KR102570402B1 - Curved touch switch and method for manufacturing the same - Google Patents

Abstract

The present invention is to provide a curved touch switch capable of securing good touch sensitivity and a manufacturing method thereof. A curved touch switch according to the present invention includes a substrate on which electrical elements are mounted, a curved skeleton panel having a curved portion and laminated on one surface of the substrate, and a skeleton panel formed on one surface of the curved portion of the skeleton panel and electrically connected to the substrate. A touch-sensing electrode part having a plurality of touch-driving electrodes (Tx), a touch-sensing electrode part having a plurality of touch-sensing electrodes (Rx) formed on the other surface of the curved surface of the skeleton panel and electrically connected to the substrate, and a skeleton panel It includes a protective panel that covers and protects the exterior.

Description

Curved touch switch and its manufacturing method {CURVED TOUCH SWITCH AND METHOD FOR MANUFACTURING THE SAME}

The present invention relates to a touch switch, and more particularly, to a curved touch switch having a curved touch surface and a manufacturing method thereof.

Switches are widely used as parts for selection and operation in a wide variety of devices such as vehicles, machine tools, home appliances, terminals, multimedia devices, and game machines.

A wide variety of switches are developed and used depending on the type of device to be applied, and continuous research and development is being conducted to enable various functional selection of the device.

For example, a push switch capable of a simple push operation, a rotary switch capable of an axial rotation operation, a lever-type switch, and the like are used in vehicles. In the case of a push-type push switch, when a user presses a button of the switch, a feeling of operation is provided to the user through movement of a physical structure such as a rubber dome or a tact switch.

Recently, there is a trend in which a physical type switch is changed to a touch type switch. The touch-type switch can have a compact structure and reduce the number of mechanical components. Therefore, there is an advantage in that the installation space of the switch can be reduced and the exterior design of the switch can be diversified.

Recently, interest in a touch switch having a curved touch surface is increasing. However, it is not easy to implement a curved touch switch using a generally used capacitive touch switch technology. In general, a capacitive touch switch is configured by attaching a film or PCB having a touch pattern formed thereon to a touch cover with an adhesive. However, this method can be applied to a product composed of a flat or simple curved surface, but it is insufficient to implement a function by applying it to a 3D shape curved product.

That is, in the case of PCB, it is impossible to attach to a curved surface. In the case of a touch film, even if it is uniformly attached to a 3D shape, there is a structural problem in that the film is overlapped or wrinkled unless the film is uniformly stretched and attached due to the nature of the 3D shape. Even if the touch film is stretched and attached uniformly, disconnection occurs as the touch film is stretched due to the nature of the conductive electrode pattern, or the electrode pattern is not uniformly arranged, resulting in irregular errors in touch coordinates recognized by the electrode pattern.

Publication No. 2012-0044620 (2012. 05. 08)

The present invention has been made in view of the above points, and an object of the present invention is to provide a curved touch switch capable of securing good touch sensitivity through a new structure and a manufacturing method thereof.

A curved touch switch according to the present invention for solving the above object is a substrate on which an electrical element is mounted; Skeleton panel having a curved surface and having a curved portion, and laminated on one surface of the substrate; a touch driving electrode part formed on one surface of the curved part of the skeleton panel and having a plurality of touch driving electrodes (Tx) electrically connected to the substrate; a touch sensing electrode unit formed on the other surface of the curved portion of the skeleton panel and having a plurality of touch sensing electrodes Rx electrically connected to the substrate; and a protective panel covering and protecting the outer surface of the skeleton panel.

The curved portion of the skeleton panel is formed in a spherical shape, the plurality of touch driving electrodes are spaced apart at regular intervals to form a spherical driving electrode pattern surface, and the plurality of touch sensing electrodes are spaced apart at regular intervals to form a spherical driving electrode pattern surface. It is possible to form a sensing electrode pattern surface of.

The touch driving electrodes are formed in a bar shape, and the touch sensing electrodes are arranged in parallel with each other and connect a plurality of straight touch sensing electrodes crossing the touch driving electrodes and ends of the plurality of touch sensing electrodes straight lines. A touch sensing electrode connection unit may be included.

It is preferable that the distance between the plurality of touch driving electrodes is 0.3 to 0.6 mm, and the distance between the plurality of touch sensing electrodes is 0.3 to 0.6 mm.

The curved touch switch according to the present invention includes a drive electrode coupler body disposed on one surface of the substrate and electrically connected to the substrate, and a drive electrode coupler protruding from the drive electrode coupler body to be electrically connected to the touch drive electrode. It may include; a plurality of touch drive electrode couplers having connection protrusions.

The driving electrode coupler body may have a C-clip shape.

A drive electrode pad having a drive electrode pad hole may be connected to the touch drive electrode, and the touch drive electrode coupler may be electrically connected to the touch drive electrode in such a manner that the drive electrode coupler connection protrusion is inserted into the drive electrode pad hole. there is.

The curved touch switch according to the present invention includes a sensing electrode coupler body disposed on one surface of the substrate and electrically connected to the substrate, and a sensing electrode coupler protruding from the sensing electrode coupler body to be electrically connected to the touch sensing electrode. It may include; a plurality of touch sensing electrode couplers having connection protrusions.

