KR20110114852A - Touch pen for touch sceen panel - Google Patents

Abstract

The touch pen applicable to the touch screen panel using the change in capacitance may be formed of a pen body made of metal, an insulating coating layer of a thin film formed on the surface of the pen body, and an electrical material to affect the change of capacitance on the touch screen panel. And a touch body mounted at an end of the pen body, wherein the touch body is partially or completely spaced from the end of the pen body, and partially elastically deformed at the portion in contact with the touch screen panel.

Description

Touch pen for touch screen panel {TOUCH PEN FOR TOUCH SCEEN PANEL}

The present invention relates to a touch pen, and more particularly, to a touch pen that can be applied to a capacitive touch screen panel.

In general, the touch screen panel uses a pressure-sensitive method in which upper and lower electrodes are selectively contacted, or an electrostatic method in which a touch pen detects a location using a change in capacitance of a touched part. It is used for precisely touching or inputting characters or pictures on the display panel.

In particular, in the case of a touch fan used in a touch screen panel employing an electrostatic method, the touch screen panel must be contacted to cause a change in capacitance. Therefore, unlike a pressure sensitive touch pen, a physical pressure that pushes the surface of the touch screen is different. Alone is not enough. In addition, since the electrostatic touch screen panel uses tempered glass to protect the surface, it may be difficult to press the surface with a conventional pressure-sensitive teach pen.

In order to be applied to the electrostatic touch screen panel, there is a method of forming a touch body by mixing a conductive material, but, for example, when forming the touch body with rubber mixed with a conductive material such as carbon, a touch pen, etc. It is also pointed out that the drawback may cause residue on the panel.

In addition, it is preferable that the electrostatic touch pen is partially electrically conductive, but it is necessary to refrain from being electrically connected directly to the body, and the touch pen can be made small while providing an electrically sufficient effect. It is also necessary.

The present invention provides a touch pen that can be applied to a capacitive touch screen panel.

The present invention provides a touch pen capable of providing a sufficient capacitance change on a touch screen panel by limiting direct electrical connection with the hand even when manufactured in a small size and interacting with the hand in a wide area.

The present invention provides a touch pen that can affect a change in electrical characteristics on a touch screen panel while providing a constant touch or pressure to a user.

The present invention provides a touch pen free of conductive material such as carbon from the end of the touch pen contacting the touch screen panel.

According to an exemplary embodiment of the present invention, a touch pen applicable to a touch screen panel using a change in capacitance may include a pen body made of metal, an insulating coating layer of a thin film formed on a surface of the pen body, and the touch screen panel. And a touch body that includes an electrical material to affect a change in capacitance in the phase and is mounted to an end of the pen body. The insulating coating layer is formed on the entire surface or the outer surface of the pen body, and the direct electrical contact between the body and the pen body is limited, and the body and the pen body are spaced apart from each other at thin intervals, thereby improving the effect on the capacitance change. . The insulating coating layer may be formed mainly on the part where the finger touches, and may be formed on the front surface, but may be formed on the part around the part held by the finger according to a special design and intention. In particular, the pen body may be formed of aluminum, and anodized on the surface thereof to form an insulating coating layer having a thickness of about 100 μm or less, wherein the aluminum pen body is limited while limiting direct electrical contact between the pen body and the finger of aluminum. By keeping the gap between and the fingers close, it is possible to interact between the finger and the pen body in a large area.

The touch body is provided in a shape that covers the end of the pen body, and is mounted in a state where the touch body is completely or partially spaced from the end of the pen body rather than being in close contact with the pen body. Therefore, the touch body itself may be formed of an elastic material, but when the touch body is pressed on the touch screen panel, it is relatively easily deformed, and the interaction between the touch body and the touch screen panel occurs in a large area through the deformation. You can do that. To this end, the touch body may be formed to include a rounded or pointed end, and the inside may be formed to be hollow so that a space is formed between the pen body and the pen body.

In addition, an inner core may be provided between the pen body and the touch body. The inner core may maintain an interval of about 3.0 mm or less corresponding to the inner surface shape of the touch body, and the deformation of the touch body may be achieved in a limited range by the inner core.

If the touch body is formed in a hollow shape and there is no inner core, the touch body can be deformed in a relatively unrestricted range, but the habit of using a pen for each user, for example, how to hold the pen, tilt of the pen, and pen Because of the different pressure to press the use of only the hollow touch body, it is difficult to determine the appropriate degree of change of different capacitances for different users, even the same user may be different usage habits according to the environment. In addition, even when a curve or a straight line is drawn by the touch pen, the touch body may move on the panel while the pressing pressure or the pressing angle may vary, and thus the degree of deformation of the touch body may vary.

