KR101095180B1 - Input device - Google Patents

Abstract

The input device of the present invention is stacked on top of the insulating layer, the first copper foil layer formed with a terminal portion connected to the outside and a first electrode portion for sensing an electrical signal, and laminated on the lower portion of the insulating layer at the position of the first electrode portion A second copper foil layer correspondingly formed with a second electrode part to detect an electrical signal, a third copper foil layer formed with a third electrode part corresponding to a position of the second electrode part to detect an electric signal, and the second electrode part A sensor ink material which is printed on a lower part or an upper part of the third electrode part to sense an external input signal according to a pressure, and is electrically connected through the first copper foil layer, the insulator, the second copper foil layer, and the third copper foil layer. The outer wall includes vias plated.

Input device, FPC, FCCL, Copper foil layer, Sensor ink material, Screen printing method, Embedded

Description

Input device

The present invention relates to an input device.

In general, personal digital assistants such as portable telephones and PDAs employ a user interface using a keypad. That is, a conventional portable telephone or the like has a keypad composed of a plurality of switches for inputting numbers and letters, etc., and adopts a method in which a user inputs information such as a telephone number or a letter by pressing the switch. A dome button corresponding to each button is provided under the button, and when the button is pressed, the dome button operates to input information.

Figure 5 shows an example of the input device according to the prior art, the FPC 12 is attached to the bottom of the metal dome switch 11, the PET film 13 is attached below, the PET film 13 of Sensor electrodes 14 and 15 are mounted in a circular space. Sensor electrodes 14 and 15 are formed on the back of the FPC 12 with the contacts of the metal dome switch 11 and a double-sided tape 16 is attached. After attaching the double-sided tape 16, the base film 17 is bonded.

As such, the input device according to the prior art adheres the double-sided tape 16 and the base film 17 to the sensor electrode 15 attached to the back of the FPC 12, so that the thickness of the input device becomes thick and the manufacturing process This was complicated.

In addition, the sensor electrodes 14 and 15 are formed such that the (+) electrode portion and the (-) electrode portion cross each other, and when the use period is long, durability of the electrode portion is broken, such as breaking the electrode portion.

Therefore, it is necessary to study the input device that can simplify the manufacturing process to not only reduce the material cost but also reduce the thickness, and can supply a stable electric signal due to its durability.

The present invention has been made to solve the above-mentioned problems of the prior art, the object of the present invention is to simplify the manufacturing process to reduce the material cost as well as to reduce the thickness of the input device, durable and stable It is to provide an input device capable of supplying an electrical signal.

In order to achieve the above object of the present invention, the input device of the present invention is laminated on top of the insulating layer and the first copper foil layer formed with a first electrode portion for sensing the electrical signal and the terminal portion connected to the outside, and A second copper foil layer stacked below and formed to correspond to the position of the first electrode portion to detect an electrical signal, and a third electrode portion to correspond to the position of the second electrode portion to form an electrical signal. A sensor ink material printed on a third copper foil layer, a lower portion of the second electrode portion, or an upper portion of the third electrode portion to sense an external input signal according to a pressure, the first copper foil layer, the insulator, and the second copper foil layer; And vias plated with outer walls electrically passing through the third copper foil layer.

In addition, the sensor ink material is characterized in that printed by a screen printing method or an inkjet printer.

In addition, the sensor ink material has a scroll (Point Scroll) function and a pointer (Pointer) function that can be operated according to the pressure, it characterized in that the operating speed is changed according to the strength of the pressure.

In addition, the sensor ink material is characterized in that the switching function of the English and Korean according to the pressure and the function of adjusting the font size.

In addition, the insulating layer is characterized in that made of polyimide or epoxy.
In addition, the outer wall of the via is characterized in that the plated with a metallic material.

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In addition, the second copper foil layer and the third copper foil layer is characterized by being bonded with a conductive adhesive or bonding sheet.

The input device of the present invention is integrated by printing the pressure sensor material on the lower portion of the second copper foil layer or on the upper portion of the third copper foil layer. As such, the input device having an embedded FPC reduces the overall thickness of the FPC, reduces manufacturing steps, and reduces damage and abrasion of the electrode, thereby increasing the durability of the FPC.