The touch sensing electrode coupler body may be formed in a C-clip shape.

A sensing electrode pad having a sensing electrode pad hole may be connected to the touch sensing electrode, and the touch sensing electrode coupler may be electrically connected to the touch sensing electrode in such a manner that the sensing electrode coupler connection protrusion is inserted into the sensing electrode pad hole. there is.

The skeleton panel includes a skeleton panel trim portion surrounding an edge of the skeleton panel curved portion, a plurality of via holes are provided in the skeleton panel trim portion, and the touch driving electrode portion is formed on one surface of the skeleton panel facing the substrate. The touch sensing electrode unit is disposed on the other surface of the skeleton panel such that the touch sensing electrode is placed on the curved surface portion of the skeleton panel and the sensing electrode pad is placed on the trim portion of the skeleton panel, and the sensing electrode coupler connection protrusion is disposed. It may pass through the via hole and be inserted into the sensing electrode pad hole.

The curved touch switch according to the present invention may include a ground electrode formed in a ring shape on the skeleton panel to surround the periphery of the plurality of touch sensing electrodes.

The plurality of touch driving electrodes Tx and the plurality of touch sensing electrodes Rx may be formed on the skeleton panel by a laser direct structuring (LDS) method.

On the other hand, a method of manufacturing a curved touch switch according to the present invention for solving the above object is, (a) preparing a skeleton panel having a curved skeleton panel; (b) forming a touch driving electrode part having a plurality of touch driving electrodes (Tx) and a touch sensing electrode part having a plurality of touch sensing electrodes (Rx) on one side and the other side of the curved part of the skeleton panel, respectively; (c) electrically connecting the touch driving electrode unit and the touch sensing electrode unit to a substrate on which an electric element is mounted; and (d) covering the outer surface of the skeleton panel with a protective panel.

In the step (b), the plurality of touch driving electrodes (Tx) and the plurality of touch sensing electrodes (Rx) may be formed on the curved portion of the skeleton panel by a laser direct structuring (LDS) method.

In the step (b), a ground electrode may be formed on the skeleton panel together with the plurality of touch driving electrodes Tx and the plurality of touch sensing electrodes Rx by a laser direct structuring (LDS) method.

In the step (b), a driving electrode pad connected to the touch driving electrode and having a driving electrode pad hole formed on one side is formed on one surface of the curved portion of the skeleton panel, and in the step (c), it is disposed on one surface of the substrate A touch drive electrode coupler having a drive electrode coupler body electrically connected to the substrate and a drive electrode coupler connection protrusion protruding from the drive electrode coupler body is prepared, and the drive electrode coupler connection protrusion is inserted into the drive electrode pad hole. The touch driving electrode unit may be electrically connected to the substrate in an inserting manner.

In the step (b), a sensing electrode pad connected to the touch sensing electrode and having a sensing electrode pad hole on one side is formed on the other surface of the curved portion of the skeleton panel, and in the step (c), it is disposed on one side of the substrate A touch sensing electrode coupler having a sensing electrode coupler body electrically connected to the substrate and a sensing electrode coupler connecting protrusion protruding from the sensing electrode coupler body is prepared, and the sensing electrode coupler connecting protrusion is inserted into the sensing electrode pad hole. The touch sensing electrode unit may be electrically connected to the substrate in an inserting manner.

In the step (a), the skeleton panel includes a skeleton panel trim portion surrounding an edge of the curved skeleton panel and provided with a plurality of via holes, and in the step (b), the touch driving electrode part faces the substrate. Arranged on one side of the skeleton panel, and disposed on the other surface of the skeleton panel so that the plurality of touch-sensing electrodes are placed on the curved portion of the skeleton panel and the plurality of detection electrode pads are placed on the trim portion of the skeleton panel. In step (c), the sensing electrode coupler connecting protrusion may be inserted into the sensing electrode pad hole through the via hole.

In the curved touch switch according to the present invention, touch driving electrodes and touch sensing electrodes are disposed on both sides of the curved skeleton panel of the skeleton panel in a curved form corresponding to the curved skeleton panel and stably adhered to the curved skeleton panel without gaps. do. Therefore, it is possible to ensure good touch sensitivity on the curved touch surface.

In addition, the curved touch switch according to the present invention is advantageous in manufacturing automation by forming a touch driving electrode part and a touch sensing electrode part on a skeleton panel through a laser direct structuring (LDS) method, and various curved touch surfaces with improved design freedom. can be implemented.

In addition, the curved touch switch according to the present invention can be electrically connected to the substrate through the touch driving electrode coupler and the touch sensing electrode coupler disposed on one surface of the substrate, and the touch driving electrode part and the touch sensing electrode part formed on the skeleton panel, The driving electrode unit and the touch sensing electrode unit may be connected to the substrate through a simple mechanical coupling method without soldering as in the prior art. Therefore, the manufacturing process can be simplified and the manufacturing time can be shortened.

