areas A total of two touch units 105 are provided with the unit 105. As a result, one touch unit 105 is provided at each of the calculated positions on the (n-1) divided areas among the n divided areas, and the calculated and designated positions on at least one designated area among the n divided areas One touch unit 105 is provided in the. Preferably, the designation touch unit 105 provided at a designated position on the designated area may be designated as a reference point of the geometrical positional relationship.

Referring to Figure 5a according to the embodiment of the present invention, the second type buried groove 505 is a designated touch unit 105 provided at a designated position on a designated area among the n divided areas in a preferred embodiment of the present invention. It is an embedding groove 505 for embedding the embedding plate 310 of the. And in order to have n touch units 105, one for each of the calculated positions on the n divided areas, the first type buried groove 505 and the third type buried groove 505 are provided in the n divided areas. It can be provided.

Referring to Figures 5a to 5c according to the implementation method of the present invention, the middle plate part 205 is inserted into the protrusion part 420 of the upper plate part 200 so that the upper plate part 200 and the middle plate part 205 are lined up. It is provided with a groove portion 510 to be aligned and coupled. The concave portion 510 is formed in a diameter into which the protrusion portion 420 of the upper plate portion 200 can be inserted. The recessed portion 510 of the middle plate portion 205 is arranged in a form inserted into the protrusion portion 420 of the upper plate portion 200 to couple the middle plate portion 205 with the middle plate portion 205.

Referring to Figure 5b according to the implementation method of the present invention, the buried plate 310 of the touch portion 105 is embedded in each buried groove 505 of the middle plate portion 205 in accordance with the direction of each buried groove 505 In addition, the contact surfaces 300 of the touch unit 105 embedded in each buried groove 505 (or the midpoint of the contact surfaces 300 of the touch unit 105) form a geometric positional relationship in design.

5A to 5B according to the embodiment of the present invention, the middle plate part 205 includes a protruding flat guide part 220 provided in the housing part 215 is the middle plate part 205 (= flat plate part (115) It is provided with a guide groove 415 for guiding to be guided to the embedded form. In the embodiments of FIGS. 5A to 5B, the guide groove 415 is formed at each corner of the embedded flat plate 500 of the middle plate part 205. Meanwhile, according to another embodiment of the present invention, the guide groove 415 may be formed on each side of the buried flat plate 500 of the middle plate part 205, and in this case, the protruding type of the housing part 215 The flat guide part 220 may be formed at a position inside the body of the housing part 215 embedded in the guide groove 415 formed at each side of the buried flat plate 500 of the middle plate part 205. Meanwhile, according to another embodiment of the present invention, a buried flat guide part 220 may be formed in an inner edge area or each side area of the body of the housing part 215, in this case, the middle plate part 205 A sliding portion 715 protruding to be guided in a form embedded in the buried flat guide portion 220 may be formed in the corner area or each side area.

Figure 6 is a diagram showing the structure of the lower plate 210 according to an embodiment of the present invention.

In more detail, FIG. 6 shows the structure of the lower plate part 210 for protruding the contact surface 300 of the touch part 105 embedded in the middle plate part 205 shown in FIG. 5 to the outside. Fig. 6a is a bottom view of the lower plate part 210 in which a protruding groove 605 protruding outside the contact surface 300 of the touch part 105 embedded in the middle plate part 205 shown in Fig. 5 is formed. 6B shows a state in which the contact surface 300 of the touch part 105 embedded in the middle plate part 205 shown in FIG. 5 protrudes through the protruding groove 605 of the lower plate part 210. Figure 6c shows a side view of a state in which the upper plate portion 200, the middle plate portion 205, and the lower plate portion 210 are assembled. 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 210 by referring and/or modifying the drawings shown in the embodiments of the present invention (for example, 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 lower plate part 210 is formed of a touch plate 600 including a part of the touch body 320 of the plurality of touch parts 105 and a plurality of protruding grooves 605 through which the contact surface 300 protrudes. According to the implementation method of the present invention, the position of each protruding groove 605 to be provided on the lower plate part 210 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 factor determining the position and direction of the protruding groove 605 provided in the lower plate part 210 is the contact surface 300 of the touch part 105 protruding through the lower plate part 210. It is a geometrical positional relationship formed by a plurality of touch points when the touch screen is touched. In addition, the geometrical positional relationship is distinguished by recognition that a plurality of touch points touched through the same touch unit 100 must be recognized as distinct touch points, and a plurality of touch points touched through different touch units 100 The geometrical positional relationship formed by the touch points must have a discrimination that different touch positional relationships are formed for each touch unit 100.

