KR100904001B1 - Silm mouse for mobile device and method for manufacturing the same - Google Patents

Abstract

The present invention relates to a slim mouse and a method of manufacturing the same, and more particularly, to a slim mouse using a tactile sensor that enhances the contact feeling when the dome is installed at the bottom and clicked.

The slim mouse using the tactile sensor for achieving the object of the present invention is configured by sequentially stacking a spacer and a keypad for the load bumper on the upper part of the tactile sensor, and a plurality of domes are installed on the lower side, the tactile sensor faces each other The upper and lower film having a metal layer on the opposite side of the metal layer is formed to face each other, the upper and lower resistance patterns consisting of a central click portion and a sensing portion formed in a circular shape at the edge of the click portion, It is composed of a spacer which is formed between the resistance patterns between the metal layers to space the distance between the resistance patterns,

The load bumper spacer has a click protrusion formed on a portion of the load bumper facing the click portion of the resistance pattern, and a sensing protrusion formed on portions facing the sensing portion, respectively.

The dome is characterized in that the click dome portion is formed in the portion facing the click portion of the resistance pattern, the sensing dome portion is formed in the portion facing the sensing portion.

In the mouse manufacturing method configured as described above, the process of manufacturing the tactile sensor, and the process of laminating the load bumper spacer and the keypad on the upper part of the tactile sensor, the adhesive process,

The process of manufacturing the tactile sensor may include forming metal layers on opposite surfaces of the upper and lower films, respectively; Forming a plurality of upper and lower resistance patterns on the surfaces of the metal layers, respectively; Bonding the spacers between the films on which the resistance patterns are formed so that the upper and lower resistance patterns are stacked in a state spaced apart from each other;

The process of stacking and attaching the load bumper spacer and the keypad on the tactile sensor may be performed by bonding each of the protrusions protruding from the bottom surface of the load bumper spacer to the click portion and the sensing portion of the resistance pattern, respectively, and then bonding them to each other. It is characterized in that the adhesive to the upper surface of the sensor.

Force Sensor, Tactile Sensor, Mouse, Dome

Description

Slim mouse using tactile sensor and manufacturing method {SILM MOUSE FOR MOBILE DEVICE AND METHOD FOR MANUFACTURING THE SAME}

The present invention relates to a mouse and a method for manufacturing the same, and more particularly, to a slim mouse using a tactile sensor that can freely move, rotate, and click a cursor on a screen using a tactile sensor that is easy to slim. will be.

More specifically, the present invention relates to a slim type mouse using a tactile sensor which has a high contact feeling when a dome is installed at the bottom thereof, and a manufacturing method thereof.

Currently there are many types of input devices as a means for entering commands into computer systems.

Commonly known input devices include buttons, switches, mice, trackballs, joysticks, and the like, and the buttons and switches are mechanical and have a disadvantage in that they cannot control a cursor or move a selection. In other words, when you move the cursor using a button or a switch, you need to use the same key as the arrow direction key. Alternatively, you can enter a specific function or character number and change the cursor direction by pressing a button. There is a disadvantage.

In the case of the mouse, when the user moves the mouse along the surface, the input pointer moves in response to the relative movement of the mouse, and the trackball moves in response to the relative movement of the ball when the user moves the ball in the housing. Will move. A multifunctional mouse having a function of moving and selecting an input pointer and scrolling through position recognition as described above requires a relatively wide mouse pad such as a desk and a table. Therefore, it is difficult to use a general mouse using location recognition as a size limitation problem for mobile devices.

 On the other hand, there is a joystick for cursor operation using force, which is also difficult to apply to mobile devices that are gradually slimmer due to its large thickness, and has a limitation in design and development considering the GUI environment design.

The technology developed and filed by the present applicant to compensate for these disadvantages is a patent application No. 2007-093868 (a slim mouse for a mobile device and its manufacturing method, unpublished).

This technology is a mouse using a plurality of tactile sensors, the lower polymer film having a metal layer on the upper surface and the upper polymer film having a metal layer on the lower surface, formed on the upper and lower portions of each metal layer and faced apart by a spacer Cursor donut array force sensor unit comprising a plurality of force sensors comprising a pair of resistance patterns bonded, a load bumper spacer formed on the upper polymer film layer and having a donut sensor unit and a sensor for click recognition, and And a pad having a donut-shaped sensor part and a click recognition sensor part formed on the load bumper spacer, and a force sensor for clicking recognition formed of a pair of resistance patterns formed under the click recognition sensor part. The movement distance and direction of movement of the mouse cursor by the user's touch are made to use a donut-type sensor unit, and the click is recognized through a force sensor for click recognition.