1 is an exploded perspective view schematically illustrating a curved touch switch according to an embodiment of the present invention.
2 is a cross-sectional side view illustrating a curved touch switch according to an embodiment of the present invention.
3 is a plan view illustrating a touch driving electrode part of a curved touch switch according to an embodiment of the present invention.
FIG. 4 is an enlarged view of a part of the touch driving electrode part shown in FIG. 3 .
5 is a plan view illustrating a touch sensing electrode part of a curved touch switch according to an embodiment of the present invention.
FIG. 6 is an enlarged view of a part of the touch sensing electrode shown in FIG. 5 .
7 is for explaining a connection structure between a touch drive electrode coupler and a touch drive electrode unit of a curved touch switch according to an embodiment of the present invention.
8 is for explaining a connection structure between a touch sensing electrode coupler and a touch sensing electrode unit of a curved touch switch according to an embodiment of the present invention.
9 is a flowchart illustrating a manufacturing method of a curved touch switch according to an embodiment of the present invention step by step.

Hereinafter, a curved touch switch according to the present invention will be described in detail with reference to the drawings.

1 is an exploded perspective view schematically illustrating a curved touch switch according to an embodiment of the present invention, and FIG. 2 is a side cross-sectional view showing the curved touch switch according to an embodiment of the present invention.

As shown in the drawing, the curved touch switch 100 according to an embodiment of the present invention includes a substrate 110 on which an electrical element 115 is mounted, and a skeleton panel 120 laminated on one surface of the substrate 110. And, the touch driving electrode unit 130 formed on one surface of the skeleton panel 120, the touch sensing electrode unit 140 formed on the other surface of the skeleton panel 120, and the outer surface of the skeleton panel 120 are covered and protected It includes a protective panel 180 to. The curved touch switch 100 has a curved touch surface on the skeleton panel 120 by the touch driving electrode unit 130 and the touch sensing electrode unit 140 .

The substrate 110 is coupled to the skeleton panel 120 to support the skeleton panel 120 . An electrical element 115 is disposed on the substrate 110 . The electric element 115 is electrically connected to the touch driving electrode unit 130 and the touch sensing electrode unit 140 through the substrate 110 to apply an electrical signal to the touch driving electrode unit 130, and to touch the touch sensing electrode unit 115. Touch coordinates may be recognized by receiving an electrical signal from the unit 140 . In addition, various electrical elements performing various functions may be disposed on the substrate 110 .

A skeleton panel 120 is laminated on top of the substrate 110 . The skeleton panel 120 includes a curved skeleton panel curved portion 121 and a skeleton panel trim portion 123 surrounding an edge of the curved skeleton panel portion 121 . The skeleton panel curved portion 121 is formed in a spherical shape gently raised upward, and the skeleton panel trim portion 123 is formed in a circular ring shape surrounding the edge of the skeleton panel curved portion 121 . A plurality of via holes 124 are provided in the skeleton panel trim part 123 . The plurality of via holes 124 are spaced apart from each other along the circumferential direction of the skeleton panel trim part 123 .

Skeletal panel 120 may be deformed into various other shapes in addition to the illustrated structure. For example, although the drawing shows that the frame panel curved portion 121 is formed of a spherical shape, the frame panel curved portion 121 may be formed of various other curved shapes other than the spherical shape. In addition, the skeleton panel trim portion 123 may be changed into various other shapes according to the shape of the skeleton panel curved portion 121 in addition to the circular ring shape.

1 to 4 and 7, the touch drive electrode unit 130 is disposed on the drive electrode pattern surface 131 formed on one surface of the skeleton panel curved portion 121 and the skeleton panel trim unit 123. It includes a plurality of drive electrode pads 134 extending outward from the edge of the drive electrode pattern surface 131 so as to be possible. The touch driving electrode unit 130 may be formed on one surface of the skeleton panel 120 by a laser direct structuring (LDS) method.

As is known, the laser direct structuring (LDS) method is a method of selectively processing a pattern using a laser on an injection-molded synthetic resin product and then imparting electrical characteristics through a plating process. A conductive pattern may be formed on the synthetic resin substrate by changing the rough surface of the synthetic resin in micro units to a state capable of being plated through laser processing.

The driving electrode pattern surface 131 has a plurality of touch driving electrodes Tx and 132 electrically connected to the substrate 110 . The driving electrode pattern surface 131 is formed in a spherical shape corresponding to the curved portion 121 of the skeleton panel and closely adheres to one surface of the curved portion 121 of the skeleton panel. The plurality of touch driving electrodes 132 are formed in a bar shape, and each of the touch driving electrodes 132 has various lengths. The plurality of touch driving electrodes 132 are spaced apart at regular intervals and disposed parallel to each other. The distance Dt between the plurality of touch driving electrodes 132 is preferably 0.3 to 0.6 mm.

In the case of the sensing electrode pattern surface formed of a conventional diamond pattern, the gap between the sensing electrodes should be formed as close as 0.1 to 0.2 mm, but in order to implement a design that is easy to apply to mass production using the laser direct structuring method, the gap between the sensing electrodes must be at least 0.3 mm. A gap of mm or more is required. When the distance between the touch drive electrodes 132 is less than 0.3 mm, the probability of occurrence of defects on the pattern surface increases, and when the distance between the touch drive electrodes 132 exceeds 0.6 mm, there is a problem in that touch sensitivity is lowered.