According to the present invention, the middle plate part 205 and the lower plate part 210 are manufactured as one set based on the geometrical positional relationship formed by the plurality of touch parts 105 provided in the touch unit 100. The geometrical positional relationship formed by the plurality of touch parts 105 protruding through the protruding groove 605 provided in the lower plate part 210, 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. 6A according to the embodiment of the present invention, the lower plate part 210 is a touch part 105 corresponding to the buried plate 310 embedded in the first type buried groove 505 shown in FIG. 5. ), a first type protruding groove 605 protruding a part of the touch body 320 and the contact surface 300, and a buried plate 310 embedded in the second type buried groove 505 shown in FIG. ), a second type protruding groove 605 protruding a part of the touch body 320 of the touch unit 105 and the contact surface 300, and a third type buried groove 505 shown in FIG. One or more of the protruding grooves 605 of the second type protruding grooves 605 protruding the contact surface 300 with some of the touch body part 320 of the touch part 105 corresponding to the buried plate 310 embedded in) ) Can be provided.

6A and 6B according to the embodiment of the present invention, each protruding groove 605 of the lower plate part 210 is a buried plate 310 embedded in each buried groove 505 shown in FIG. 5. A part of the touch body 320 of the touch part 105 corresponding to) and the contact surface 300 protrude, and the contact surface 300 of the protruding touch part 105 forms a designated geometrical positional relationship. .

Referring to Figures 6a to 6c according to the implementation method of the present invention, the lower plate portion 210, the protrusion portion 420 of the upper plate portion 200 is inserted, the upper plate portion 200, the middle plate portion 205 and the lower plate portion It is provided with a concave groove portion 510 to align and combine (210) in a line. The concave portion 510 is formed in a diameter into which the protrusion portion 420 of the upper plate portion 200 can be inserted. The concave portion 510 is formed in a diameter into which the protrusion portion 420 of the upper plate portion 200 can be inserted. The concave portion 510 of the lower plate portion 210 is arranged in a form inserted into the protrusion portion 420 of the upper plate portion 200 to couple the lower plate portion 210 with the middle plate portion 205 and the upper plate portion 200 .

Referring to Figures 6a to 6c according to the implementation method of the present invention, the lower plate portion 210, the protruding flat guide portion 220 provided in the housing portion 215 is the lower plate portion 210 (= flat plate portion (115) It is provided with a guide groove 415 for guiding to be guided to the embedded form.

7 is a diagram showing the structure of the adapter unit 230 according to an embodiment of the present invention.

In more detail, Fig. 7 shows the structure of the adapter unit 230 of the frame unit 110, and specifically, Fig. 7A shows the side appearance of the adapter unit 230, and Fig. 7B shows the adapter unit 230. Fig. 7c shows a plan view of the adapter unit 230, and Fig. 7c shows a bottom view of the adapter unit 230. If one of ordinary skill in the art to which the present invention belongs, various implementation methods for the structure of the adapter unit 230 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.