However, the slim mouse configured as described above may have a smooth movement of the cursor by the tactile sensor of the donut-type sensor unit, but when the user clicks the mouse, the user does not feel the click.

The present invention was developed to solve the above-mentioned disadvantages of the prior art, and provides a slim mouse using a tactile sensor and a method of manufacturing the same that give a hand a touch when clicked.

In particular, the present invention provides a slim mouse and a method of manufacturing the same using a tactile sensor that allows a user to have a touch when a user clicks or senses by installing a dome in a sensing part and a click part of a slim mouse bottom.

Slim type mouse using the tactile sensor to achieve the object of the present invention is configured by sequentially stacking the load bumper spacer and keypad on the top of the tactile sensor, a plurality of domes are installed on the bottom,

The tactile sensor is formed to face each other on the upper and lower film having a metal layer on the surface opposite to each other, and the opposite surface of each metal layer, the center click portion and the sensing portion formed in a circular shape at the edge of the click portion An upper and lower resistance patterns and spacers formed between the resistance patterns between the metal layers to separate the distances between the resistance patterns,

The load bumper spacer has a click protrusion formed on a portion of the load bumper facing the click portion of the resistance pattern, and a sensing protrusion formed on portions facing the sensing portion, respectively.

The dome is characterized in that the click dome portion is formed in the portion facing the click portion of the resistance pattern, the sensing dome portion is formed in the portion facing the sensing portion.

In the mouse manufacturing method configured as described above, the process of manufacturing the tactile sensor, and the process of laminating the load bumper spacer and the keypad on the upper part of the tactile sensor, the adhesive process,

The process of manufacturing the tactile sensor may include forming metal layers on opposite surfaces of the upper and lower films, respectively; Forming a plurality of upper and lower resistance patterns on the surfaces of the metal layers, respectively; Bonding the spacers between the films on which the resistance patterns are formed so that the upper and lower resistance patterns are stacked in a state spaced apart from each other;

The process of laminating the load bumper spacer and the keypad on the upper part of the tactile sensor may be performed by bonding each protrusion projecting on the bottom surface of the load bumper spacer so as to face the click portion and the sensing portion of the resistance pattern, and then bonding the haptic. It is characterized in that the adhesive to the upper surface of the sensor.

According to the present invention, a mouse can be miniaturized by using a plurality of tactile sensors. Furthermore, a dome is installed on the bottom surface so that the sensing unit and the click unit are supported higher than other portions so that the user can easily recognize it when sensing or clicking. It is effective.

Hereinafter, an example of the present invention will be described in detail with reference to the accompanying drawings in order to help understanding of the present invention.

1 is a plan view of a slim mouse using a tactile sensor of the present invention, Figure 2 is a cross-sectional view showing an example of a slim mouse using a tactile sensor of the present invention, Figure 3 is another of the slim mouse using a tactile sensor of the present invention 4A to 4E are cross-sectional views illustrating a process of manufacturing a tactile sensor according to the present invention.

As shown, the slim type mouse using the tactile sensor according to the present invention is characterized by further comprising domes 4a and 4b on the bottom of the tactile sensor 1.

That is, in the slim type mouse using the tactile sensor according to the present invention, the load bumper spacer 2 and the keypad 3 are sequentially stacked on the upper part of the tactile sensor 1, and a plurality of domes 4a and 4b are disposed below. It is configured by installation.

The tactile sensor 1 is similar to the technology of the patent application formulation 2007-093868 already filed by the applicant as described above, but will be described again as follows.

That is, the tactile sensor 1 provided in the mouse according to the present invention includes the upper and lower films 11 and 12 having the metal layers 11a and 12a on the surfaces facing each other, and the respective metal layers 11a and 12a. It is formed to face each other to face each other, the upper and lower resistance consisting of the sensing portion (13b, 14b) formed in a circular annular shape at the edge of the center click portion (13a, 14a) and the click portion (13a, 14a) The spacers 15 are formed between the patterns 13 and 14 and the resistance patterns 13 and 14 between the metal layers 11a and 12a so that the distances between the resistance patterns 13 and 14 are spaced apart from each other. It consists of.

The films 11 and 12 are coated with thin metal plates 11a and 12a on surfaces facing each other, and the metal layers 11a and 12a are conductive.