The driving electrode pad 134 is for electrical connection with the substrate 110 and is connected to the driving electrode pattern surface 131 and disposed on the skeleton panel trim part 123 of the skeleton panel 120 . The driving electrode pad 134 is connected to the end of the touch driving electrode 132 so as to extend outward from the driving electrode pattern surface 131 . A driving electrode pad hole 135 and a driving electrode pad extension 136 are provided in the driving electrode pad 134 . The drive electrode pad hole 135 is formed to correspond to the via hole 124 of the skeleton panel 120 and is connected to the via hole 124 . The driving electrode pad extension 136 is disposed to protrude from the circumference of the driving electrode pad hole 135 toward the skeleton panel 120 . At least a portion of the driving electrode pad extension 136 is inserted into the via hole 124 of the skeleton panel 120 .

The structure of the touch driving electrode unit 130 is not limited to that shown. That is, the shape or arrangement structure of the touch driving electrode 132 or the driving electrode pad 134 constituting the touch driving electrode unit 130 may be variously changed. In addition, the shape of the driving electrode pattern surface 131 composed of the plurality of touch driving electrodes 132 may be variously changed according to the shape of the curved portion 121 of the skeleton panel 120 provided on the skeleton panel 120 .

1, 2, 5, 6 and 8, the touch sensing electrode unit 140 includes the sensing electrode pattern surface 141 formed on the other surface of the skeleton panel curved portion 121, and the skeleton panel trim. It includes a plurality of sensing electrode pads 146 extending outward from the edge of the sensing electrode pattern surface 141 so as to be disposed on the portion 123 . Like the touch driving electrode unit 130, the touch sensing electrode unit 140 may be formed on the other surface of the skeleton panel 120 by a laser direct structuring method.

The sensing electrode pattern surface 141 has a plurality of touch sensing electrodes Rx and 142 electrically connected to the substrate 110 . The sensing electrode pattern surface 141 is formed in a spherical shape corresponding to the curved portion 121 of the skeleton panel and closely adhered to the other surface of the curved portion 121 of the skeleton panel. The plurality of touch sensing electrodes 142 are roughly shaped like bars intersecting the touch driving electrodes 132 . Each of the plurality of touch sensing electrodes 142 has a different length.

The touch sensing electrode 142 includes a plurality of touch sensing electrode straight parts 143 arranged in parallel to cross the touch driving electrode 132 and a plurality of touch sensing electrode straight parts 143 connected to each other. A sensing electrode connection part 144 is included. The touch sensing electrode connection parts 144 are disposed at both ends of the straight touch sensing electrode parts 143 to connect the straight touch sensing electrode parts 143 to each other. In the drawing, it is shown that the touch sensing electrode 142 includes three touch sensing electrode straight parts 143 and a plurality of touch sensing electrode connection parts 144 disposed at the ends of the touch sensing electrode straight parts 143. , The number of touch sensing electrodes 142 or the location of the touch sensing electrode connection part 144 may be variously changed. In addition, the shape of the touch sensing electrode 142 may be variously changed.

The plurality of touch sensing electrodes 142 are spaced apart at regular intervals and disposed parallel to each other. Like the touch driving electrode 132, the distance Dr between the plurality of touch sensing electrodes 142 is preferably 0.3 to 0.6 mm. This is because a gap of at least 0.3 mm or more is required between the sensing electrodes to implement a design that is easy to apply to mass production using the laser direct structuring method. When the distance between the touch sensing electrodes 142 is less than 0.3 mm, the probability of occurrence of a defect on the pattern surface increases, and when the distance between the touch sensing electrodes 142 exceeds 0.6 mm, there is a problem in that touch sensitivity deteriorates.

The sensing electrode pad 146 is for electrical connection with the substrate 110 and is connected to the sensing electrode pattern surface 141 and disposed on the frame panel trim portion 123 of the frame panel 120 . The sensing electrode pad 146 is connected to the end of the touch sensing electrode 142 so as to extend outside the sensing electrode pattern surface 141 . A sensing electrode pad hole 147 and a sensing electrode pad extension 148 are provided in the sensing electrode pad 146 . The sensing electrode pad hole 147 is formed to correspond to the via hole 124 of the skeleton panel 120 and is connected to the via hole 124 . The sensing electrode pad extension 148 is disposed to protrude from the circumference of the sensing electrode pad hole 147 toward the skeleton panel 120 . At least a portion of the sensing electrode pad extension 148 is inserted into the via hole 124 of the skeleton panel 120 .

The structure of the touch sensing electrode unit 140 is not limited to that shown. That is, the shape or arrangement structure of the touch sensing electrode 142 or the sensing electrode pad 146 constituting the touch sensing electrode unit 140 may be variously changed. Also, the shape of the sensing electrode pattern surface 141 composed of the plurality of touch sensing electrodes 142 may be variously changed according to the shape of the curved portion 121 of the skeleton panel 120 provided on the skeleton panel 120 .

