KR101040062B1 - Membrane Switch - Google Patents

Abstract

The present invention relates to a membrane switch that can be used to form the electrode by using an electrically conductive material containing polyaniline and a metal material, to enable electrode printing in a low temperature process and to improve the price competitiveness.

The membrane switch according to the present invention is configured by disposing an insulating layer having a porous layer between the lower layer and the upper layer and the lower layer and the upper layer, wherein a first electrode is formed on an upper surface of the lower layer and a second on a lower surface of the upper layer. An electrode is formed, wherein the first electrode and the second electrode are configured to be disposed in a position opposite to each other through a porous layer formed in the insulating layer, the first electrode and the second electrode is a conductive polymer, a metal material and a binder It is composed of an electrically conductive material produced by mixing the solution, the electrically conductive material is characterized in that the conductive polymer and the metal material is formed in a particle form to be electrically connected.

Membrane Switch, Polyaniline, Metal

Description

Membrane Switch

The present invention relates to a membrane switch that can be used to form the electrode by using an electrically conductive material containing polyaniline and a metal material, to enable electrode printing in a low temperature process and to improve the price competitiveness.

Types of switches have been changed from the conventional push type, slide type or rotary type to thin membrane switches such as membrane switches, contact panels and transparent contact panels using plastic films. In particular, recently, membrane switches have been used for various products. It is used.

The membrane switch refers to a switch made of a thin circuit film.

In general, the membrane switch is composed of a lower circuit film and an upper circuit film, and an insulating film for preventing a short is disposed between the lower circuit film and the upper circuit film. In addition, an electrode is formed in the lower circuit film, a contact is formed in the upper circuit film, and an opening is formed in the insulating film corresponding to the position where the contact is formed.

That is, when the user presses the switch, the membrane switch is configured to recognize the input of the switch by contacting the contact formed in the upper circuit film with the electrode of the lower circuit film through the opening of the insulating film.

In this case, the electrodes or contacts formed on the upper circuit film and the lower circuit film are made of an electrically conductive material, and a metal material is generally used as the electrically conductive material.

In addition, in order to form a pattern of an electrode and a contact on an upper circuit layer or a lower circuit layer using an electrically conductive material made of the metal material, a high temperature process of about 160 ° C. or more is involved.

However, in the case of printing a pattern through a high temperature process, an expensive cost is required according to a high temperature process, and an upper circuit film or a lower circuit film, which is usually composed of a polyethylene terephthalate film (PET film), is contracted by heat, so that the correct electrode and Due to the problem that the printing of the contacts becomes difficult, there is a limit in selecting the film.

Accordingly, the present invention has been made in view of the above-described circumstances, and by providing an electrode using an electrically conductive material containing polyaniline and a metal material, it is possible to provide a membrane switch that enables printing of an electrode at a low temperature. Its technical purpose is.

The membrane switch according to the present invention for achieving the above object is configured by arranging an insulating layer having a porous layer between the lower layer and the upper layer and the lower layer and the upper layer, the first electrode is formed on the upper surface of the lower layer and the A second electrode is formed on a lower surface of the upper layer, and the first electrode and the second electrode are configured to be disposed at positions facing each other through the porous layer formed on the insulating layer, and the first electrode and the second electrode are conductive. It is composed of an electrically conductive material produced by mixing a polymer, a metal material and a binder solution, the electrically conductive material is characterized in that the conductive polymer and the metal material is formed to particles to be electrically connected.

In addition, the conductive polymer constituting the electrically conductive material is characterized in that the polyaniline.

In addition, the polyaniline is composed of a mixture of aniline derivatives attached to R and aniline without a substituent attached to each or in a certain molar ratio, the aniline derivatives attached to R is configured to have the following formula,

In the above formula, R is hydrogen or hydrophobic alkyl {-(O) _m -(-CH _2- ) _n -CH ₃ : n = 1 to 24} or hydrophilic oxyalkyl {-(-OCH ₂ CH _2- ) _n -O (CH ₂ ) _m CH ₃ : n = 1 or more integer, m = 0 or more}.

In addition, the metal material constituting the electrically conductive material is characterized in that the silver (Ag) or copper (Cu).

According to the present invention, by forming an electrode using an electrically conductive material produced by mixing a metal material with a polyaniline solution, and printing the electrode at a low temperature, the membrane switch is able to perform the electrode printing more accurately and easily Can be provided.

In addition, according to the present invention, by mixing a metal material with a lower cost polyaniline to produce an electrically conductive material for forming an electrode, it is possible to provide a cost-effective membrane switch by reducing the product cost.

