JP5793391B2 - Input pen - Google Patents

Description

  The present invention relates to an input pen for performing input to an input device (hereinafter simply referred to as a touch pad or the like) that converts displacement of a contact position into input information such as a touch pad, a touch panel, and a digitizer.

Conventionally, a touch pad or the like, which is one of capacitance detection type pointing devices, uses an operator's finger when performing an input operation.
However, when an input operation is performed with a finger on a touch pad or the like, the contact area of the fingertip to be operated is not constant, and the detected coordinate information may not match the operator's intention.

  For this reason, instead of an operation with a finger, an operation with an input pen (stylus pen) has been performed. In particular, when performing so-called handwriting input in which a finger or an input pen is moved so as to write characters on an operation surface such as a touchpad, the input pen is closer to actual writing and easier to input. .

When performing input on a touchpad using an input pen, for example, tap an input surface such as a touchpad with an input pen to select a menu or button, drag to move an icon or file, An operation such as sliding the input pen pressed against the input surface for character input is performed. For this reason, if the tip of the input pen, that is, the tip of the pen, is hard, the input surface of the touch pad or the like will be damaged. Therefore, an elastic material such as rubber or sponge is used for the pen tip.
In particular, the touch panel superimposed on the display makes it difficult to see the display on the display if it is scratched, so it is necessary to ensure elasticity so as not to be scratched even if a considerable number of contacts are made.
In addition, in the capacitance detection type pointing device, when contact is made in a predetermined area or more, contact is detected and input is performed, so that the pen tip of the input pen can secure a contact surface larger than this area. It is configured.

JP 2000-122799 A JP-A-10-222280

As described above, since the conventional input pen uses an elastic material for the contact surface with the input surface such as a touch pad, the dynamic friction coefficient when the input pen is slid against the input surface for character input, etc. And the resistance when moving the input pen is strong, there is a problem that it is difficult to input.
For this reason, a material in which the surface of the elastic material is chemically treated with a surface treatment agent to reduce the dynamic friction coefficient has been proposed. However, even if the dynamic friction coefficient is slightly reduced by the surface treatment, the original dynamic friction coefficient is high, so that it is not a fundamental solution. In addition, since the processing is performed only on the surface, there is a problem that if the surface is worn during use, the effect of reducing the dynamic friction coefficient is lost and the durability is poor.
Furthermore, when the user carries the touchpad or the like, the surface of the touchpad or the like may be smudged with a fingerprint or the like, which is often oil such as sebum. If there is oil stains on the input surface, if the surface of the input pen is an elastic material such as rubber, the pen tip will slide only on the oil stains.
Stable input is not possible. In addition, the oil stain is extended along with the movement of the input pen and spreads on the input surface, so that the display on the display becomes very difficult to see on the touch panel integrated with the display.

  The present invention solves such problems, and an object of the present invention is to provide an input pen with improved operability by keeping the coefficient of dynamic friction with respect to the input surface low within a predetermined range.

In order to solve the above problems, the input pen of the present invention is
An input pen for performing an input operation on a capacitance detection type coordinate input device,
A support having a predetermined rigidity or more;
An upper covering portion covering at least a contact surface side of the support body with the coordinate input device;
The dynamic friction coefficient between the contact surface covered with the upper cover and the input surface of the coordinate input device is 0.05 to 0.25.

  ADVANTAGE OF THE INVENTION According to this invention, the input pen which suppressed the dynamic friction coefficient with respect to an input surface to the predetermined range low, and improved operativity can be provided.

External view of input pen according to Embodiment 1 Illustration of the nib part Explanatory drawing of test to confirm the rigidity of the nib Illustration of the nib Diagram showing the method for measuring the dynamic friction coefficient

Hereinafter, embodiments for carrying out the present invention will be described with reference to the drawings. The configuration of the following embodiment is an exemplification, and the present invention is not limited to the configuration of the embodiment.
1A and 1B are external views of the input pen according to the first embodiment. FIG. 1A is a front view, FIG. 1B is a plan view, and FIG. 1C is a bottom view. FIG. 2 is an explanatory diagram of the pen tip portion and shows a cross section (xy plane) parallel to the front surface.

As shown in FIG. 1, the input pen 10 according to the first embodiment includes a rod-shaped cylindrical main body 1 and a pen tip 2 connected to one end of the main body 1.
The main body 1 is a rod-like member that is gripped by a user, and has at least a part of conductivity. In the present embodiment, the main body 1 has a cylindrical shape. However, the shape is not limited to this, and any shape that is suitable for the user to hold and operate, for example, a rectangular column or a hexagonal column may be used. Also, the size of the main body 1 may be arbitrarily set as long as it is suitable for hand-held operation. For example, the shaft diameter is 5 mm to 20 mm, the shaft length (the length in the y-axis direction). ) Between 50 mm and 150 mm. In the first embodiment, the outer shape of the shaft is 9 mm, the length is 120 mm, and the wall thickness is 1.5 mm.