A ground electrode 150 is disposed outside the touch sensing electrode unit 140 . The ground electrode 150 has a ring shape surrounding the touch sensing electrode unit 140 . The ground electrode 150 is disposed on the skeleton panel trim portion 123 of the skeleton panel 120 . The ground electrode 150 may protect the touch sensing electrode 142 from disturbance (noise). Like the touch driving electrode unit 130 or the touch sensing electrode unit 140, the ground electrode 150 may be formed on the other surface of the skeleton panel 120 through a laser direct structuring method. The ground electrode 150 may be disposed in a variety of other shapes that may protect the touch sensing electrode 142 from disturbance by being disposed on the skeleton panel 120, in addition to the circular ring shape as shown.

Referring to FIGS. 1 and 7 , the touch drive electrode coupler 160 is disposed on one surface of the substrate 110 to electrically connect the substrate 110 and the touch drive electrode unit 130 . The touch drive electrode coupler 160 includes a drive electrode coupler body 161 disposed on one surface of the substrate 110 and electrically connected to the substrate 110, and a touch drive electrode unit 130 from the drive electrode coupler body 161. and a drive electrode coupler connection protrusion 162 protruding to the side. The drive electrode coupler body 161 is formed in a C-clip shape and is elastically deformable between the substrate 110 and the touch drive electrode unit 130 . The driving electrode coupler connecting protrusion 162 is inserted into the driving electrode pad hole 135 of the driving electrode pad 134 and electrically connected to the driving electrode pad 134 . The drive electrode coupler connection protrusion 162 is inserted into the drive electrode pad extension 136 of the drive electrode pad 134, so that its outer surface can stably make surface contact with the inner surface of the drive electrode pad extension 136. .

In this way, the touch drive electrode coupler 160 is configured such that the drive electrode coupler connecting protrusion 162 provided thereon is inserted into the drive electrode pad hole 135 of the touch drive electrode unit 130. can be easily connected with Also, since the touch drive electrode coupler 160 can be elastically deformed and is elastically disposed between the substrate 110 and the touch drive electrode unit 130, a stable connection state with the touch drive electrode unit 130 can be maintained. By using the touch drive electrode coupler 160, it is possible to interconnect the substrate 110 and the touch drive electrode unit 130 in a simple mechanical coupling method without soldering as in the prior art, thereby simplifying the manufacturing process and shortening the manufacturing time. there is.

The touch sensing electrode coupler 170 is disposed on one surface of the substrate 110 to electrically connect the substrate 110 and the touch sensing electrode unit 140 . The touch sensing electrode coupler 170 includes a sensing electrode coupler body 171 disposed on one surface of the substrate 110 and electrically connected to the substrate 110, and a touch sensing electrode unit 140 from the sensing electrode coupler body 171. It includes a sensing electrode coupler connecting protrusion 172 protruding to the side. The sensing electrode coupler body 171 is formed in a C-clip shape and is elastically deformable between the substrate 110 and the touch sensing electrode unit 140 . The sensing electrode coupler connecting protrusion 172 is inserted into the sensing electrode pad hole 147 of the sensing electrode pad 146 and electrically connected to the sensing electrode pad 146 . That is, the sensing electrode coupler connecting protrusion 172 extends through the driving electrode pad hole 135 of the touch driving electrode unit 130 and the via hole 124 of the skeleton panel 120 to the inside of the sensing electrode pad extension part 148. It is inserted into the sensing electrode pad hole 147. Since the sensing electrode coupler connection protrusion 172 is inserted into the sensing electrode pad extension part 148, the outer surface of the sensing electrode coupler connection protrusion 172 can stably come into surface contact with the inner surface of the drive electrode pad extension part 136. there is.

In this way, the touch-sensing electrode coupler 170 is configured such that the sensing electrode coupler connection protrusion 172 provided thereon is inserted into the sensing electrode pad hole 147 of the touch-sensing electrode unit 140. can be easily connected with In addition, since the touch sensing electrode coupler 170 is elastically deformable and is elastically disposed between the substrate 110 and the skeleton panel 120, a stable connection state with the touch sensing electrode unit 140 can be maintained. By using the touch-sensing electrode coupler 170, the substrate 110 and the touch-sensing electrode unit 140 can be interconnected in a simple mechanical coupling method without soldering as in the prior art, thereby simplifying the manufacturing process and reducing manufacturing time. there is.

Referring back to FIG. 1 , the protective panel 180 covers and protects the outer surface of the skeleton panel 120 . The protection panel 180 insulates the touch sensing electrode unit 140 and the ground electrode 150 on the upper side of the skeleton panel 120 and prevents the touch sensing electrode unit 140 and the ground electrode 150 from being damaged. The protection panel 180 may be made of various insulating and waterproof materials.

As described above, the curved touch switch 100 according to an embodiment of the present invention includes touch driving electrodes 132 and touch sensing electrodes on both sides of the curved skeleton panel 121 of the skeleton panel 120, respectively ( 142) is bent to correspond to the curved surface of the skeleton panel 121 and is stably and closely attached to the curved surface of the skeleton panel 121 without a gap. Therefore, it is possible to secure good touch sensitivity on the touch surface.

