JPH0552610B2 - - Google Patents

Description

[Detailed Description of the Invention] [Field of Industrial Application] The present invention relates to a conductive computer that is used as a terminal device for various information processing devices such as a pen-input word processor, digitizer (graphic processing input device), or reed switch. Regarding the seat.

[Prior Art] Conventionally, this type of conductive sheet has been made by forming a sheet layer of silicone rubber in which carbon powder is dispersed on the surface of a metal plate such as an iron plate.

Initially, this product can provide a uniform resistance value no matter which part of the conductive sheet is pressed with a pin, etc. However, as it is used, the surface of the metal plate gradually becomes oxidized, causing fluctuations in the resistance value. In addition, the metal plate itself is hard and lacks flexibility, and the rubber sheet layer on the surface breaks during repeated use, causing the pen tip to come into direct contact with the metal plate, resulting in malfunction. There were some shortcomings.

Apart from this, there are also products made by forming a carbon layer on one side of a polyester resin sheet.
The biggest drawback of this is that the resistance value fluctuates greatly as you move toward the periphery.

Generally, a flexible high-resistance sheet layer made of a conductive polymer material with carbon, graphite, etc. When measured by using a wire, the disadvantage is that it is difficult to obtain a phenomenon in which the resistance increases linearly in proportion to the distance due to the high resistance.

In addition, in the case of a conductive sheet formed solely of a flexible low-resistance sheet layer made of a flexible polymeric material in which metal particles are dispersed, when it is applied as a press-input type switch, the flexible Because the polymeric material contains a large amount of metal particles, it lacks elasticity and tends to become brittle when repeatedly struck through a spacer.

Furthermore, when applying the conductive sheet as a pen input type, the pen side is used as one electrode, and one end edge of the conductive sheet is used as the other electrode. In this case, when the conductive sheet is formed of the above-mentioned high-resistance sheet layer alone, there is a drawback that it is difficult to obtain the phenomenon that the resistance value increases linearly in proportion to the distance as described above. It is difficult to

On the other hand, when the conductive sheet is formed of the above-mentioned low-resistance sheet layer alone, the signal can be reliably detected because the resistance increases linearly in proportion to the distance from the base point. On the other hand, repeatedly hitting the surface of the conductive sheet with a pen causes the surface to become brittle, which is undesirable.

[Problem to be solved by the invention] This invention was made to solve the above-mentioned drawbacks, and its purpose is to provide a material that has elasticity, can withstand repeated hitting, and can withstand pen contact. To create this structure, a flexible low-resistance sheet layer made of a flexible polymeric material with metal particles dispersed or attached to it is thermally bonded to the back side of the upper high-resistance sheet layer that is in a conductive relationship with each other. By making the conductive sheet integrally formed, the conductive sheet can be applied as a press input type or as a pen input type, and the resistance value is uniform no matter which part of the conductive sheet is pressed. The resistance value increases linearly in proportion to the distance from the electrode at one edge of the conductive sheet as a base point, prevents oxidation of the conductor portion, eliminates chattering, and is flexible as a whole. To provide generally a conductive sheet which has a structure that eliminates damage to the surface layer due to repeated use, and which can be turned on and off reliably without causing malfunctions when pressed with a pen, etc., without putting strain on the hand. be.

[Means for Solving the Problems] As a means for solving the above problems, the present invention uses a conductive polymer material in which carbon, graphite, etc. are dispersed, or ions, metals, or metal complexes are added. The upper layer forming the flexible high-resistance sheet layer 2 and the lower layer forming the flexible low-resistance sheet layer 3 made of a flexible polymer material in which metal particles are dispersed or attached are thermally bonded. This is a conductive sheet 1 that is integrally formed.

The conductive sheet 1 is composed of a flexible high-resistance sheet layer 2 as an upper layer and a flexible low-resistance sheet layer 3 as a lower layer. Here, the high resistance value refers to a specific resistance in the range of 1 to 10 ² Ωcm, and the low resistance value refers to a specific resistance in the range of 10 ^-6 to ^{10 -3} Ωcm. The conductive polymer material constituting the upper layer is, for example, polyethylene, polypropylene, polyester, polyvinyl chloride, polyacetal, chloroprene rubber, silicone rubber, NBR, SBR, IIR, BR,
It is obtained by adding a conductive dispersant such as carbon or graphite to a polymer material such as polyurethane, acrylic rubber, or EP rubber. The amount of conductive dispersant added is such that the above specific resistance value can be obtained. Furthermore, in order to obtain a conductive polymer material, in addition to the above-mentioned cases, a conductive polymer material to which ions, metals, or metal complexes are added may be used. That is, for example, polyphenylene, sulfite, polyacetylene, polyphenylene, polypyrrole, etc. are used as polymers, and I ₃ ⁻ , SO ₃ ⁻ , I ₃ ⁺ , NH ₄ ⁺ , I ₂ , etc. are added as additives.
AsF ₆ , etc. are added, or metal complexes such as tetracyanoquinodimethane, tetracyanoethylene, etc. are added with iodine, AsF ₆ , tetrathiofulvalene, tetraselenofulvalene, etc. as additives. Good too.