  Moreover, in this Embodiment 1, the electroconductivity of the main body surface and the nib 2 is ensured by making the main body 1 metal. As the material of the main body 1, iron, stainless steel, aluminum, nickel, copper, brass, and alloys thereof can be used. In this embodiment, an aluminum alloy is used from the viewpoint of workability, weight, and weather resistance.

As shown in FIG. 2, the pen tip 2 has an outer shape having a dome-shaped contact portion 21 and a joint portion 22 with the main body 1. The nib 2 is fixed to the main body 1 by fitting the joint portion 22 into the hollow portion 13 of the main body 1. At this time, by forming the outer diameter of the joint portion 22 of the nib 2 to be substantially the same as or slightly larger than the inner diameter of the main body 1, the friction between the inserted outer peripheral surface of the joint portion 22 and the inner peripheral surface 12 of the main body 1. Therefore, the pen point 2 may be prevented from coming off, or the joining portion 22 and the inner peripheral surface 12 may be bonded with an adhesive or the like.

  The nib 2 includes a support 23B made of a highly rigid material, an elastic body 23A that covers the tip of the support 23B, and a conductive upper surface that covers the outer surfaces of the support 23B and the elastic body 23A. And a covered portion 24.

The material of the support 23B is not particularly limited as long as it has a predetermined rigidity or more, and may be a metal, ceramic, synthetic resin, or the like. In the case of using a synthetic resin, for example, one having a hardness of at least 40 ° or more, preferably 50 ° or more is used. The hardness here is JIS K
It was determined with a 6253 durometer type A.

  The elastic body 23A is a member that is softer and more elastic than the support body 23B, such as rubber, silicon, urethane, sponge, etc., and has a hardness of less than 40 °, preferably 20 ° to 30 °. Consists of. Thereby, when the nib 2 is pressed against a plane with a predetermined force (a force corresponding to writing pressure), the elastic body 23A is compressed and the tip of the nib 2 is deformed. It is regulated by 23B. FIG. 3 is an explanatory diagram of a test for confirming the deformation amount. As shown in FIG. 3A, the state in which the pen tip 2 touches the plane 80 so that the angle formed by the central axis 14 of the input pen 10 and the plane 80 becomes a predetermined angle θ is set as an initial state. When biased in a direction F1 perpendicular to the plane 80 with a predetermined force (for example, 50 gW), the contact portion 21 of the pen tip 2 (support 23) is deformed as shown in FIG. The amount moved in the direction F1 of the urging force is measured as the deformation amount Hf. In FIG. 3B, the initial state of the input pen 10 is indicated by a dotted line, and the deformed state is indicated by a solid line. 3B shows a state in which the contact portion 21 is greatly deformed for the sake of explanation, in the nib 2 of the first embodiment, the deformation is limited by the support body 23B, so that the actual deformation amount Hf is slight. For example, the threshold value of the deformation amount Hf is set to at least 2 mm or less, preferably 1 mm or less, more preferably 0.5 mm or less. In this way, by restricting the amount of deformation of the pen tip by the support 23B, shaft blurring during character input is prevented and operability is improved.

  The input pen 10 of the present embodiment secures a contact area necessary for input by deforming the elastic body 23 </ b> A while the support body 23 </ b> B having such a high rigidity suppresses shaft blurring. Both can be input with the same and can be input without blurring. For example, in the input pen 10 according to the present embodiment, the load required to make an input by contacting the input surface of the coordinate input device is 15 gW to 40 gW. This load can be changed depending on the hardness of the elastic body 23A, and may be, for example, 20 gW to 30 gW.

  The upper cover 24 is a thin film member provided in close contact with the periphery of the support 23. In the present embodiment, cloth is used as the upper cover portion 24 in order to ensure the conductivity and slidability of the nib. The fabric as the upper cover portion 24 is not limited in the structure such as woven fabric, knitted fabric, felt, and non-woven fabric, and may be any fabric formed from fibers. However, in order to ensure durability when the pen nib 2 is slid and to keep the deformation amount Hf shown in FIG. 3 below a threshold value, the cloth as the upper cover portion 24 should be woven or knitted. desirable. In addition, when using a felt as the upper cover part 24, it is good to shrink what was once woven into a woolen fabric and to make a woven felt.