In the case of a touchpad using a conventional film, there is difficulty in automating work for attaching the film to the panel, and it is very difficult to uniformly attach the film to the curved panel. In addition, when a curved touchpad is implemented using a PCB, an air gap is likely to occur between the curved panel and the PCB, and such an air gap adversely affects touch sensitivity, resulting in greatly reduced touch recognition performance. In contrast, the present invention can overcome these limitations of the prior art.

In addition, in the curved touch switch 100 according to an embodiment of the present invention, the touch driving electrode unit 130 and the touch sensing electrode unit 140 are formed on the skeleton panel 120 through a laser direct structuring method, thereby improving manufacturing automation. It is advantageous, and design freedom is improved, so that various curved touch surfaces can be implemented.

In addition, in the curved touch switch 100 according to an embodiment of the present invention, the touch driving electrode unit 130 and the touch sensing electrode unit 140 formed on the skeleton panel 120 are disposed on one surface of the substrate 110 It can be electrically connected to the board 110 through the touch driving electrode coupler 160 and the touch sensing electrode coupler 170, so that the touch driving electrode unit 130 and the touch sensing electrode unit 140 can be connected without soldering as in the prior art. It can be connected to the substrate 110 by a simple mechanical coupling method. Therefore, the manufacturing process can be simplified and the manufacturing time can be shortened.

Hereinafter, a method of manufacturing the above-described curved touch switch will be described.

Referring to FIG. 9 , a method of manufacturing a curved touch switch according to an embodiment of the present invention includes preparing a skeleton panel 120 (S10) and forming electrodes on the skeleton panel 120 (S20). and electrically connecting electrodes formed on the skeleton panel 120 to the substrate 110 (S30), and laminating the protective panel 180 on the skeleton panel 120 (S40).

First, in the step of preparing the skeleton panel 120 (S10), a skeleton panel 120 having a curved skeleton panel curved portion 121 and a skeleton panel trim portion 123 having a plurality of via holes 124 formed thereon form The skeleton panel curved portion 121 may be formed in various shapes, such as a spherical shape gently raised upward.

Next, in the step of forming electrodes on the skeleton panel 120 (S20), the touch driving electrode unit 130 is formed on one surface of the skeleton panel 120, and the touch sensing electrode unit is formed on the other surface of the skeleton panel 120 ( 140) and the ground electrode 150 are formed. The touch driving electrode unit 130 , the touch sensing electrode unit 140 , and the ground electrode 150 may be formed in various shapes according to the shape of the skeleton panel 120 . At this time, the touch drive electrode unit 130 has its drive electrode pattern surface 131 disposed on one surface of the skeleton panel curved portion 121 and the drive electrode pad 134 disposed on the skeleton panel trim portion 123. It is formed on one side of (120). The touch sensing electrode unit 140 is configured such that the sensing electrode pattern surface 141 is disposed on the other surface of the skeleton panel curved portion 121 and the sensing electrode pad 146 is disposed on the skeleton panel trim portion 123. ) is formed on the other side of

In this step, the touch driving electrode unit 130, the touch sensing electrode unit 140, and the ground electrode 150 may be formed on the skeleton panel 120 through the laser direct structuring method. By using the laser direct structuring method, the touch driving electrode part 130 and the touch sensing electrode part 140 can be formed in a curved shape to correspond to the curved surface part 121 of the skeleton panel 120, and the touch driving electrode The unit 130 and the touch sensing electrode unit 140 may be stably and closely attached to one surface and the other surface of the skeleton panel 120 without a gap with the skeleton panel 120 .

Next, in the step of electrically connecting the electrodes formed on the skeleton panel 120 to the substrate 110 (S30), the touch driving electrode 132 and the touch sensing electrode 142 formed on the skeleton panel 120 are connected to the substrate 110. ) and electrically connected. In this step, the touch driving electrode 132 is electrically connected to the substrate 110 using the touch driving electrode coupler 160, and the touch sensing electrode 142 is connected to the substrate 110 using the touch sensing electrode coupler 170. ) and can be electrically connected. The touch driving electrode coupler 160 and the touch sensing electrode coupler 170 are disposed on one surface of the substrate 110 . A plurality of touch driving electrode couplers 160 and a plurality of touch sensing electrode couplers 170 are properly disposed on one surface of the substrate 110 so as to be electrically connected to the substrate 110, and the touch driving electrode unit 130 and touch sensing The touch driving electrode unit 130 and the touch sensing electrode unit 140 are formed on the substrate 110 by combining the skeleton panel 120 on which the electrode unit 140 is formed with the substrate 110 to cover one surface of the substrate 110. can be electrically connected.