However, when there is an inner core inside the touch body as in the present invention, the touch pen moves only by a predetermined depth (for example, about 2 to 3 mm) on the touch screen panel, and deformation is prevented. Therefore, the touch body may be changed to a certain degree, and may not be excessively deformed to maintain an approximately general pen shape. In addition, since the elastic touch body moves only a certain depth and is blocked by the inner core, the user may provide a click feeling even in a simple pressing operation.

By maintaining the degree that the inner core is supported, the user can maintain the degree to which the touch body is pressed or the pressure to be pressed even when a straight line or a curve is drawn with the touch pen.

The touch body may be formed of a single layer structure composed of a single material or a single mixture, but may be formed of a multilayer structure or a laminated structure composed of a plurality of materials or mixtures. For example, in order to prevent the rubber layer mixed with carbon from being worn, the wear resistant layer may be formed using urethane.

Here, the electrical material is a material that can change the capacitance on the surface of the touch screen panel when the touch body is deformed while being pressed on the panel or when it is in contact with the surface of the panel. ) May be a conductive material such as titanium dioxide (TiO ₂ ), barium titanate (BaTiO ₃ ), lead titanate (PbTiO ₃ ), or a compound containing them, for example, to other non-conductive electrical properties (eg, dielectric constant). It can also be a ceramic material that can change. When the conductive material is used, irregularities may be formed on the surface of the elastic layer or the wear resistant layer, or a change in conductivity may be further enhanced by using a material having a plurality of pores.

Such electrical material may be provided in a mixed state in a rubber layer or a wear resistant layer, and may be provided in all or part of a single layer or a plurality of layers. In some cases, it may be provided in a separate layer structure applied or laminated on the outer surface or the inner surface of the rubber layer or wear-resistant layer.

Since the touch pen of the present invention has an inner core inside the touch body, the touch pen moves only by a predetermined depth (for example, about 2 to 3 mm) on the touch screen panel, and deformation is prevented. Therefore, it is possible to change the touch body only within a limited range, and to maintain the general pen shape without excessive deformation. For example, it is possible to prevent abnormal deformation even when pressed down.

Therefore, even in a device employing a touch screen panel, since the change in capacitance due to the touch pen is predicted to a certain degree, the input by the touch pen can be easily detected.

In addition, even when the same user maintains the degree of support of the inner core, it is possible to prevent the touch body from being gradually changed when a straight line or a curve is drawn with the touch pen, and to maintain a constant pressure.

In addition, since the elastic touch body moves only a certain depth and is blocked by the inner core, the user may provide a click feeling even in a simple pressing operation.

In addition, when the wear-resistant layer is formed using a urethane material, carbon and the like can be prevented from being applied to the panel, and it is possible to express a specific color or pattern inside the urethane material, so that various expressions can be expressed in appearance.

1 is an exploded perspective view of a touch pen for explaining a touch pen according to an embodiment of the present invention.
FIG. 2 is a partially enlarged cross-sectional view of the touch pen of FIG. 1.
3 is a cross-sectional view illustrating an example of using the touch pen of FIG. 1 in a vertical state.
4 is a cross-sectional view illustrating an example of using the touch pen of FIG. 1 in an inclined state.
5 is a perspective view illustrating a touch pen according to an embodiment of the present invention.
6 is an exploded perspective view illustrating the touch pen of FIG. 5.
FIG. 7 is a cross-sectional view for describing a touch end of the touch pen of FIG. 5.
8 is an exploded perspective view illustrating a touch pen according to another exemplary embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings, but the present invention is not limited or limited by the embodiments. For reference, in the present description, the same numbers refer to substantially the same elements, and may be described by quoting contents described in other drawings under such a rule, and the contents repeated or deemed apparent to those skilled in the art may be omitted.

1 is an exploded perspective view of a touch pen for explaining a touch pen according to an embodiment of the present invention, Figure 2 is a partially enlarged cross-sectional view of the touch pen of FIG.

1 and 2, the touch pen 100 includes a pen body 110, an inner core 120, and a touch body 130. An end of the pen body 110 is provided with a touch body 130 formed of an elastic material, and an inner core 120 is interposed between the pen body 110 and the touch body 130.