Therefore, mechanical reliability is increased as compared with the related art, and the resistance characteristic of the pressure sensor can be stabilized.

Hereinafter, an input device 100 according to preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

The input device 100 of the present invention is mainly used in a touch screen device operated by a user's touch, and is an FPC embedded type. FPC (Flexible Printed Circuit Board) has the features of flexibility and light and small size compared to the conventional PCB, so it is easy to form a sophisticated pattern as well as good workability, heat resistance, chemical resistance, dimensional stability.

In addition, it is easy to design in multi-layer and three-dimensional and according to the application, there is no need for a connector, such as light weight, miniaturization, three-dimensional, all three beats required by mobile devices.

Most of these features are polyimide (PI) film and copper foil, which are the materials of FPC, and the most effective combination is the conductive adhesive.

The polyimide film has high thermal stability, such as being able to withstand high temperatures of 400 degrees or more and a low temperature of minus 269 degrees or less, and has excellent mechanical properties such as thin and flexible. In addition, it is widely used in the field requiring stable performance even in a harsh environment due to its strong chemical and abrasion resistance.

The FPC consists of at least one flexible copper clad laminate (FCCL) in which an insulating layer (such as a PI film) and a copper foil are bonded using a conductive adhesive.

As shown in Figure 1 to 4, the input device 100 of the present invention is mainly used in the pressure sensor structure of the touch screen, by placing the sensor ink material between the electrode layer in the multilayer FPC inside the FPC It shows a structure in which the sensor ink material is embedded.

Such an FPC embedded type input device refers to an input device having an FPC that includes not only passive elements such as resistors and capacitors but also active elements such as integrated circuits (ICs), which reduces cost and manufacturing steps by eliminating surface mounting. In addition to reducing the area occupied by the device and minimizing signal interference, the board can be used more effectively and contributes to the miniaturization of electronic products.

Input device 100 according to the present invention is composed of a double-sided FCCL and a single-sided FCCL, the double-sided FCCL is a first copper foil layer 110 (copper foil layer) 110 is laminated on the upper side with the insulating layer 111 therebetween, The second copper foil layer 120 is laminated thereon. A third copper foil layer 140 having a cross section FCCL is stacked below the second copper foil layer 120.

Insulating layer 111 is to be easily released to the outside heat dissipated by a capacitor or a resistor, preferably a material having excellent heat resistance and wear resistance, such as polyimide and epoxy.

The first copper foil layer 110 is mounted on the insulating layer 111 and the first electrode part 114 is positioned at a position corresponding to an input part (not shown) of the PI cover 113 that receives a user input signal. ) Is formed, and a terminal unit 115 connected to an external power source is formed to detect an electrical signal.

The first electrode 114 has a dome shape and converts an external input signal into an electrode signal, and a rear side includes a positive electrode and a negative electrode.

The first copper foil layer 110 includes at least one via plated with copper outer walls 112 to electrically connect the insulator 111, the second copper foil layer 120, and the third copper foil layer 140. do. The vias 112 are preferably formed at four corners one by one.

The upper surface of the first copper foil layer 110 is mainly equipped with a cover 113 to surround the FPC 100 as a whole to protect the circuit pattern. The cover 113 is mainly used a polyimide (PI) cover.

The second copper foil layer 120 is mounted under the insulating layer 111, and the second electrode part 122 is formed at a position corresponding to the first electrode part 114 of the first copper foil layer 110, thereby providing an electrical signal. Detect it.

As shown in FIG. 2, the sensor ink material 130 is printed on the lower portion of the second copper foil layer 120 to correspond to the second electrode portion 122.

The sensor ink material 130 is a pressure sensor material mainly used in an input device, and is applied to an electronic product for a touch screen such as a mobile phone or a navigation device and is a material that recognizes an electric signal according to the size of an external pressure of a user.

That is, the sensor ink material 130 may include a pressure sensor and a tactile sensor, and enable a scroll function and a pointer function that can be operated according to the user's touch pressure, and the operating speed varies depending on the pressure strength. . For example, if the user presses hard on the touch screen of the mobile phone, the list goes down quickly, and if the user presses weakly, the list goes down slowly.

