JP2016115029A - Handwriting input pen - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an input pen for an electrostatic capacitance type input device equipped with a pen tip made of a material, which does not damage the surface of input panel when sliding the input pen thereon to input information into the device, while ensuring a high responsiveness while giving a user an appropriate pen touch.SOLUTION: An input pen 1, which is used for an electrostatic capacitance type input device, includes: a shaft body 2 made of a porous material; and a pen tip 3 attached to the shaft body 2. The pen tip 3 has a contact face 30 which, when used, comes into contact with the input panel. A part or all of the surface of the shaft body 2 is coated with a conductive substance.SELECTED DRAWING: Figure 1

Description

  The present invention relates to an input pen used for a capacitive input terminal.

Conventionally, when inputting information to a capacitance-type input terminal that can input by sensing a change in capacitance on the surface of the input panel when a conductor such as a finger contacts the input panel, the input panel I input directly with my finger. Examples of the capacitance type input terminal include a computer capacitance type coordinate input device or a display-integrated capacitance type input device.
However, with the finger, the contact state with the input panel changes due to force, and the position shifts, or the operability deteriorates when the finger does not slide due to sweat, etc., so do not touch the input panel surface directly. Therefore, an invention using a pen-type input device (hereinafter referred to as an input pen) has been made. The input pen used in the capacitive input device is made of a conductive material because it requires conductivity to fingers. As the input pen used in the capacitance type input device, the invention described in Patent Document 1 in which a conductive fiber brush or felt is used for the pen tip and a conductive material such as metal is used for the shaft, The invention described in Patent Document 2 uses conductive rubber for the shaft and a conductive material for the shaft. Patent Document 3 discloses an invention relating to a method for freely adjusting a material containing a conductive substance in order to use the conductive substance for a capacitive input pen.

JP-A-10-39989 JP-A-10-161895 JP2013-239093A

However, as in Patent Document 1, when a brush or felt is used for the pen tip, the tip is soft, the touch at the time of input is soft, and the input panel is not damaged. I cannot input location information. In addition, when inputting a writing sensation that slides on the input panel, the friction coefficient is too low to provide a writing feeling as if writing on paper with a pencil.
Further, as in Patent Document 2, when conductive rubber is used for the pen tip, there is no problem in the pointing operation, and the touch at the time of input is soft and does not damage the input panel. The sliding operation is highly resistant and cannot be comfortably slid.

  SUMMARY OF THE INVENTION Accordingly, an object of the present invention is to provide an electrostatic force that can provide an appropriate writing feeling while maintaining high reactivity when an input pen is slid on an input panel in order to input information to a capacitive input device. An input pen for a capacitive input device is provided. Another object of the present invention is to provide an input pen for a capacitive input device having a pen tip that can be manufactured without using a material that damages the surface of the input panel.

(First invention)
1st invention in this invention is the input pen 1 used for an electrostatic capacitance type input device,
A shaft body 2 made of a porous body, and a nib 3 provided on the shaft body 2,
The nib 3 has a contact surface 30 that comes into contact with the input panel during use,
A part or all of the surface of the shaft body 2 is covered with a conductive substance.
Here, “covering with a conductive substance” means covering with a thin film made of a conductive substance, applying a conductive substance, or plating.

(Second invention)
According to a second aspect of the present invention, in addition to the characteristics of the first aspect, the porous body constituting the shaft body 2 is wood.
(Third invention)
According to a third aspect of the present invention, in addition to the features of the first aspect, the porous body constituting the shaft body 2 is a plastic foam,
The plastic foam has a density of 100 to 550 kg / m ³ .

(Fourth invention)
According to a fourth aspect of the present invention, in addition to the characteristics of the first, second or third aspect, the pen tip 3 contains a conductive substance.
(Fifth invention)
According to a fifth aspect of the present invention, in addition to the features of the fourth aspect, the nib 3 includes a fiber bundle, and the fiber bundle includes a fiber containing a low-melting resin and a conductive fiber. It is characterized by being fused together.

(Sixth invention)
The sixth invention of the present invention is characterized in that, in addition to the features of the fourth invention, the pen tip 3 is attached so as to cover the tip of the shaft body 2.
(Seventh invention)
According to a seventh aspect of the present invention, in addition to the features of the fourth or sixth aspect, the contact surface 30 is formed in a spherical shape, and conductive fibers are electrostatically implanted on the contact surface 30. It is characterized by.

In the present invention, by covering the surface of the shaft body with a conductive material, the conductivity of the shaft body is improved, and an input pen used in a capacitive input device with good reactivity can be provided. Further, even if the shaft body itself is not made of a material made of a conductive material, it is possible to impart conductivity only by covering the surface of the shaft body with the conductive material, so that the manufacturing cost can be reduced.
In addition, by using a porous body as the shaft body, when the tip of the pen tip of the input pen slides on the input panel, the vibration of the pen tip at the time of sliding is transmitted to the user's finger through the shaft body. . As a result, a writing feeling can be obtained when writing on a paper with a wooden shaft pencil.

  Furthermore, the use of a fiber bundle as the pen tip or electrostatic flocking of conductive fibers on the contact surface can provide an input pen that has a soft tip and does not damage the input panel surface.