Specifically, the pen body 110 may be formed in a general pen shape or a pillar shape, and in some cases, may be formed in various shapes, for example, small pieces or thimble, in addition to the pen shape. . The pen body 110 is formed of a conductive material such as metal, and its outer surface is protected by the insulating coating layer 116. In this embodiment, the pen body 110 is provided of an aluminum material, and the insulating coating layer 116 may be formed on the outer surface of the pen body 110 through anodizing treatment.

The anodized insulating coating layer 116 may electrically separate the pen body 110 and the finger, and formed on the surface of the aluminum pen body 110 with a thickness of about 100 μm or less, so that the pen body changes in capacitance due to finger contact. Can have a greater impact on In addition, it is possible to provide a high quality coating layer even in the wear resistance and uniformity as an effective insulating coating layer.

The touch body 130 may be formed of silicon or rubber material having elasticity. The touch body 130 may be provided in a plurality of laminated structures, but alternatively, may be formed of a single material or a single mixed material. In some cases, the coating layer for a specific function may be formed on the inner and outer surfaces of the touch body 130. This may be formed.

The inner core 120 is formed in the pen body 110, but may be formed of the same aluminum metal material as the pen body 110, but in some cases may also be formed of a silicone, rubber or foam material that can be slightly modified There is a number. If the inner core 120 is formed of a metal material, the touch body 130 may be electrically connected to the pen body 110 through the inner core 120. The inner core 120 is formed to correspond to the inner surface shape of the touch body 130, and generally may be formed to maintain an interval within about 3.0 mm along the inner surface of the touch body 130.

Here, the touch body 130 and the inner core 120 may be formed to have a pointed end or a rounded end, and the inner surface of the touch body 130 is completely spaced apart from the outer surface of the inner core 120. It may be formed to, but in some cases may be formed so as to contact the upper portion.

The touch body 130 may be mixed with an electrical material. As described above, the electrical material is a material that can change the capacitance on the surface of the touch screen panel when the touch body is pressed and deformed on the panel or when it is in contact with the panel surface. The same conductive material may be used, and other properties besides conductivity may be expected, such as a high dielectric constant material. The high dielectric constant material may be a ceramic material such as titanium dioxide (TiO ₂ ), barium titanate (BaTiO ₃ ), lead titanate (PbTiO ₃ ), or the like, which may change other electrical characteristics other than conductivity.

In the present embodiment, the conductive material such as carbo is mixed inside the touch body 130 in powder form as an electrical material, but alternatively, it may be provided in a structure stacked on or inside the touch body or the inner core.

The touch body 130 may be provided in a laminated structure including the elastic layer 132 and the wear resistant layer 134. The elastic layer 132 may be provided using silicon or natural rubber, and the wear resistant layer 134 may be provided using urethane or silicon. In some cases, the wear resistant layer may be provided using PET or PC film.

Electrical materials may be mixed or applied to any one or both of the elastic layer 132 and the wear-resistant layer 134 of the touch body 130, and the electrical materials to be mixed may be the same kind or different kinds. As described above, the electrical material may be a conductive material such as metal or carbon, and a material capable of increasing the sensitivity of the touch pen by changing electrical properties such as a high dielectric constant material. In addition, since the electrical material may also be formed on the decorative layer 136 and the binder layer 138 which will be described later, the electrical material may be mixed or formed on all or a part of the laminated structure forming the touch body 130. .

According to another embodiment, a metal layer may be interposed between the wear resistant layer 134 and the elastic layer 132 as a conductive material, and the metal layer may be used in methods such as deposition, sputtering, inkjet printing, silkscreen, spray coating, plating, and the like. It may be formed on the wear-resistant layer 134 or the elastic layer 132 by. Alternatively, it may be formed by laminating a film imparted with conductivity.

The touch body 130 may further include a decoration layer 136 inward of the wear resistant layer 134. When the wear-resistant layer 134 is formed of a material such as urethane, the decorative layer 136 may be visible to the outside, and the exterior of the touch body 130 may be decorated by expressing a specific color or a specific pattern. Unlike rubber or silicone mixed with conventional carbon, the wear-resistant layer 134 of urethane is excellent in resistance to abrasion, and may include a powder of an electrical material inside the urethane. 136 can also be formed, which can impart many advantages. The decorative layer 136 may be formed by color printing. Alternatively, the decorative layer 136 may be formed by various methods such as carbon ink printing, metal or oxide deposition, and the decorative layer 136 itself may be provided in a single layer or a multilayer structure. .

3 is a cross-sectional view illustrating an example of using the touch pen of FIG. 1 in a vertical state, and FIG. 4 is a cross-sectional view illustrating an example of using the touch pen of FIG. 1 in an inclined state.