When the skeleton panel 120 and the substrate 110 are coupled, the drive electrode coupler connecting protrusion 162 of the touch drive electrode coupler 160 is inserted into the drive electrode pad hole 135 of the touch drive electrode unit 130 . Accordingly, the touch driving electrode unit 130 may be electrically connected to the electric element 115 disposed on the substrate 110 through the touch driving electrode coupler 160 . In addition, the sensing electrode coupler connection protrusion 172 of the touch sensing electrode coupler 170 passes through the drive electrode pad hole 135 of the touch drive electrode unit 130 and the via hole 124 of the skeleton panel 120 to sense the touch It is inserted into the sensing electrode pad hole 147 of the electrode unit 140 . Accordingly, the touch sensing electrode unit 140 may be electrically connected to the electric element 115 disposed on the substrate 110 through the touch sensing electrode coupler 170 .

Next, in the step of laminating the protective panel 180 on the skeleton panel 120 (S40), the outer surface of the skeleton panel 120 is covered with the protective panel 180 to protect it. The protection panel 180 is laminated on the skeleton panel 120 to insulate the touch sensing electrode unit 140 and the ground electrode 150 formed on the skeleton panel 120, and the touch sensing electrode unit 140 and the ground electrode 150 ) to prevent damage.

Although the preferred examples of the present invention have been described above, the scope of the present invention is not limited to the forms described and illustrated above.

For example, in the drawing, the touch sensing electrode unit 140 is disposed on one side of the skeleton panel 120 facing the substrate 110, and the touch driving electrode unit 130 is disposed on the other side of the skeleton panel 120. Although shown as being disposed, the positions of the touch driving electrode unit 130 and the touch sensing electrode unit 140 on the skeleton panel 120 may be changed in various ways.

In addition, although the drawing shows that the touch drive electrode unit 130 is electrically connected to the substrate 110 by the touch drive electrode coupler 160 having a C-clip shape disposed on one surface of the substrate 110, the touch drive electrode An electrical connection structure between the unit 130 and the substrate 110 or a connection means electrically connecting the touch driving electrode unit 130 and the substrate 110 may be variously changed. Also, the touch sensing electrode unit 140 may be electrically connected to the substrate 110 by various other methods other than the method using the C-clip-shaped touch sensing electrode coupler 170 as shown.

In the above, the present invention has been shown and described in relation to preferred embodiments for illustrating the principles of the present invention, but the present invention is not limited to the configuration and operation as shown and described. Rather, it will be appreciated by those skilled in the art that many changes and modifications may be made to the present invention without departing from the spirit and scope of the appended claims.

100: curved touch switch 110: substrate
120: skeleton panel 121: skeleton panel curved portion
123: skeleton panel trim part 130: touch drive electrode part
131: driving electrode pattern surface 132: touch driving electrode
134: drive electrode pad 140: touch sensing electrode unit
141: sensing electrode pattern surface 142: touch sensing electrode
146: sensing electrode pad 150: ground electrode
160: touch driving electrode coupler 170: touch sensing electrode coupler
180: protection panel

Claims (19)