On the other hand, the flexible polymer material with metal particles dispersed or attached thereto that constitutes the lower layer includes, for example, sheet-like materials such as chloroprene rubber containing nickel powder, silicone rubber containing silver powder, and polyester containing silver powder. Metal-plated fiber cloth such as nickel-metal acrylic fiber cloth or nickel foil,
It may be in the form of a sheet in which the back surface of a metal foil such as copper foil or aluminum foil or a metal vapor deposited layer such as an aluminum vapor deposited layer is coated with a flexible polymeric material such as proproprene rubber, silicone rubber, or polyester.

Note that when bonding the two layers, it is necessary to select in advance a material that can be thermally bonded.

Here, the conductive sheet 1 has a structure in which an upper layer forming a flexible high-resistance sheet layer 2 and a lower layer forming a flexible low-resistance sheet layer 3 are integrally formed by thermal bonding. The reason we decided to do this is as follows.

That is, the conductive sheet 1 according to the present invention can be applied as a press input type, and can also be applied as a pen input type. This is because when applied as a pen input type, if both the upper layer and the lower layer are not conductive, the device will not become energized when a pen is applied to it, making it unusable.

Further, even if the surface of the conductive sheet 1 of the present invention is repeatedly struck with a finger or the like or touched with a pen, the struck part or the pen-applied part is protected by the upper high-resistance sheet layer 2 made of an elastic material. This is based on the fact that it has elasticity and can be flexibly changed in an integrated manner, increasing durability without becoming brittle, and that on-off operation can be performed reliably.

Furthermore, when the conductive sheet 1 of the present invention is applied to a press input type, when pressing a predetermined position of the high resistance sheet layer 2, which is the upper layer of the conductive sheet 1, with a finger or the like, the pressed position of the high resistance sheet layer 2 If it comes into direct contact with a fixed contact on the board, the electrical resistance will be large and it will not be possible to reliably turn on and off depending on the position and location of the press.To solve this problem, an integrated two-layer The fixed contact side of the conductive sheet in the structure is the low resistance sheet layer 3, and even if you press any predetermined location of the high resistance sheet layer 2 with your finger, the fixed contact between the low resistance sheet layer 3 and the board will be removed. is on and off.
This is to enable the switch to turn off and eliminate contact failure.

Furthermore, even when used as a pen input type, for example, when one edge of the conductive sheet 1 is used as a positive electrode and the pen side is used as a negative electrode, when the pen is applied to the top surface of the conductive sheet 1, the high resistance value sheet layer 2 and the low resistance value sheet layer 3, a closed circuit is formed, and when the pen is removed from the conductive sheet 1,
The energized state is released. That is, the low-resistance sheet layer 3 uses the electrode at one edge as a reference point, and uses the fact that its resistance changes linearly depending on the distance from the reference point to determine which location on the conductive sheet 1 is pressed with a pen. Detected, a switch circuit based on pen input is reliably formed.

[Function] An upper layer forming a flexible high-resistance sheet layer 2 made of a conductive polymer material, and a flexible low-resistance layer made of a flexible polymer material with metal particles dispersed or attached thereto. When the conductive sheet 1 obtained by thermally adhering the lower layer forming the sheet layer 3 is used, for example, as a pen input device, one edge of the sheet 1 is used as a positive electrode, and the pen ( When the side (not shown) is used as a negative electrode, no matter where the pen is placed on the top surface of the conductive sheet 1, the upper layer and the lower layer are conductive and become energized, and when the pen is removed from the conductive sheet 1, the energization is turned off. It is a state. In this case, since the lower layer has low resistance, the resistance increases linearly in proportion to the distance starting from the electrode at one edge of the conductive sheet 1, and it is possible to reliably detect which position on the surface of the conductive sheet 1 is pressed with the pen. can.

When the conductive sheet 1 is used as a switch, the conductive sheet 1 according to the present invention is attached to the lower electrode 4 with a spacer 5 in between, with the high resistance layer 2 on top and the low resistance layer 3 on the bottom. When placed on the sheet 1 and pressed from the top surface of the sheet 1, the lower low resistance layer 3 contacts the lower electrode 4 and turns on, and when the two separate, it turns off. .

Example 1 Silicone rubber containing silver powder was dispersed at a ratio of 300 parts by weight of silver powder to 100 parts by weight of silicone rubber.
It was hot vulcanized and molded to a thickness of 0.2 mm. Next, a dough of unvulcanized carbon-containing silicone rubber compound prepared by adding and mixing 30 parts by weight of carbon powder to 100 parts by weight of silicone rubber was placed on the silicone rubber plate containing silver powder, and both were heated and vulcanized again. Then, the two were integrally thermally bonded so that the thickness of the upper layer was 0.2 mm. The specific resistance of the upper layer is 5Ωcm
In the lower layer, it was 10 ^-3 Ωcm. Regarding the conductive sheet obtained in this way, using a tester, one bar of the tester was placed on the base point of the conductive sheet, and the other tester's bar was shifted on the conductive sheet by 10 mm to measure up to 120 mm, and the results were approximately proportional to the distance. A linearly uniform resistance value was obtained.