Referring to FIG. 3, when the touch pen 100 is used in a vertical state, the touch body 130 is partially deformed to be in contact with a relatively wide surface on the touch screen panel, and mixed inside the touch body 130. The electrical material may interact with the electrode patterns of the touch screen panel to change the capacitance.

At this time, the touch body 130 is deformed only by a predetermined depth and blocked by the inner core 120, and the user may press the touch pen 100 only to the extent that the touch body is blocked by the inner core 120.

In addition, referring to FIG. 4, even when the touch pen 100 is used in an inclined state such as a form of holding a pen, the touch body 130 is partially deformed to be in contact with a wide surface on the touch screen panel. The touch body 130 may be deformed only by a certain distance and then blocked by the inner core 120. Even when the side is in contact with each other, the touch body 130 can be prevented from being excessively deformed, and the user can easily grasp an appropriate depth such as how much to press by the inner core 120.

The central and side portions of the touch body 130 can be kept at a distance of approximately 3.0 mm from the surface of the inner core 120, and the touch pen is pressed only a certain distance and then provides a kind of click feeling by providing resistance. You may.

The inner core 120 allows the user to physically sense the depth at which the touch pen is pressed and the appropriate degree of pressure, and the inner core 120 functions as a stopper, which is excessive in the capacitive touch pen. The area of the capacitance can be prevented from increasing. Further, by forming a stopper than when there is no stopper, the user can always maintain a constant touch pressure.

5 is a perspective view illustrating a touch pen according to an exemplary embodiment of the present invention, FIG. 6 is an exploded perspective view illustrating the touch pen of FIG. 5, and FIG. 7 illustrates a touch end of the touch pen of FIG. 5. It is a section for.

5 to 7, the touch pen 200 capable of LA touch recognition according to the present embodiment may use a capacitive touch recognition and a general writing instrument function. The touch pen 200 includes a pen body 210 and a touch body 230 including a writing function. The pen body 210 of the touch pen 200 includes an ink core 225 including a pen holder 215 and a writing point 220, and the pen holder 215 by pressing the other end of the pen holder 215. The writing point 220 of the embedded ink core 225 may be exposed or concealed. The structures of the pen holder 215 and the ink core 225 of the general ball pen are obvious to those skilled in the art, and detailed description thereof will be omitted.

The pen body 210 includes a pen holder 215 made of metal and an insulating coating layer 216 formed on a surface thereof. As described above, the pen holder 215 may be made of aluminum, and the surface of the pen holder 215 may be formed of the insulating coating layer 216 by anodizing. Alternatively, the pen holder 215 may be formed of another metal material, and the insulating coating layer 216 may be formed by depositing, printing, or coating an oxide film or an insulating material.

An end portion of the pen body 210 is provided with a holder 212 which is tightly fixed to the touch body 230 and an inner core portion 214 formed at an end portion of the holder 212, and an ink at the end portion of the inner core portion 214. A body hole 217 is formed to project the shim 225. The holder 212 is formed to be stepped from the surface of the pen body 210 by approximately the thickness of the touch body 230, and the conductive portion 240 is formed on the surface of the holder 212.

The touch body 230 formed of an elastic material may be inserted into and fixed to the holder 212. The touch body 230 may be formed of silicon or rubber material having elasticity. Although the touch body may be provided in a plurality of laminated structures, as shown, the touch body 230 may be formed of a single material or a single mixed material, and in some cases, the inner and outer surfaces of the touch body 230. A coating layer for a specific function may be formed in. For example, a coating layer may be provided on the surface of the touch body 230 to improve coloring or surface smoothness.

A body hole 217 for passing the ink shim 225 is formed at the writable end of the pen holder 215, and the body hole 217 is fixed to the holder 212 while the touch body 230 is inserted into the periphery. The touch body 230 includes a cap hole 238 corresponding to the body hole 217, and the cap hole 238 is spaced about 2 to 3 mm from the body hole 217, and the touch is performed in a spaced state. The body 230 may be deformed by an external force.

For reference, in the present embodiment, the body hole 217 and the touch body 230 for the passage of the ink core 225 are formed on the same side with respect to the pen holder 215, but in some cases the ink core with respect to the pen holder It may also be formed on the opposite side of each other. For example, as shown in Figure 8, the ink core 315 is fixed to one side of the pen body 310, such as a conventional ballpoint pen or pencil, and the touch body 330 or the touch body 330 on the other side Combinations of inner cores 320 may be mounted. A ball pen cover 318 or the like may further be used. Here, the inner core 320 may be provided as a structure that can be mounted or detached at the end of the pen body 310 in which the insulating coating layer 316 is formed, and may also be provided as silicon or rubber including a metal material or an electrical material. It is possible. Of course, it is also possible to mount the ink core so that it can be sunk without being fixed to the pen holder, and with respect to such a configuration, reference can be made to a conventional writing instrument configuration.