  The material of the fiber is not particularly limited, and any fiber such as vegetable fiber such as cotton, hemp, and linen, animal fiber such as wool, silk, and cashmere, and synthetic fiber such as nylon, polyurethane, and polyester can be used.

And the upper cover part 24 uses electroconductive fiber for at least one part, and surface resistance is 1 * 10 < ³ >-.
1 × 10 ⁵ Ωsq. Here, the conductive fiber means a fiber such as stainless steel, titanium or aluminum, or a metal layer formed by plating or vapor deposition on the surface of a fiber such as nylon or polyester, or a conductive filler (metal powder, carbon powder, metal Flakes, metal short fibers, carbon short fibers) dispersed in the material.

  The upper covering portion 24 is not limited to the one in which all the fibers are made conductive, and may be one in which conductive fibers are mixed with a part of the fibers constituting the upper covering portion 24. For example, the fabric of the upper cover portion 24 may be manufactured using a twisted yarn in which a predetermined proportion of conductive fibers are mixed with insulating fibers. Further, a woven fabric in which one of the warp and the weft is an insulating yarn and the other is a conductive yarn may be used. Further, when creating a knitted fabric with a plurality of yarns, some yarns may be conductive yarns. Further, a conductive thread may be sewn into a fabric made of an insulating thread. The upper cover portion 24 of the present embodiment produced a knitted fabric using electrically conductive yarn for 1/3 of the yarn when knitting with a 10 to 13 gauge.

  Further, the upper cover portion 24 may be one in which conductivity is ensured by sewing a conductive thread into a cloth made of so-called microfiber as described above. As a result, input can be performed without spreading dirt on the input surface. Here, it is important that the microfiber has a single fiber diameter (single fiber diameter) in the range of 10 to 1000 nm (preferably 100 to 900 nm, particularly preferably 550 to 900 nm). When the single fiber diameter is converted into a single fiber fineness, it corresponds to 0.000001 to 0.01 dtex. When the single fiber diameter is smaller than 10 nm, the fiber strength is lowered, which is not preferable for practical use. On the contrary, when the single fiber diameter is larger than 1000 nm, there is a possibility that sufficient sebum removal performance may not be obtained, which is not preferable. Here, when the cross-sectional shape of the single fiber is an atypical cross section other than the round cross section, the diameter of the circumscribed circle is defined as the single fiber diameter. The single fiber diameter can be measured by photographing the cross section of the fiber with a transmission electron microscope. Moreover, it is preferable that the dispersion | variation in single fiber fineness exists in the range of -20%-+ 20%.

  In the filament yarn, the number of filaments is not particularly limited, but is preferably 3000 or more (more preferably 5000 to 10000) in order to obtain excellent sebum removal properties. The total fineness of the filament yarn (the product of the single fiber fineness and the number of filaments) is preferably in the range of 5 to 150 dtex.

  The fiber form of the filament yarn is not particularly limited, but is preferably a long fiber (multifilament yarn). The cross-sectional shape of the single fiber is not particularly limited, and may be a known cross-sectional shape such as a circle, a triangle, a flat shape, or a hollow shape. In addition, normal air processing and false twist crimping may be applied.

  The type of polymer forming the filament yarn is not particularly limited, but a polyester polymer is preferable. For example, polyethylene terephthalate, polytrimethylene terephthalate, polybutylene terephthalate, polylactic acid, stereocomplex polylactic acid, polyester obtained by copolymerizing the third component, and the like are preferably exemplified. Such polyester may be material recycled or chemically recycled polyester.

The joint portion 22 of the pen nib 2 covering the outer peripheral surface of the support 23 with the upper cover portion 24 is fitted into the hollow portion 13 of the main body 1 and fixed, so that the outer surface of the upper cover portion 24 and the inner peripheral surface of the main body 1 are fixed. And the nib 2 and the main body 1 are electrically connected. That is, when the user holds the metal main body 1, the user's hand and the pen tip are brought into conduction. For this reason, when the pen tip 2 comes into contact with an input surface such as a touch pad during input, the pen tip 2 that is electrically connected to the user functions as a ground line, and the pen tip 2 and the touch pad are electrostatically coupled to each other. The touch pad or the like detects this change in capacitance as input information.