a substrate on which electrical elements are mounted; Skeleton panel having a curved surface and having a curved portion, and laminated on one surface of the substrate; a touch driving electrode part formed on one surface of the curved part of the skeleton panel and having a plurality of touch driving electrodes (Tx) electrically connected to the substrate; a touch sensing electrode unit formed on the other surface of the curved portion of the skeleton panel and having a plurality of touch sensing electrodes Rx electrically connected to the substrate; And a protective panel covering and protecting the outer surface of the skeleton panel; includes,
A plurality of touch driving electrodes including a drive electrode coupler body disposed on one surface of the substrate and electrically connected to the substrate, and a drive electrode coupler connecting protrusion protruding from the drive electrode coupler body to be electrically connected to the touch drive electrode. Curved touch switch comprising a; coupler.
According to claim 1,
The skeleton panel curved portion is formed in a spherical shape,
The plurality of touch drive electrodes are spaced apart at regular intervals to form a spherical drive electrode pattern surface,
The plurality of touch sensing electrodes are spaced apart at regular intervals to form a spherical sensing electrode pattern surface.
According to claim 1,
The touch driving electrode is formed in a rod shape,
The touch sensing electrodes include a plurality of touch sensing electrode straight parts disposed in parallel with each other and intersecting the touch driving electrodes, and a touch sensing electrode connecting part connecting ends of the plurality of touch sensing electrode straight parts to each other. Characterized in that Curved touch switch.
According to claim 3,
The distance between the plurality of touch driving electrodes is 0.3 to 0.6 mm,
A curved touch switch, characterized in that the distance between the plurality of touch sensing electrodes is 0.3 ~ 0.6mm.
delete According to claim 1,
The driving electrode coupler body is a curved touch switch, characterized in that made of a C clip shape.
According to claim 1,
A driving electrode pad having a driving electrode pad hole is connected to the touch driving electrode,
The touch drive electrode coupler is a curved touch switch, characterized in that electrically connected to the touch drive electrode in such a way that the drive electrode coupler connection protrusion is inserted into the drive electrode pad hole.
a substrate on which electrical elements are mounted; Skeleton panel having a curved surface and having a curved portion, and laminated on one surface of the substrate; a touch driving electrode part formed on one surface of the curved part of the skeleton panel and having a plurality of touch driving electrodes (Tx) electrically connected to the substrate; a touch sensing electrode unit formed on the other surface of the curved portion of the skeleton panel and having a plurality of touch sensing electrodes Rx electrically connected to the substrate; And a protective panel covering and protecting the outer surface of the skeleton panel; includes,
A plurality of touch sensing electrodes including a sensing electrode coupler body disposed on one surface of the substrate and electrically connected to the substrate, and a sensing electrode coupler connecting protrusion protruding from the sensing electrode coupler body to be electrically connected to the touch sensing electrode. Curved touch switch comprising a; coupler.
According to claim 8,
The touch-sensing electrode coupler body is a curved touch switch, characterized in that made of a C-clip shape.
According to claim 8,
A sensing electrode pad having a sensing electrode pad hole is connected to the touch sensing electrode,
The touch sensing electrode coupler is a curved touch switch, characterized in that electrically connected to the touch sensing electrode in such a way that the sensing electrode coupler connecting protrusion is inserted into the sensing electrode pad hole.
According to claim 10,
The skeleton panel includes a skeleton panel trim portion surrounding an edge of the skeleton panel curved portion, and a plurality of via holes are provided in the skeleton panel trim portion,
The touch driving electrode unit is disposed on one surface of the skeleton panel facing the substrate,
The touch sensing electrode unit is disposed on the other surface of the skeleton panel such that the touch sensing electrode is placed on the curved portion of the skeleton panel and the sensing electrode pad is placed on the trim portion of the skeleton panel,
The curved touch switch, characterized in that the sensing electrode coupler connection protrusion passes through the via hole and is inserted into the sensing electrode pad hole.
According to claim 1,
and a ground electrode formed in a ring shape on the skeleton panel to surround the periphery of the plurality of touch sensing electrodes.
According to claim 1,
The plurality of touch driving electrodes (Tx) and the plurality of touch sensing electrodes (Rx) are formed on the skeleton panel by a laser direct structuring (LDS) method.
(a) preparing a skeletal panel having a curved skeletal panel;
(b) forming a touch driving electrode part having a plurality of touch driving electrodes (Tx) and a touch sensing electrode part having a plurality of touch sensing electrodes (Rx) on one side and the other side of the curved part of the skeleton panel, respectively;
(c) electrically connecting the touch driving electrode unit and the touch sensing electrode unit to a substrate on which an electric element is mounted; and
(d) covering the outer surface of the skeleton panel with a protective panel;
In the step (b), a drive electrode pad connected to the touch drive electrode and having a drive electrode pad hole formed on one side is formed on one surface of the curved portion of the skeleton panel,
In the step (c), a touch drive electrode coupler having a drive electrode coupler body disposed on one surface of the substrate and electrically connected to the substrate and a drive electrode coupler connection protrusion protruding from the drive electrode coupler body is prepared, , The method of manufacturing a curved touch switch, characterized in that for electrically connecting the touch driving electrode part to the substrate by inserting the driving electrode coupler connection protrusion into the driving electrode pad hole.
15. The method of claim 14,
In step (b), the plurality of touch driving electrodes (Tx) and the plurality of touch sensing electrodes (Rx) are formed on the curved portion of the skeleton panel by a laser direct structuring (LDS) method. Manufacturing method of the switch.
According to claim 15,
In the step (b), a ground electrode is formed on the skeleton panel together with the plurality of touch driving electrodes (Tx) and the plurality of touch sensing electrodes (Rx) by a laser direct structuring (LDS) method. Curved surface, characterized in that A method for manufacturing a type touch switch.
delete (a) preparing a skeletal panel having a curved skeletal panel;
(b) forming a touch driving electrode part having a plurality of touch driving electrodes (Tx) and a touch sensing electrode part having a plurality of touch sensing electrodes (Rx) on one side and the other side of the curved part of the skeleton panel, respectively;
(c) electrically connecting the touch driving electrode unit and the touch sensing electrode unit to a substrate on which an electric element is mounted; and
(d) covering the outer surface of the skeleton panel with a protective panel;
In the step (b), forming a sensing electrode pad connected to the touch sensing electrode on the other surface of the curved portion of the skeleton panel and having a sensing electrode pad hole on one side,
In the step (c), a touch sensing electrode coupler having a sensing electrode coupler body disposed on one surface of the substrate and electrically connected to the substrate and a sensing electrode coupler connecting protrusion protruding from the sensing electrode coupler body is prepared, , The method of manufacturing a curved touch switch, characterized in that for electrically connecting the touch sensing electrode part to the substrate by inserting the sensing electrode coupler connection protrusion into the sensing electrode pad hole.
According to claim 18,
In the step (a), the skeleton panel includes a skeleton panel trim portion surrounding an edge of the curved skeleton panel and having a plurality of via holes,
In the step (b), the touch driving electrode unit is disposed on one surface of the skeleton panel facing the substrate, the touch sensing electrode unit is placed on the curved surface portion of the skeleton panel, and the plurality of sensing electrodes are placed on the curved surface portion of the skeleton panel. An electrode pad is disposed on the other surface of the skeleton panel so as to be placed on the skeleton panel trim,
In the step (c), the sensing electrode coupler connection protrusion is passed through the via hole and inserted into the sensing electrode pad hole.

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