Referring to Figures 7a and 7c according to the embodiment of the present invention, the outer shape of the adapter unit 230 is made in a bell shape, and includes a handle connecting portion 700 connected to the handle portion 120. The embodiment of Figure 7 shows a configuration in which the handle connection part 700 is connected in a form in which the handle part 120 is inserted, but is limited to the embodiment shown in FIG. 7 in the form of the handle connection part 700 Never becomes. The handle part 120 may be any shape as long as it can be held by a person's hand, preferably in the form of a painted handle, as well as a logo of each company or organization using the touch unit 100 It can be manufactured as, and the handle connection part 700 may also have any structure as long as it is a structure that can be connected to each type of handle part 120.

Referring to Figures 7a, 7b, and 7d according to the implementation method of the present invention, the adapter unit 230 is, when the adapter unit 230 and the flat plate 115 (or the upper plate 200) is screwed It has a bolt through groove 705 through which the bolt for screw assembly passes. The bolt through groove 705 includes a diameter through which the head portion of the bolt for screw assembly can pass without passing through, but the body portion.

Referring to Figures 7b and 7d according to an embodiment of the present invention, the adapter unit 230 guides the coupling portion 405 of the flat plate 115 (or the upper plate 200) to guide the flat plate 115 ) Is provided with a coupling induction groove 710 to induce coupling to the designated position. The coupling guide groove 710 includes a diameter into which the coupling portion 405 of the flat plate portion 115 (or the top plate portion 200) can be inserted.

Referring to Figures 7b and 7d according to the implementation method of the present invention, the adapter unit 230 is a sliding sliding along the guide unit 220 so as to be guided by the guide unit 220 of the housing unit 215 It has a part 715. The sliding part 715 is preferably made of a pair of an inner sliding part 715 and an outer sliding part 715, whereby the adapter part 230 is guided along the guide part 220 of the housing part 215 Is processed so that it is guided stably without shaking.

Meanwhile, in the present method, the adapter unit 230 forms a physically fixed coupling relationship with the flat plate 115, but may be guided in a sliding form with the housing unit 215 through the sliding unit 715. However, it does not have a physically fixed bond. In particular, as shown in Figs. 7c and 7d, since the portion where the adapter unit 230 and the housing unit 215 are in contact with each other is in a circular shape, the adapter unit 230 is a guide unit 220 of the housing unit 215 ), it is not guided only in the vertical direction where the pressing force is applied, but can rotate in the horizontal direction. However, when the adapter part 230 and the flat part 115 are screw-assembled, the screw assembly may be released by rotating the adapter part 230 in the horizontal direction. In order to prevent this, referring to Figure 7d according to the implementation method of the present invention, the adapter unit 230 is caught in the latch groove 810 of the housing unit 215 to prevent the adapter unit 230 from rotating in the horizontal direction. It may be provided with a clasp 720 to prevent. If the shape of the plane or the bottom of the adapter unit 230 is not circular but has an angular polygonal shape, the adapter unit 230 will not rotate in the horizontal direction, and thus the clasp 720 may be omitted.

FIG. 8 is a diagram showing the structure of a housing part 215 according to an exemplary method of the present invention.

In more detail, FIG. 8 shows the structure of the adapter part 230 and the housing part 215 that interfaces with the frame part 110, and in detail, FIG. 8A shows the side appearance of the housing part 215, Figures 8b and 8c show a cut surface of the housing part 215, figure 8d shows a plan view of the housing part 215, and figure 8e shows a bottom view of the housing part 215. For those of ordinary skill in the art to which the present invention belongs, various implementation methods for the structure of the housing unit 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. I want to make it clear.

Referring to Figure 8a according to the embodiment of the present invention, the outer shape of the housing part 215 is made in the shape of a bowl that is overturned, and accommodates the flat part 115 of the frame part 110, and at the same time, the adapter part ( 230).

Referring to Figures 8b to 8e according to an embodiment of the present invention, the housing part 215 includes a body for accommodating the flat plate 115 (or the frame 110), and the flat plate 115 ) Is provided with a through-plate groove 800 through which the coupling portion 405 of the adapter portion is coupled to the adapter portion 230.