The front view (A) of the input pen in 1st Embodiment, and the schematic diagram (B) of a cross section are shown. The schematic diagram of the cross section of the input pen in a modification is shown. FIG. 2 is a schematic diagram of a cross section of the input pen in the first embodiment. The schematic diagram of the cross section of the input pen in Example 2 is shown.

As shown in FIG. 1B, an input pen 1 according to the present embodiment is an input pen 1 used for a capacitance-type input device, and is provided with a shaft body 2 and a tip of the shaft body 2. With a nib 3
(Shaft body 2)
The shaft body 2 is made of a porous body, and the porous body is wood or a plastic foam having a density of 100 to 550 kg / m ³ . Examples of the plastic foam include synthetic wood containing plastic.
A part or all of the surface of the shaft body 2 is covered with a conductive material. This covered portion is referred to as a covering portion 20. The covering portion 20 can be provided by applying a conductive material to the surface of the shaft body 2.

As a coating method, the porous body may be immersed in a resin solution containing a conductive substance, or brushing, spraying, or the like may be performed. Moreover, you may perform baking etc. as needed.
The resin solution containing a conductive substance can be adjusted by adding a tomato for appropriately adjusting the conductivity to a solution in which a conductive resin that is a conductive substance is dispersed or solubilized.
Examples of the conductive resin include polypyrrole, polythiophene, polyethylenedioxythiophene, polyisothianaphthene, and polyaniline.
The topanto is 2,3,7,8-tetracyano-1,4,6,9-tetraazanaphthalene, dodecylbenzenesulfonic acid, p-toluenesulfonic acid and the like.

In addition, as a solution to be applied to the surface of the shaft body 2, special carbon blacks such as carbon black, graphite, and ketjen black, carbon nanotubes, graphene, fullerene, metal particles, etc. dispersed as conductive substances are dispersed. It may be a solution or a molten resin solution.
The covering portion 20 may be provided by covering the surface of the shaft body 2 with a thin film containing a conductive substance (hereinafter referred to as a conductive thin film). Examples of the conductive thin film include a synthetic resin thin film containing carbon black or metal fine particles, or a foil made of a conductive metal.

The covering portion 20 may be provided by plating the surface of the shaft body 2.
(Nib 3)
The tip of the nib 3 protrudes from the tip of the shaft body 2 as shown in FIGS. 1 (A) and 1 (B). Here, a portion that contacts the input panel is referred to as a contact surface 30.
The nib 3 is composed of a fiber bundle obtained by bundling conductive fiber bodies.
In order to obtain this fiber bundle, the fiber containing the low melting point resin and the fiber containing the conductive material are mixed and then the mixed fibers are bonded together.

Examples of the low melting point resin used for the fiber containing the low melting point resin include a low melting point polyamide fiber, a low melting point polypropylene fiber, a low melting point polyester fiber, and a low melting point polyethylene fiber.
A method for producing a fiber containing a conductive substance can be made based on a resin solution containing a conductive substance. Here, as the resin solution containing the conductive substance, the resin solution used when applying the conductive substance to the porous body constituting the shaft body 2 can be used as appropriate.
In addition, the production method of the fiber bundle which bundled the fiber body which has electroconductivity is not restricted to this.

The pen tip 3 can be used as it is, but there is a case where the responsiveness is inferior unless the entire contact surface 30 is brought into contact with the input panel. In this case, it is possible to obtain the input pen 1 having a suitable response regardless of the contact angle by unbinding the fiber bundles constituting the nib 3 and giving the contact surface 30 a flexible touch. it can. Here, when the length of unraveling is long, it is possible to obtain the input pen 1 that provides a writing feeling as when using a brush pen.
An outer skin portion having conductivity may be provided on the outer periphery of the fiber bundle constituting the nib 3. The outer skin portion is obtained by mixing a relatively large amount of low melting point fibers in the outer peripheral portion of the fiber bundle. Specifically, when the low-melting fibers are heated, they are heat-bonded to each other and hardened. Therefore, by mixing many low-melting fibers only in the outer peripheral portion of the fiber bundle, only the outer peripheral portion is hardened. By providing the outer skin portion, it is possible to prevent the fibers from falling off the fiber bundle and to greatly improve the mechanical strength such as the bending strength of the fiber bundle. In addition, when the outer skin portion is made conductive, the “area” in contact with the pen tip can be clearly recognized.

The contact surface 30 can include a plane that intersects the central axis of the input pen 1, and the angle between the plane and the central axis of the input pen 1 is preferably 45 ° to 90 °. If it is less than 45 °, the sharpness of the contact surface 30 becomes too sharp, and the fiber bundle tends to fall apart. The area of the plane is preferably 10mm ² ~80mm ^2, more desirably is 20mm ² ~40mm ^2. When the contact area is less than 10 mm ² , the feeling of use etc. is not different from the conventional input pen, and the contact area exceeding 80 mm ² is too large and there is a high possibility of contact other than the target location on the input panel. End up.