In addition, the electrical material may be mixed in the touch body 230. As described above, the electrical material is a material that can change the capacitance on the surface of the touch screen panel when the touch cap is deformed while being pressed on the panel or when it is in contact with the surface of the panel. The conductive material may be the same, or may be a high dielectric constant material or an electrolyte.

In the present embodiment, the conductive material or the high dielectric constant material is mixed inside the touch body 230 in the form of powder as an electrical material, but alternatively, the touch material may be provided in a structure stacked on or inside the touch cap or the inner core.

An insulating coating layer 216 may be formed on the surface of the holder 212. Alternatively, the pen holder 215 may be partially exposed to be electrically connected to the touch body 230. The finger is in close contact with the conductive region extending through the holder 212, and the change in capacitance through the touch body 230 may be further increased by the action of the holder 212 and the finger.

The inner core portion 214 may be formed at an end of the holder 212 of the pen body 210. The inner core portion 214 may be formed of a metal material integrally with the holder 212, but may also be formed of plastic, or a partially deformable silicone, rubber or foam material. The inner core part 214 is formed to correspond to the inner surface shape of the touch body 230, and generally may be formed to maintain an interval within about 2 to 3.0 mm along the inner surface of the touch body 230.

Here, the touch body 230 and the inner core portion 214 may be formed to have a pointed end or a rounded end, and the inner surface of the touch body 230 may be formed from the outer surface of the inner core portion 214. Although all may be formed to be spaced apart, in some cases it may be formed to be in contact with the lower portion.

As described above, although described with reference to a preferred embodiment of the present invention, those skilled in the art will be variously modified and changed without departing from the spirit and scope of the invention described in the claims below I can understand that you can.

100: Touch pen 110: Pen body
120: internal core 130: touch body
200: Touch pen 210: Pen body
214 ： inner core 230 ： touch body

Claims (16)

In the touch pen applicable to the touch screen panel using a change in capacitance,
Pen body made of metal;
An insulating coating layer of a thin film formed on the surface of the pen body; And
And a touch body including an electrical material for affecting a change in capacitance on the touch screen panel and mounted to an end of the pen body.
The touch pen is partially or spaced apart from the end of the pen body, the touch pen, characterized in that the elastic deformation partly in contact with the touch screen panel. The method of claim 1,
The pen body is a touch pen, characterized in that provided in the form of hollow hollow or hollow non-hollow body. The method of claim 1,
The pen body is provided using aluminum, and the insulating coating layer is a touch pen, characterized in that the anodizing layer formed on the pen body surface of the aluminum material. The method of claim 1,
The pen body of the metal material is a touch pen, characterized in that electrically connected or separated from the touch body. The method of claim 1,
And an inner core protruding from an end of the pen body, wherein the touch body is deformed within a limited range by the inner core. The method of claim 5,
And a distance between the touch body and the inner core is maintained at 3 mm or less. The method of claim 1,
The touch pen is a touch pen, characterized in that provided in a single layer or a multi-layer structure. The method of claim 7, wherein
The touch body is a touch pen, characterized in that it comprises an inner elastic layer and the wear-resistant layer formed on the outer surface of the elastic layer. The method of claim 8,
And the electrical material is mixed in at least one of the elastic layer and the wear resistant layer. The method of claim 8,
And the electrical material is interposed between the elastic layer and the wear resistant layer. The method of claim 8,
The wear-resistant layer is a touch pen, characterized in that provided using a urethane material. The method of claim 8,
Touch pen, characterized in that a decorative layer is interposed between the wear-resistant layer and the elastic layer of the urethane material. The method of claim 1,
The electrical material is a touch pen, characterized in that the conductive material or high dielectric constant material. The method of claim 1,
The pen body may include a writing unit using graphite or ink, and the pen may be written using the touch pen and touch recognition using the touch body. The method of claim 14,
The writing unit with respect to the pen body is mounted so as to be protruding, the writing unit and the touch body is a touch pen, characterized in that formed on the same side. The method of claim 14,
The writing unit is mounted on the pen body so that the writing unit is protruding or fixed, wherein the writing unit and the touch body are formed on opposite sides.

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