TWM565337U - Partitioned mouse pad - Google Patents

Abstract

A partitioned mouse pad adapted to a mouse includes a mouse pad body and a plurality of raised structure group. The mouse pad body has a plurality of operating regions. The raised structure groups respectively correspondingly protrude from the operation area, each of the raised structure groups includes a plurality of raised structures distributed according to a sequence of lines, and the raised sizes of the raised structure groups are different from each other. A surface roughness of the operating area is different from each other. Wherein, the surface roughness is different from each other, so that a sliding resistance generated by a user moving the mouse over the operation areas is different from each other.

Description

Partitioned mouse pad

This creation is about a mouse pad, especially a zoned mouse pad.

Normally, the mouse will operate on the mouse pad. Since the existing mouse pad uses a whole piece of cloth as the sliding operation surface of the mouse, it can only provide the user with a fixed sliding speed when operating the mouse. . However, the existing users are more and more widely used in the operation of the computer, and the mouse pad which can only provide the basic operation feel can not meet the needs of the user.

The present invention provides a partitioned mouse pad suitable for use with a mouse, including a mouse pad body and a plurality of raised structure groups. The mouse pad system has a plurality of operation regions; a plurality of convex structure groups respectively correspondingly protrude from the operation regions, and each of the convex structure groups comprises a plurality of convex structures distributed according to an arrangement of lines, And the protrusion sizes of the raised structure groups are different from each other, so that the surface roughness of the operation regions are different from each other; wherein the surface roughness is different from each other The slip resistance generated by a user moving the mouse over the operating areas is different from each other.

As described above, the partitioned mouse pad of the present invention divides the operation surface of the mouse pad into a plurality of operation areas, and each operation area can generate a difference in surface roughness by the convex size of the convex structure group. When the user moves the mouse to each operation area, the difference in the sliding speed in different directions may be generated due to the difference in the roughness of the different operation areas, so that the user can switch the slide by operating the mouse in different operation areas. The operation performance of the mouse effectively enhances the convenience and functionality of use.

The specific embodiments used in the present application will be further illustrated by the following examples and drawings.

100‧‧‧ District mouse pad

1‧‧‧Mouse pad body

2‧‧‧Operation layer

21, 22‧‧‧ first silk thread

23, 24‧‧‧Second silk thread

25‧‧‧ convex structure group

251‧‧‧First raised structure

252‧‧‧second raised structure

26‧‧‧ convex structure

3‧‧‧Induction chip

4‧‧‧Induction chip

200‧‧‧ Mouse

R1‧‧‧ first operating area

R2‧‧‧Second operating area

R3‧‧‧ third operating area

D1‧‧‧ first direction

D2‧‧‧ second direction

L1‧‧‧ wire diameter

L2‧‧‧ wire diameter

100a‧‧‧Partial mouse pad

1a‧‧‧Mouse pad body

2a‧‧‧Operation layer

21a‧‧‧First silk thread

211a‧‧‧First raised structure

22a‧‧‧Second silk thread

221a‧‧‧second raised structure

100b‧‧‧Partial mouse pad

1b‧‧‧Mouse pad body

2a‧‧‧Operation layer

21b, 23b‧‧‧ first thread

22b, 24b‧‧‧second thread

D3‧‧‧First direction

D4‧‧‧ second direction

D5‧‧‧ first direction

D6‧‧‧ second direction

R4, R5‧‧‧ operating area

100c‧‧‧Partial mouse pad

1c‧‧‧Mouse pad body

2c‧‧‧ operation layer

21c‧‧‧first thread

22c‧‧‧second thread

The first figure shows a schematic plan view of the partitioned mouse pad provided by the first preferred embodiment of the present invention; the second figure shows an enlarged schematic view of the first picture circle A; and the third figure shows the partitioned mouse of the present creation. A plan view of the pad in the second operating area; the fourth figure shows a schematic view of the partitioned mouse pad of the mouse created in the second operating area; the fifth figure shows the partial sliding of the mouse A schematic plan view of the mouse pad moving rapidly in the second operation area; the sixth figure is shown in the second preferred embodiment of the present invention, the mouse is lightly pressed against the operation FIG. 7 is a plan view showing a plane in which the mouse is pressed against the operation surface in the second preferred embodiment of the present invention; and the eighth diagram shows the partition provided by the third preferred embodiment of the present creation. A schematic plan view of a mouse pad provided in the fourth preferred embodiment of the present invention; and a tenth view showing a fourth preferred embodiment of the present invention. A schematic plan view of another perspective of the partitioned mouse pad.

The specific implementation of the present creation will be described in more detail below with reference to the schematic drawings. The advantages and features of the present invention will be more apparent from the following description and claims. It should be noted that the drawings are in a very simplified form and all use non-precise proportions, and are only used to facilitate and clearly explain the purpose of the present embodiment.

Please refer to the first figure. The first figure shows a schematic plan view of the partitioned mouse pad provided by the first preferred embodiment of the present invention. As shown, a zoned mouse pad 100 includes a mouse pad body 1, an operating layer 2, a sensing wafer 3, and a sensing wafer 4.

The mouse pad body 1 has three operation regions (including a first operation region R1, a second operation region R2, and a third operation region R3). The operation layer 2 is provided on the mouse pad body 1. The sensing chip 3 is embedded in the mouse pad body 1 in the first operating region R1, and the sensing chip 4 is The second operation area R2 is embedded in the mouse pad body 1, and the third operation area R3 is a wrist placement area in this embodiment.