That is, it serves to transmit a current signal between the resistance patterns (13, 14).

The resistance patterns 13 and 14 are divided into two parts as shown. That is, the resistance patterns 13 and 14 are formed of click parts 13a and 14a at the center and sensing parts 13b and 14b formed in a circular ring shape on the outside of the click parts 13a and 14a. These are separated from each other, and a spacer 15 is provided between the click parts 13a and 14a and the sensing parts 13b and 14b.

The spacer 15 is a means for forming a gap of a predetermined distance between the opposing surfaces of the resistive patterns 13a and 14a to have a thickness greater than that of the two resistive patterns 13a and 14a. As a result, a gap is formed between the two resistance patterns 13a and 14a.

In the tactile sensor 1 configured as described above, as shown in FIGS. 2 to 4E, the load bumper spacer 2 and the keypad 3 are stacked on the upper portion thereof.

The load bumper spacer 2 is transmitted to the haptic sensor 1 directly when the user touches the keypad 3 to prevent the tactile sensor 1 from being damaged, as well as the keypad 3. As a means for ensuring that the contacting force is well transmitted to the tactile sensor 1 when contacted, a plurality of protrusions 2a and 2b are formed on the bottom as shown.

The protrusions 2a and 2b to be formed in the load bumper spacer 2 correspond to the click portions 13a and 14a and the sensing portions 13b and 14b of the resistance patterns 13 and 14, respectively, as shown. It consists of a click protrusion 2a and a sensing protrusion 2b, the click protrusion 2a is formed in the center, and the sensing protrusion 2b is formed at the edge of the click protrusion 2a.

The keypad 3 is stacked on the load bumper spacer 2.

The keypad 3 also includes a click pad portion 3a facing the click portions 13a and 14a of the resistance patterns 13 and 14 and the sensing portion 13b, like the load bumper spacer 2. 14b) and the sensing pad portion 3b opposite to each other, and the click pad portion 3a and the sensing pad portion 3b may be configured separately from each other or may have different shapes or shapes without being physically separated. Can be distinguished.

The domes 4a and 4b are protrusions provided on the bottom surface of the tactile sensor 1 as described above, and are means for increasing the contact feeling when the keypad 3 is touched.

The dome is divided into two parts, such as the spacer for the load bumper 2 and the keypad 3, and the click dome part 4a is disposed at the portion opposed to the click parts 13a and 14a of the resistance patterns 13 and 14. ) And a portion facing the sensing portions 13b and 14b is composed of a sensing dome portion 4b, the click dome portion 4a is circular, and the sensing dome portion 4b is formed in a circular ring shape.

In addition, the keypad 3 and the load bumper spacer 2 may be separately formed and bonded or may be integrally formed. That is, as shown in FIG. 2, the keypad 3 and the load bumper spacer 2 may be separated and bonded to each other, or may be integrally formed as shown in FIG. 3.

In addition, the keypad 3 may be configured to separate the click pad unit 3a and the sensing pad unit 3b, respectively, and the load bumper spacer 2 also includes the click protrusion unit 2a and the sensing protrusion unit 2b. ) Can be configured separately.

When the click pad part 3a and the sensing pad part 3b, the click protrusion part 2a, and the sensing protrusion part 2b are separated and configured, the respective parts are bonded to each other, and then the corresponding parts on the upper part of the tactile sensor 1 are formed. It is attached to and installed on.

Hereinafter, a slim mouse manufacturing method using the tactile sensor configured as described above will be described.

In the method of manufacturing a slim mouse using a tactile sensor according to the present invention, a process of manufacturing a tactile sensor 1 and a process of laminating a load bumper spacer 2 and a keypad 3 on an upper portion of a tactile sensor 1 Is done.

The process of manufacturing the tactile sensor 1 may include forming metal layers 11a and 12a on opposite surfaces of the upper and lower films 11 and 12, respectively; Forming a plurality of upper and lower resistance patterns (13a, 14a, 13b, 14b) on the surfaces of the metal layers (11a, 12a), respectively; Bonding the spacers 15 between the films 11 and 12 on which the resistance patterns are formed so that upper and lower resistance patterns are stacked in a state in which the resistance patterns are spaced apart from each other. The process of laminating and attaching 3 to the upper part of the tactile sensor 1 includes the protrusions 2a and 2b protruding from the bottom surface of the load bumper spacer to the click parts 13a and 14a and the sensing part of the resistance pattern. 13b and 14b), and then bonded to each other and bonded to the upper surface of the tactile sensor 1.