8B to 8E according to the embodiment of the present invention, the housing part 215 includes the adapter part 230 and the flat part 115 when a pressing force is applied by the handle part 120. ) To be spaced apart from each other in a designated direction, and one or more guide units 220 for guiding the plurality of touch units 105 provided on the flat plate 115 to sequentially touch the capacitive touch screen.

The housing part 215 includes a through guide part 220 for guiding the coupling part 405 of the flat part 115 penetrating through the flat through groove 800 and a body of the adapter part 230. An adapter guide unit 220 and a flat plate guide unit 220 for guiding the flat plate unit 115 including the touch unit 105 are provided.

The adapter guide part 220 may include an inner guide part 220 for guiding the inside of the adapter part 230 and an outer guide part 220 for guiding the outside of the adapter part 230.

The flat guide unit 220 includes a protruding flat guide unit 220 for guiding the flat plate 115 in a state protruding from the inside of the body of the housing unit 215 toward the flat plate, and the body of the housing unit 215 The inside includes a flat plate guide 220 for guiding the flat plate.

Referring to Figure 8d according to the embodiment of the present invention, the housing part 215 is a latch groove 810 that prevents the adapter part 230 from rotating in the horizontal direction by catching the latch part 720 of the figure 9d. ) Is provided. If the shape of the flat or bottom surface of the adapter unit 230 is not circular but has an angular polygonal shape, the housing unit 215 will not rotate in the horizontal direction, and thus the clasp groove 810 may be omitted.

Referring to Figures 8b, 8c, and 8e according to the implementation method of the present invention, the housing part 215 passes through the flat plate through groove 800 so that the flat plate portion 115 is directed toward the floor. Supports the flat plate 115 against the elastic force of at least one spring unit 225 holding the unit 115 (or the touch unit 105 provided on the flat plate 115) apart from the floor to a certain height It is provided with a flat plate support (805). The flat plate support part 805 is made of a soft, semi-soft, or semi-rigid material, or a soft, semi-soft, or semi-rigid material is attached to prevent noise due to the elastic force of the spring part 225.

Referring to Fig. 8e according to the implementation method of the present invention, the housing unit 215 contacts the bottom surface of the housing unit 215 to the capacitive touch screen to imprint the touch unit 100 on the capacitive touch screen. A non-slip part 815 is provided to prevent the housing part 215 from slipping in one state. Preferably, the anti-slip part 815 is a non-conductive material (for example, a non-conductive material that prevents slipping because the friction coefficient is greater than a specified reference value with respect to the material of the capacitive touch screen (eg, glass material, transparent plastic material, etc.) It is preferable to include a non-conductive rubber material, a non-conductive silicone material). The non-slip part 815 may be attached to the bottom surface of the housing part 215 by an adhesive.

The non-slip part 815 includes a straight non-slip part 815 attached to the side area of the bottom area of the housing part 215, and the area of the protruding flat guide part 220 among the bottom area of the housing part 215 Among the circular non-slip parts 815 attached to, it may include at least one non-slip part 815.

According to an embodiment of the present invention, when the bottom of the housing 215 is in contact with the capacitive touch screen in order to imprint the touch unit 100 on the capacitive touch screen, the non-slip part 815 By preventing the touch unit 100 from slipping on the capacitive touch screen, errors or errors do not occur in the recognition and interpretation of the touch points for the geometric positional relationship of the plurality of touch points by the painting touch of the present invention. This gives reliability when the touch unit 100 of the present invention is used as an authentication means or an identification means.

9 is a view showing an assembly view of assembling the flat plate 115, the adapter unit 230, and the housing unit 215 according to an embodiment of the present invention.