4A and 4B are explanatory diagrams of the tip shape of the pen tip 2. FIG. 4A is a diagram showing the tip of the pen tip when not in contact, and FIG. 4B is a diagram showing the tip of the pen tip during input. It is.
As shown in FIG. 4A, the tip of the pen tip 2 has a dome shape that is convex toward the tip of the long axis direction (axis 14 direction), and touches an input surface such as a touch pad during input. The curvature X when the region Ca is deformed in contact with the input surface is set to 1/5 mm to 1/10 mm. As shown in FIG. 4B, when the tip of the pen tip 2 is brought into contact with the input surface 51 such as a touch pad at the time of input, the distance from the input surface 51 to the surface of the pen tip 2 is within the range Sa. The distance is within a predetermined distance Th. Here, the predetermined distance Th is an upper limit value of the distance at which the pen tip 2 and the touch pad or the like are electrostatically coupled. That is, the surface of the pen tip and the touch pad are electrostatically coupled in the region Sa, and the capacitance between them is detected. In the first embodiment, the width of the region Sa is set to be 3 mm to 6 mm.

  Conventionally, an input pen using an elastic body such as conductive rubber or sponge for the pen tip in order to improve the input stability is deformed when input, and the pen tip sinks about 4 to 6 mm. If the pen tip is lifted about 4 to 6 mm for each stroke and the next stroke is not moved, the pen tip will not move away from the input surface such as a touch pad, and the stroke will continue. For this reason, in order to input characters with a conventional input pen, the pen tip must be consciously separated from the input surface for each stroke, and there is a problem that the feeling of operation is very poor.

<Dynamic friction coefficient>
The input pen had a dynamic friction coefficient of 0.05 to 0.25 when measured under the following conditions.
FIG. 5 is a diagram showing a method for measuring the dynamic friction coefficient. As shown in FIG. 5, the input pen 10 of this embodiment is brought into contact with the input surface 9 </ b> A of the coordinate input device 90 vertically, and a load m (150 gW in this example) corresponding to writing pressure is applied in the horizontal direction ( The force F when pulled in the X direction) is measured, and the dynamic friction coefficient μ is obtained based on the following equation.
F = μ (mg + Mg)
However, g is a gravitational acceleration and M is the mass of the input pen 10.
As a result of the measurement, the dynamic friction coefficient of the input pen 10 of this embodiment was 0.05 to 0.25. The dynamic friction coefficient also varies depending on the material of the top cover 24, the weaving method, the knitting method, the thickness of the elastic body 23A, and the like. The lower the dynamic friction coefficient, the more the input pen can be moved without resistance, so unnecessary power is not required, but not only users who prefer light writing.
For this reason, for example, it is desirable that the dynamic friction coefficient be 0.08 to 0.12. Further, it is more desirable that the dynamic friction coefficient is 0.09 to 0.11.
As described above, the input pen of the present embodiment has a conductive cloth on the surface layer in contact with the input surface such as a touch pad, and the dynamic friction coefficient is set to 0.05 to 0.25. It is possible to provide a highly durable input pen in which this sliding lasts.
Further, according to the present embodiment, since the support 23 has high rigidity and the pen tip does not sink during writing, handwritten character input can be performed in the same manner as writing with a normal writing tool, and high operability is achieved. realizable.
Furthermore, the input pen according to the first embodiment uses a conductive cloth for the surface layer in contact with the input surface such as a touch pad, so that even if there is oil stain such as sebum on the input surface, the input pen is stably input. be able to. In addition, oil stains are not spread, and the visibility of the display is not lowered on the touch panel integrated with the display.

10, 20, 20A Input pen 1 Body 2, 2A, 2B, 2C, 2D pen tip

Claims (3)

An input pen for performing an input operation on a capacitance detection type coordinate input device,
A pen tip having a support body having a predetermined rigidity or more , and an upper cover portion covering at least a contact surface side of the support body with the coordinate input device;
A rod-shaped main body for fixing the nib to the tip;
Ri dynamic friction coefficient of 0.05 to 0.25 der between the input surface and the upper contact surface covered with the parts the coordinate input device,
The contact surface of the nib is brought into contact with the input surface in a state where the bar-shaped main body to which the nib is attached is inclined at a predetermined angle with respect to the input surface of the coordinate input device, and the main body is used as the input surface. On the other hand, an input pen in which the amount of movement of the main body vertically when the pen tip is deformed when the pen is biased at 50 gW in the vertical direction is 2 mm or less .   The input pen according to claim 1, wherein the upper cover portion is a conductive cloth. The contact surface covered with the upper cover is a convex curved surface with respect to the coordinate input device,
With the main body inclined at a predetermined angle with respect to the input surface, the contact surface of the pen tip is brought into contact with the input surface, and the main body is biased with a force of 15 gW to 40 gW in a direction perpendicular to the input surface. When it does, the input pen of Claim 1 or 2 from which the width | variety of the area | region which carries out electrostatic coupling with the said input surface among the said convex contact surfaces will be 3 mm-6 mm .

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