In the mouse manufacturing process

The forming of the metal layers 11a and 12a on the upper and lower films 11 and 12 is performed by depositing metal powder on the surfaces of the films 11 and 12 and depositing the metal powder on the films 11 and 12. The method may use a sputtering method or the like, but other methods may be performed, and detailed description thereof will be omitted.

The method of forming the resistance patterns 13 and 14 may also be variously modified, but preferably, a pressure-sensitive ink coating method or a resistance material coating method may be used.

The method of adhering the upper and lower films 11 and 12 formed to the resistance patterns 13 and 14 to each other may be performed by applying or covering an adhesive or an adhesive tape on both sides of the spacer 15 and then adhering to each other.

The method of stacking the load bumper spacer 2 and the keypad 3 on the upper surface of the tactile sensor 1 made as described above may also be made by using an adhesive or adhesive tape, and the keypad 3 and the load bumper. When the spacer 2 is integrally formed, the process can be simplified by bonding only between the bottom surface of the load bumper spacer 2 and the top surface of the tactile sensor 1.

However, when the load bumper spacer 2 and the keypad 3 are integrally formed in this way, it is somewhat difficult to form the protrusions 2a and 2b formed on the bottom surface of the load bumper spacer 2 and thus the protrusions 2a, Since the exposed portion of the keypad 3 may be damaged in the process of forming 2b), the keypad 3 and the load pump spacer 2 may be manufactured separately from each other, and may be integrated by bonding opposite surfaces to each other. .

In addition, the click protrusion portion 2a and the sensing protrusion portion 2b of the load bumper spacer 2 are separately configured so that any part that may be generated when the click protrusion portion 2a and the sensing protrusion portion 2b are connected to each other. When pressing, it is possible to solve the problem that other parts work together, and when configured in this way, each of the protrusions 2a and 2b is bonded by bonding (bonding) to a corresponding position on the upper part of the upper film 11 of the tactile sensor 1. do.

In addition, in the case of the keypad 3, the click pad part 3a facing the click parts 13a and 14a of the resistance patterns 13 and 14 by separating like the load bumper spacer 2 and the sensing The sensing pad portions 3b opposed to the portions 13b and 14b are separated from each other, and the separated pad portions 3a and 3b are bonded to the upper portion of the load bumper spacer 2. Can be combined.

Meanwhile, a mouse may be manufactured using a capacitive tactile sensor using only upper and lower metal layers 11a and 12a without using the upper and lower resistance patterns 13 and 14.

1 is a plan view of a slim mouse using the tactile sensor of the present invention,

Figure 2 is a cross-sectional view showing an example of a slim mouse using the tactile sensor of the present invention,

Figure 3 is a cross-sectional view showing another example of a slim mouse using the tactile sensor of the present invention,

4A to 4E are cross-sectional views illustrating a process of manufacturing the tactile sensor of the present invention.

<Description of the symbols for the main parts of the drawings>

1: tactile sensor

11: top film

  11a, 12a: metal layer

12: lower film

13: upper resistance pattern 13a, 14a: click part 13b, 14b: sensing part

14: lower resistance pattern

15: spacer

2: Load bumper spacer 2a: Click protrusion 2b: Sensing protrusion

3: keypad 3a: click pad portion 3b: sensing pad portion

                          4a: click dome part 4b: sensing dome part

Claims (12)