Hereinafter, embodiments according to the present invention will be described. However, the embodiments described below show one preferred embodiment of the present invention, which is not intended to limit the scope of the present invention. The present invention can be carried out in various modifications without departing from the technical spirit of the invention.

1 and 2 are cross-sectional views showing a schematic configuration of a membrane switch according to a first embodiment of the present invention.

As shown in FIGS. 1 and 2, the membrane switch according to the first embodiment of the present invention includes a lower layer 100, an upper layer 200 disposed to face the lower layer 100, and the lower layer. It is disposed between the (100) and the upper layer 200, and comprises a porous insulating layer 300 to prevent the lower layer 100 and the upper layer 200 to be shorted by a predetermined interval. Although not, the circuit portion for sensing switch information corresponding to each contact is coupled to the bottom surface of the lower layer 100.

The lower layer 100 and the upper layer 200 may be formed of a film such as polyethylene terephthalate (PET).

In addition, the insulating layer 300 is composed of a polymer film that is transparent and excellent in heat resistance, chemical resistance, electrical insulation, and elasticity, and is formed by forming a plurality of openings 310 in a polymer film having a thin film form.

A first electrode 110 is formed on an upper surface of the lower layer 100, and a second electrode (on a surface of the lower layer 100 that is opposite to the first electrode 110 of the lower layer 100) is formed. 210 is formed. In this case, the first electrode 110 formed on the lower layer 100 may be an electrode having a predetermined level of voltage, and the second electrode 210 formed on the upper layer 200 may be a contact point.

In addition, when the opening 310 formed in the insulating layer 300 is pressurized from the outside, a suitable position where the electrode 110 formed on the lower layer 100 and the contact 210 formed on the upper layer 200 contact each other. Is placed on.

The electrode 110 formed on the lower layer 100 and the contact 210 formed on the upper layer 200 are made of an electrically conductive material. The conductive material is patterned on the lower layer 100 and the upper layer 200 in a predetermined form and then dried at a predetermined temperature, thereby printing. In this case, as the printing method of the electrode, various printing methods such as screen printing or offset printing may be applied according to characteristics such as viscosity.

That is, as shown in FIG. 3, a pattern is formed on the top surface of the lower layer 100 so that a plurality of switches SW1 to SW5 including a pair of electrodes are disposed, and the switch SW1 is formed on the bottom surface of the upper layer 200. Contacts 210: S1 to S5 are formed at positions corresponding to ˜SW5.

In addition, openings 310 (T1 to T5) are formed at positions corresponding to the switches SW1 to SW5 in the insulating layer 300 disposed between the lower layer 100 and the upper layer 200.

Therefore, the contacts 210 formed on the upper layer 200 (S1 to S5) contact the switches SW1 to SW5 through the openings 310: T1 to T5, and thus, the pair of electrodes 110 constituting the switch. The contact 210 is electrically connected to the ON state.

Meanwhile, the electrically conductive material includes a conductive polymer, a metal material, and a binder material. Here, the binder material performs a function of attaching a conductive material mixed with a conductive polymer and a metal material to a film, and at the same time, increases the coupling property of the conductive polymer and the metal material. The conductive polymer may be polyaniline. In addition, the metal material may be composed of silver (Ag) or copper (Cu).

4 illustrates a cross-sectional structure of an electrically conductive material forming the electrode 110 and the contact 210. As shown in FIG. 4, the electrically conductive material is formed by a large purchaser of silver or copper (A) through a binder solution (C). ) And the small buyer's polyaniline (B) are granulated so as to be electrically connected. Thus, the electrically conductive material will exhibit electrical properties in all volumes.

More specifically, the electrically conductive material is composed of 15 to 25% polyaniline solution, 60 to 65% silver or copper paste, and 15 to 20% weight ratio of binder solution.

At this time, the silver or copper (A) is composed of several μm size, preferably 2-3 μm size.

In addition, the binder solution may be composed of a thermosetting resin or a UV curing resin, the binder solution serves to increase the strength of the electrically conductive material and improve the adhesion.

In addition, the polyaniline (B) is composed of aniline derivatives attached to R and aniline without a substituent attached to each other or in a fixed molar ratio, and the aniline derivatives attached to R have the following Formula 1.

In Formula 1, R is hydrogen or hydrophobic alkyl {-(O) _m -(-CH _2- ) _n -CH ₃ : n = 1 to 24} or hydrophilic oxyalkyl {-(-OCH ₂ CH _2- ) _n- O (CH ₂ ) _m CH ₃ : an integer greater than or equal to n = 1 and an integer greater than or equal to m = 0.