Further, the nib 3 is composed of a fiber bundle in which conductive fiber bodies are bundled, but at least the contact surface 30 and the tip end portion may be formed of a fiber bundle in which fiber bodies are bundled, The nib 3 located inside the shaft body 2 may be formed of a conductive material such as conductive fiber, conductive sponge, metal, and graphite sintered body. At this time, the nib 3 located inside the shaft body 2 and the tip portion need to be electrically connected.
(Modification)
In the present embodiment, the nib 3 is composed of a fiber bundle in which fibrous bodies having conductivity are bundled. However, it may be any soft material such as felt that is conductive.

Further, as shown in FIG. 2, a conductive resin is used as a base material for the pen tip 3, the contact surface 30 is formed into a spherical shape, and conductive fibers are electrostatically flocked to the contact surface 30 to cause the pen tip 3. It is good.
In addition, as shown in FIG. 3, instead of fitting the pen tip 3 into the shaft body 2, a member containing a substantially hemispherical conductive material is attached so as to cover the tip of the tapered shaft body 2. This may be the nib 3. In this case, it is preferable to electrostatically implant conductive fibers on the contact surface 30 so that the input panel is not damaged when the contact surface 30 slides on the input panel.
In addition, the covering portion 20 may be provided on the surface of the shaft body 2 by applying a conductive substance, covering the surface of the shaft body 2 with a conductive thin film, or plating the surface of the shaft body 2. These methods may be combined.

In addition, the covering portion 20 that covers the surface of the shaft body 2 is not required to be provided on the entire surface of the shaft body 2 because it is sufficient to secure at least a conductive path from the portion held by the user to the pen tip 3.
(Characteristics of input pen 1)
The resistance value from the contact surface 30 of the input pen 1 in the present embodiment to the outer peripheral surface touched by the user of the shaft body 2 is not particularly limited. If this resistance value is 10 MΩ or less, a responsive touch pen can be obtained. However, even if the resistance value is so high that it cannot be measured by a general measuring instrument, the lower part of the shaft 2, that is, the pen. When the user grips the tip 3 closer to the contact surface 30, the reactivity without any problem in use can be achieved.

  In addition, by using a porous body as the shaft body 2, when the tip of the pen tip 3 of the input pen 1 slides on the input panel, the vibration of the pen tip 3 when it slips is used through the shaft body 2. It is transmitted to the finger of the person. As a result, a writing feeling can be obtained when writing on a paper with a wooden shaft pencil.

As shown in FIG. 3, a covering portion 20 is provided by applying a conductive material on the surface of the shaft body 2 made of wood, and a nylon fiber coated with silver plating as a nib 3 is attached to the tip of the shaft body 2. The input pen 1 was obtained by attaching the contact surface 30 so as to cover the silicone rubber planted.
The covering portion 20 was provided on the surface of the shaft body 2 by dipping the shaft body 2 in a solution in which carbon black was dispersed in water, and then removing the shaft body 2 and drying it.
The resistance value from the contact surface 30 of the input pen 1 created as described above to the outer peripheral surface of the shaft body 2 was 70 kΩ.

As shown in FIG. 4, a coating portion 20 is provided on the surface of the shaft body 2 having a tapered tip, and nylon fiber coated with silver plating as a pen tip 3 is planted on the contact surface 30 at the tip of the shaft body 2. An input pen 1 was obtained by attaching it so that it was covered with silicone rubber.
The shaft body 2 is made of expanded polypropylene having a density of 300 kg / m ³ .
Further, the covering portion 20 of the shaft body 2 is provided with a conductive thin film portion 20a in which the side surface of the cylindrical shaft body 2 is covered with an aluminum foil, and a conductive thin film portion 20a. The coating portion 20b is provided by applying a solution in which carbon black is dispersed by brush coating and drying.

  The resistance value from the contact surface 30 of the input pen 1 created as described above to the outer peripheral surface of the shaft body 2 was 0.1Ω.

  INDUSTRIAL APPLICABILITY The present invention can be used as an input pen used for underlining in so-called electronic books, adding and processing digital images, or inputting characters, handwriting, and drawn lines.

1 Input pen 2 Shaft body 20 Cover
20a Conductive thin film 20b
3 Nib 30 Contact surface

Claims (7)

An input pen for use in a capacitive input device,
A shaft body made of a porous body, and a pen tip provided on the shaft body,
The nib has a contact surface that comes into contact with the input panel during use,
An input pen, wherein a part or all of the surface of the shaft is covered with a conductive material.   The input pen according to claim 1, wherein the porous body constituting the shaft body is wood. The porous body constituting the shaft body is a plastic foam,
The input pen according to claim 1, wherein the plastic foam has a density of 100 to 550 kg / m ³ .   The input pen according to claim 1, wherein the pen tip contains a conductive substance.   5. The input pen according to claim 4, wherein the nib comprises a fiber bundle, and the fiber bundle includes a fiber containing a low-melting point resin and a conductive fiber, and is fused to each other. .   The input pen according to claim 4, wherein the pen tip is attached so as to be put on a tip of a shaft body.   The input pen according to claim 4 or 6, wherein the contact surface is formed in a spherical shape, and conductive fibers are electrostatically implanted on the contact surface.