In the upper part of the tactile sensor 1, the load bumper spacer 2 and the keypad 3 are sequentially stacked, and a plurality of domes 4a and 4b are installed in the lower part. The tactile sensor 1 includes upper and lower films 11 and 12 having metal layers 11a and 12a on surfaces facing each other, The metal layers 11a and 12a of the metal layers 11a and 12a face each other to face each other, and the sensing parts 13b formed in a circular shape at the edges of the central click parts 13a and 14a and the click parts 13a and 14a. The distance between the resistance patterns 13 and 14 formed between the upper and lower resistance patterns 13 and 14 and the resistance patterns 13 and 14 between the metal layers 11a and 12a. Is composed of a spacer 15 so that The load bumper spacer 2 has a click protruding portion 2a formed at a portion of the load bumper spacer 2 facing the click portions 13a and 14a of the resistance patterns 13 and 14, and the sensing portions 13b and 14b. Sensing protrusions 2b are formed at portions facing each other, The dome 4a and 4b is formed with a click dome portion 4a at a portion of the resistance patterns 13 and 14 facing the click portions 13a and 14a, and at a portion opposite to the sensing portions 13b and 14b. Slim mouse using the tactile sensor, characterized in that the sensing dome portion (4b) is formed. The method of claim 1, The keypad 3 includes a click pad part 3a facing the click parts 13a and 14a of the resistance patterns 13 and 14 and a sensing pad part 3b facing the sensing parts 13b and 14b. Slim mouse using the tactile sensor, characterized in that each is configured separately. The method according to claim 1 or 2, Slim mouse using the capacitive tactile sensor without using the upper and lower resistance patterns (13, 14). The method of claim 3, wherein The keypad (3) and the load bumper spacer (2) is a slim type mouse using a tactile sensor, characterized in that the adhesive is configured to separate each. The method of claim 3, wherein Slim keypad using the tactile sensor, characterized in that the keypad (3) and the load bumper spacer (2) is configured integrally. The method of claim 5, wherein Click protrusion (2a) and the sensing protrusion (2b) of the load bumper spacer (2) is a slim type mouse using a tactile sensor, characterized in that each configured separately. The upper part of the tactile sensor 1 is configured by sequentially stacking the spacers 2 and the keypad 3 for the load bumper, and installing a plurality of domes 4a and 4b in the lower part of the tactile sensor 1. The upper and lower films 11 and 12 having the metal layers 11a and 12a on opposite surfaces are formed so as to face each other on opposite surfaces of the metal layers 11a and 12a. , Upper and lower resistance patterns 13 and 14 formed of circular sensing elements 13b and 14b formed at the edges of the click parts 13a and 14a and the metal layers 11a and 12a. The spacers 15 are formed between the patterns 13 and 14 so that the distances between the resistance patterns 13 and 14 are spaced apart from each other, and the load bumper spacer 2 has a bottom surface of the resistance pattern ( Click protrusions 2a are formed at portions facing the click portions 13a and 14a of 13 and 14, and sensing stones are respectively opposed to the sensing portions 13b and 14b. An outlet portion 2b is formed, and the dome has a click dome portion 4a formed at a portion of the resistance patterns 13 and 14 that opposes the click portions 13a and 14a, and the sensing portions 13b and 14b. In the mouse manufacturing method in which the sensing dome portion 4b is formed on the opposite portion, The process of manufacturing the tactile sensor (1), and the process of laminating and bonding the load bumper spacer (2) and the keypad (3) on top of the tactile sensor (1), The process of manufacturing the tactile sensor 1 may include forming metal layers 11a and 12a on opposite surfaces of the upper and lower films 11 and 12, respectively; Forming a plurality of upper and lower resistance patterns (13a, 14a, 13b, 14b) on the surfaces of the metal layers (11a, 12a), respectively; Bonding the spacers 15 between the films 11 and 12 on which the resistance patterns are formed so that the upper and lower resistance patterns are stacked in a state spaced apart from each other, The process of stacking and attaching the load bumper spacer 2 and the keypad 3 to the upper part of the tactile sensor 1 includes the protrusions 2a and 2b protruding from the bottom surface of the load bumper spacer. Method of manufacturing a slim mouse using a tactile sensor, characterized in that after facing each of the portion (13a, 14a) and the sensing unit (13b, 14b), and bonded to the upper surface of the tactile sensor (1). The method of claim 7, wherein Method of manufacturing a slim mouse using a capacitive tactile sensor without using the upper and lower resistance patterns (13, 14). The method according to claim 7 or 8, The click protrusions 2a and the sensing protrusions 2b of the load bumper spacer 2 are separately configured, and bonding the protrusions 2a and 2b to the upper portion of the upper film 11 of the tactile sensor 1. Slim type mouse manufacturing method using a tactile sensor characterized in that (bonding). The method of claim 9, The keypad 3 includes a click pad part 3a facing the click parts 13a and 14a of the resistance patterns 13 and 14 and a sensing pad part 3b facing the sensing parts 13b and 14b. Are separated and configured, and each of the separated pad parts (3a, 3b) is bonded to the upper portion of the load bumper spacer (2) by bonding (bonding), characterized in that the slim mouse manufacturing method using a tactile sensor. The method of claim 10, Slim keypad manufacturing method using the tactile sensor, characterized in that the keypad (3) and the load bumper spacer (2) is formed integrally. The method of claim 10, The keypad (3) and the load pump spacers (2) are manufactured separately from each other, a slim mouse manufacturing method using a tactile sensor, characterized in that the bonding by bonding the surfaces facing each other.

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