Example 2 Nickel plating with a plating rate of about 15% was applied to a 200 mesh, 15 denier polyester fiber cloth,
Place the nickel-plated fiber cloth on top, place an unvulcanized silicone rubber fabric underneath, and heat and vulcanize both to form a silicone rubber plate with a thickness of 0.2 mm.
And so. Next, an unvulcanized silicone rubber compound fabric containing silver powder was placed on top of the silicone rubber with the cloth adhered to the top surface in the same proportion as in Example 1, and both were heat vulcanized and molded to form the upper layer of silicone rubber. The plate thickness was set to 0.2 mm. The specific resistance of the nickel layer was 10 ^-4 Ωcm. Regarding the conductive sheet obtained in this way, use a tester to place one bar of the tester on the base point of the conductive sheet, and shift the other tester's bar on the conductive sheet by 10 mm.
When measuring up to 120mm, a uniform resistance value was obtained that was linearly proportional to the distance.

[Effects of the Invention] As can be seen from the above description, the present invention has the following unique effects.

The present invention has elasticity, can withstand repeated hitting,
In addition, in order to have a structure that can withstand pen contact, a flexible low-molecular material made of a flexible polymer material with metal particles dispersed or attached is placed on the back side of the upper high-resistance sheet layer that is in a conductive relationship with each other. This is a conductive sheet in which a resistance value sheet layer is integrally formed by thermal adhesion.

The conductive sheet according to the present invention can be applied as a press input type or as a pen input type. When applied as a pen input type, unless both the upper layer and the lower layer have conductivity, the device will not become energized when a pen is applied to it, making it unusable.

The conductive sheet of the present invention can be used for both press input type and pen input type, so there is no need to prepare conductive sheets for each purpose.
It is versatile and low cost. Furthermore, even if you repeatedly strike the surface of the conductive sheet with your finger or touch it with a pen, the struck part or the pen touch part is protected by the upper high-resistance sheet layer made of an elastic material, which increases its elasticity. It flexibly changes as a unit in the equipped state, increasing durability without becoming brittle, and ensures reliable on/off operation.

Furthermore, when the conductive sheet of the present invention is applied to a press-input type, when a predetermined location of the high resistance sheet layer, which is the upper layer of the conductive sheet, is pressed with a finger, the pressed location of the high resistance sheet layer is directly applied to the substrate. If it comes into contact with a fixed contact, the electrical resistance is large and the on/off operation cannot be achieved reliably depending on the position and location of the press.To solve this problem, an integrated two-layer conductive sheet is used. The fixed contact side of the board is a low-resistance sheet layer, and even if you press any predetermined position of the high-resistance sheet layer with your finger, the low-resistance sheet layer and the fixed contact of the board will be turned on and off reliably. Since it will operate, contact failure will be eliminated.

Furthermore, even when used as a pen input type, for example, one edge of the conductive sheet can be used as a positive electrode.
When the pen side is used as a negative electrode, when the pen is applied to the top surface of the conductive sheet, the high resistance value sheet layer and the low resistance value sheet layer become energized and a closed circuit is formed.
Furthermore, when the pen is removed from the conductive sheet, the energized state is canceled.

In other words, the low-resistance sheet layer uses the electrode at one edge as a reference point, and the resistance value changes linearly according to the distance from the reference point, which is used to detect which point on the conductive sheet is pressed with the pen. Thus, a switch circuit based on pen input can be reliably formed.

Moreover, since the conductive sheet according to the present invention is made of a flexible material, the upper layer and the lower layer are elastically deformed as a unit even when the surface of the sheet is pressed with a pen or the like. ,
Not only does the pressing operation not put a strain on the hands, it also prevents damage to the sheet surface layer, eliminates chattering, and provides excellent effects in that reliable on/off operation can be achieved.

[Brief explanation of the drawing]

FIG. 1 is an enlarged sectional view showing an embodiment of the present invention;
FIG. 2 is a cross-sectional view showing the state in which it is used. 1... Conductive sheet, 2... High resistance value sheet layer,
3...Low resistance sheet layer.

Claims (1)

[Claims] 1 Disperse carbon, graphite, etc.
Alternatively, an upper layer formed of a flexible high-resistance sheet layer made of a conductive polymer material doped with ions, metals, or metal complexes, and a flexible polymer material made of a flexible polymer material with metal particles dispersed or attached to it. 1. A conductive sheet characterized by being integrally formed with a lower layer forming a low-resistance sheet layer by thermal adhesion.