In addition, in Formula 1, at least one or more R of each R is hydrophobic alkyl {-(O) _m -(-CH _2- ) _n -CH ₃ : n = 1 to 24} or hydrophilic oxyalkyl {-( -OCH ₂ CH _2- ) _n -O (CH ₂ ) _m CH ₃ : may be an integer greater than n = 1, m = an integer greater than 0}.

In addition, the polyaniline is prepared in a dispersion solution in order to mix with the silver paste. In other words, in order to make a polyaniline dispersion solution doped with a dopant such as DBSA [Dodecylbenzenesulfuric acid], a dopant such as polyaniline and DBSA is used at a constant molar ratio. The total content thereof was dispersed so as to be 1.0 to 5.0 wt% with respect to solvents such as toluene and xylene. Dopants such as polyaniline and DBSA are uniformly ground and mixed for 30 minutes, and the mixed powder is dispersed at a rate of 3,000 rpm or more using a disperser for 30 minutes or more to produce a polyaniline dispersion solution.

Meanwhile, the present invention may be applied to a membrane switch configured to have contacts 110 and 210 formed on the upper surface of the lower layer 100 and the lower surface of the upper layer 200 as shown in FIGS. 5 and 6, respectively. Can be.

In more detail, the electrode pattern is formed on the upper surface of the lower layer 100, and the first contact point 110: X1 to X5 is formed at the switch position, and the electrode pattern is formed on the lower surface of the upper layer 200. In addition, the second contact 210 (Y1 to Y5) is formed at the switch position.

In addition, openings 310 (T1 to T5) are formed at positions corresponding to the first and second contacts 110 and 210 in the insulating layer 300 disposed between the lower layer 100 and the upper layer 200. . Therefore, the second contacts 210 (Y1 to Y5) formed in the upper layer 200 are electrically connected to the second contacts 110: X1 to X5 formed in the lower layer 100 through the openings 310: T1 to T5. Connected ON state.

That is, in the above embodiment, the polyaniline dispersion solution, the silver paste, and the binder solution, which are conductive polymers, are mixed at a predetermined ratio to form an electrically conductive material, so that electrode printing can be performed in a low temperature process while maintaining a constant conductivity characteristic.

Therefore, according to the present invention, by using the electrically conductive material and the metal material as the main components, it is possible not only to reduce the manufacturing cost but also to set the firing temperature to 160 ° C. or lower, so that more accurate printing of the electrodes and the contacts can be achieved. It becomes possible.

1 to 3 are views for explaining the structure of the membrane switch according to the first embodiment of the present invention.

4 is a view showing the particle shape of the electrode shown in FIGS.

5 and 6 are views for explaining the structure of the membrane switch according to another embodiment of the present invention.

******* Brief description of the main parts of the drawing *******

100: lower film, 110: electrode,

200: top film, 210: contact point,

300: insulating film, 310: opening,

A: silver / copper B: polyaniline,

C: binder solution.

Claims (4)

An insulating layer having a porous layer formed between the lower layer and the upper layer, and the lower layer and the upper layer, A first electrode is formed on an upper surface of the lower layer, and a second electrode is formed on a lower surface of the upper layer, and the first electrode and the second electrode are disposed to face each other through a porous layer formed on the insulating layer. , The first electrode and the second electrode is composed of an electrically conductive material produced by mixing a conductive polymer, a metal material and a binder solution, The electrically conductive material is a membrane switch, characterized in that the conductive polymer and the metal material is formed in the form of particles to be electrically connected. The method of claim 1, Membrane switch, characterized in that the conductive polymer constituting the electrically conductive material is polyaniline. The method of claim 2, The polyaniline is composed of aniline derivatives attached to R and aniline without a substituent attached to each other or in a fixed molar ratio, and the aniline derivatives attached to R are formed to have the following formula,

In the above formula, R is hydrogen or hydrophobic alkyl {-(O) _m -(-CH _2- ) _n -CH ₃ : n = 1 to 24} or hydrophilic oxyalkyl {-(-OCH ₂ CH _2- ) _n -O (CH ₂ ) _m CH ₃ : a membrane switch characterized in that n = an integer of 1 or more, m = an integer of 0 or more}. The method of claim 1, Membrane switch, characterized in that the metal material constituting the electrically conductive material is silver (Ag) or copper (Cu).

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