In more detail, Fig. 9a shows an embodiment in which the flat plate 115 and the adapter unit 230 are screwed together and the housing unit 215 and the spring unit 225 are included therebetween, and Fig. 9b is the flat plate unit. 115, the adapter unit 230, the housing unit 215, etc. are shown in the assembled state before the pressing force is applied, and Figure 9c shows the state in which the pressing force is applied in the assembled state. 9C shows the bottom surface of the touch unit 100 in the assembled state. For those of ordinary skill in the art to which the present invention belongs, various implementation methods for the assembly drawing by referring and/or modifying the drawings shown in the embodiments of the present invention (eg, some components are omitted or modified or , Or an integrated implementation method), but the present invention is made including all of the inferred implementation methods, and it is clear that the technical features of the present invention are not limited only by the implementation methods shown below. It is a bar.

Referring to Figure 9a according to the implementation method of the present invention, the coupling portion 405 of the flat plate portion 115 passes through the flat plate through groove 800 of the housing portion 215, and the coupling guide groove of the housing portion 215 ( While being guided to 710, in a state in which the spring part 225 is located between the flat guide part 220 of the housing part 215 and the inner guide part 220 of the adapter guide part 220, the adapter part 230 and the Screw is assembled.

Referring to Figure 9b according to the implementation method of the present invention, when a pressing force is not applied while the flat plate 115, the adapter unit 230, and the housing unit 215 are assembled, the touch unit 100 is In a state facing the floor, the flat portion 115 (or the touch portion 105 provided on the flat portion 115) is maintained in a state in which the spring portion 225 is dropped to a predetermined height from the floor.

Referring to Fig. 9c according to the implementation method of the present invention, when a pressing force is applied in the state of Fig. 9b, the through guide unit 220 provided in the housing unit 215, the adapter guide unit 220 and the flat plate By at least one of the guides 220, the flat plate 115 maintains a parallel relationship with the capacitive touch screen and moves in the direction of the touch screen inside the housing unit 215 to provide the plurality of touches. The unit 105 is sequentially touched on the capacitive touch screen.

Referring to FIG. 9D according to the embodiment of the present invention, the bottom of the touch unit 100 in which the flat plate 115, the adapter unit 230, and the housing unit 215 are assembled is shown in Fig. 9B. It may be any one of the states of 9c.

100: touch unit 105: touch unit
110: frame portion 115: flat plate
200: upper plate 205: middle plate
210: lower plate portion 215: housing portion
220: guide part 225: spring part
230: adapter part 300: contact surface
305: protrusion 310: buried plate
315: recess 320: touch body
325: contraction groove 330: empty space
400: support plate 405: coupling portion
410: screw groove 415: guide groove
420: protrusion 500: purchased flat plate
505: buried groove 510: concave groove
600: touch plate 605: protruding groove
700: handle connection 705: bolt through groove
710: coupling guide groove 715: sliding part
720: clasp 800: flat plate through groove
805: flat plate support 810: clasp groove
815: non-slip part

Claims (22)

In a touch unit to be touched on a capacitive touch screen provided in a device by being held in a hand or carried on an object capable of contact with the human body,
A plurality of touch units that can be restored after contraction and are made of an electrostatic change inducing material; And
The plurality of touch units are placed on the capacitive touch screen according to the pre-designed touch order while the geometric position relationship including the distance relationship and the angular relationship between the midpoints of the plurality of touch units are arranged and fixed in a pre-designed unique design geometric position relationship. A touch unit comprising: a frame unit having a height of at least one of the plurality of touch units to be touched sequentially at a different height in a design corresponding to the touch order.
The method of claim 1, wherein the plurality of touch units,
A touch unit, characterized in that the specified capacitance is stored before being touched on the capacitive touch screen.
delete delete delete delete delete delete delete delete delete The method of claim 1, wherein the touch unit,
A touch unit comprising a cylindrical touch body that maintains a circular boundary of a contact surface in contact with the capacitive touch screen.
The method of claim 1, wherein the touch unit,
A touch unit comprising a touch body for maintaining a polygonal boundary of a contact surface in contact with the capacitive touch screen.
delete delete delete delete delete The method of claim 1, wherein the plurality of touch units,
A touch unit, characterized in that 100pF ~ 300pF of capacitance is stored by the human body.

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