In addition, the sensor ink material 130 may perform a function of switching between English and Korean according to pressure and a case of English alphabets according to pressure and the alphabet of Korean alphabet. In addition, by specifying the characters entered after the character input, you can adjust the size or thickness of the character according to the pressure.

The pressure sensor of the sensor ink material 130 can be converted from the text input mode to the tactile sheet mode at the time of writing, thereby enabling the input of various fonts.

The method of printing the sensor ink material 130 may include a screen printing method using a metal mask (not shown) or a printing method using an inkjet printer.

The third copper foil layer 140 is mounted below the second copper foil layer 120 on which the sensor ink material 130 is printed. In the third copper foil layer 140, a third electrode part 142 is formed to correspond to the second electrode part 122 of the second copper foil layer 120 to detect an electrical signal.

The second copper foil layer 120 and the third copper foil layer 140 are bonded with a conductive adhesive or bonding sheet.

As another embodiment, as shown in FIG. 3, the sensor ink material 130 may be printed on the third electrode layer 142 of the third copper foil layer 140.

The sensor ink material 130 is printed on the lower portion of the second copper foil layer 120 or on the upper portion of the third copper foil layer 140, whereby the sensor ink material 130 and the second copper foil layer 120 or the third copper foil layer ( 140 is integrated. As a result, the conventional manufacturing step of mounting the double-sided tape and the base film is reduced, and the overall thickness of the FPC 100 is reduced by the thickness of the removed double-sided tape and the base film.

In addition, the mechanical reliability is improved and the resistance characteristics of the pressure sensor can be stabilized as compared with the conventional sensor pad patch type.

4 is a side view in which the first copper foil layer 110, the insulator 111, the second copper foil layer 120, and the third copper foil layer 140 according to the present invention are electrically connected through the vias 112. The figure shown.

As such, the input device 100 according to the present invention is a pressure sensor material 130 is printed on the lower portion of the second copper foil layer 120 or the upper portion of the third copper foil layer 140 and the conventional double-sided tape or base film The same component is unnecessary.

Therefore, the overall thickness of the input device 100 is reduced and manufacturing steps are reduced, as well as the damage and wear of the electrode is reduced, thereby increasing durability.

Although the input device 100 of the present invention has been described above with reference to a preferred embodiment of the present invention, it will be apparent to those skilled in the art that modifications, changes, and various modifications can be made without departing from the spirit of the present invention.

1 is an exploded perspective view of an input device according to the present invention;

2 is a cross-sectional view of a second copper foil layer of the input device according to the present invention;

3 is a cross-sectional view of a third copper foil layer of the input device according to the present invention;

4 is a side view of an input device according to the present invention;

5 is an exploded view of an input device according to the prior art.

<Explanation of symbols for main parts of drawing>

100: input device 110: first copper foil layer

111: insulation layer 112: via

120: second copper foil layer 130: pressure sensor material

140: third copper foil layer

Claims (7)

A first copper foil layer laminated on the insulating layer and having a terminal portion connected to the outside and a first electrode portion detecting an electrical signal; A second copper foil layer laminated under the insulating layer and formed with a second electrode part corresponding to the position of the first electrode part to detect an electrical signal; A third copper foil layer formed with a third electrode part corresponding to the position of the second electrode part to detect an electrical signal; A sensor ink material printed on a lower portion of the second electrode portion or on an upper portion of the third electrode portion to sense an external input signal according to a pressure; And And vias having an outer wall plated therethrough electrically passing through the first copper foil layer, the insulating layer, the second copper foil layer, and the third copper foil layer. The method according to claim 1, And the sensor ink material is printed by a screen printing method or an inkjet printer. The method according to claim 1, The sensor ink material has a scroll function and a pointer function that can be operated according to pressure, and an input device of which the operating speed varies according to the strength of pressure. The method according to claim 1, The sensor ink material is an input device having an embedded FPC, characterized in that the switching function of the English and Korean and the font size control function according to the pressure. The method of claim 1, The insulating layer is an input device, characterized in that made of polyimide or epoxy. The method according to claim 1, The external wall of the via is plated with a metallic material. The method according to claim 1, And the second copper foil layer and the third copper foil layer are bonded by a conductive adhesive or a bonding sheet.

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