In this embodiment, the sensing chip 3 and the sensing chip 4 comprise a Near Field Communication sensor chip or a Radio Frequency Identification (DRAM) chip for a mouse 200 (labeled in the fourth figure). Inductively, when the mouse 200 senses the sensing chip 3, the computer system can correct the moving signal of the mouse 200 in the first operating area R1 according to the information of the sensing chip 3; similarly, when the mouse 200 senses the sensing At the time of the wafer 4, the computer system can correct the movement signal of the mouse 200 in the second operation area R2 according to the information of the sensing chip 4.

Please continue to refer to the second figure, which is an enlarged schematic view of the first circle A. As shown in the figure, the operation layer 2 of the first figure is interlaced by a plurality of wires, and in the embodiment, the plurality of wires comprise a plurality of first wires 21 and 22 (only two are shown) A plurality of second wires 23 and 24 (only two are shown). The first wires 21 and 22 extend in a first direction D1, and the second wires 23 and 24 extend in a second direction D2 perpendicular to the first direction D1, whereby the first wires 21 and 22 and the second wires are made. 23 and 24 are interlaced and a plurality of raised structure groups 25 (only one is shown); wherein the raised structure group 25 comprises a plurality of raised structures, and in the embodiment, the plurality of raised structures comprise a plurality of The first raised structure 251 (only one is shown in the figure, that is, the protrusion where the first wire 21 overlaps the second wire 23) and the plurality of second raised structures 252 (only one is shown in the figure, that is, the second The wires 23 overlap at the protrusions of the first wire 22).

According to the above, in the first direction D1 is perpendicular to the second direction In the case of D2, the first raised structure 251 and the second raised structure 252 are distributed according to the orthogonal arrangement of the lines, and since the first wires 21 and 22 have a wire diameter L1, and the second wires 23 and 24 have one The wire diameter L2 is smaller than the wire diameter L1. Therefore, the width of the first protrusion structure 251 formed by the protrusions of the first wires 21 and 22 is larger than the width of the second protrusion structure 252 formed by the second wires 23 and 24. So that the operation layer 2 in the first operation region R1 generates different surface roughness between the first direction D1 and the second direction D2, and when the user moves the mouse 200 on the convex structure group 25, along the first The slip resistance of the movement in the direction D1 is smaller than the slip resistance in the second direction D2, whereby the user can quickly move the mouse 200 in the first direction D1 and slow down the movement speed in the second direction D2. In addition, the degree of linearity when the mouse 200 moves in the first direction D1 or the second direction D2 can be increased.

Please continue to refer to the third to fifth figures. The third figure shows the plan view of the partitioned mouse pad of the present invention in the second operation area; the fourth picture shows the partitioned mouse pad of the mouse creation. A schematic plan view of the slow movement in the second operation area; the fifth figure shows a schematic diagram of the rapid movement of the partitioned mouse pad of the mouse in the second operation area.

As shown, the operating layer 2 is comprised of a plurality of resilient raised structures 26 (only one of which is shown) in the second operating region R2. In this embodiment, the resilient raised structures 26 are for example It is a short fiber of elastic fiber.

Wherein, when the user operates the mouse 200 to slowly move at a first speed on the elastic convex structure 26 as shown in the fourth figure, the elastic convex structure 26 may be subjected to deformation. Feedback The mouse 200 has a large reaction force; and when the user operates the mouse 200 as shown in FIG. 5 on the elastic convex structure 26, it moves at a second speed greater than the first speed, and has elasticity. The raised structure 26 will feed back the smaller reaction force of the mouse 200 because of the small extent of the deformation.

As described above, when the user slowly moves the mouse 200 for a more precise operation, the sliding speed of the mouse 200 can be increased by the elastic convex structure 26, thereby increasing the user's slow movement of the mouse 200. The stability of the time, thereby increasing the accuracy of the control; however, when the user wants to move the cursor quickly and move the mouse 200 quickly, the user controls the force of the mouse 200 to be applied to the elastic raised structure 26 It will be relatively small, so that the sliding speed of the resilient convex structure 26 fed back to the mouse 200 is also small; thereby, the user can flexibly control the movement of the mouse 200 in the second operating region R2. The raised structure 26 increases the control precision at the time of slow speed, and can reduce the sliding speed when the mouse 200 is quickly moved, thereby effectively improving the convenience of use.

Please refer to the sixth and seventh figures. The sixth figure shows a schematic diagram of the mouse in the second preferred embodiment of the present invention, the mouse is lightly pressed on the operation layer; the seventh figure is shown in the second preferred embodiment of the present invention. In the embodiment, the mouse is heavily pressed against the planar view of the operating layer.

As shown, the one-part mouse pad 100a has a mouse pad body 1a and an operation layer 2a, and the operation layer 2a includes a plurality of first wires 21a (only one is shown) and a plurality of second wires 22a. (only one is shown in the figure). The first wire 21a has a plurality of first protruding structures 211a (only one is shown), and the second wire 22a has a plurality of second protruding structures 221a (only one is shown), and the first protruding structure 211a of the first wire 21a and the second protruding structure 221a of the second wire 22a are arranged alternately in a staggered manner, whereby when the user is in the operation layer 2a When the mouse 200 is gently pressed to move in the first direction D1, the sliding speed of the mouse 200 is only from the frictional force of the mouse 200 contacting the first wire 21a; and when the user is heavily pressed on the operating layer 2a When the mouse 200 moves in the first direction D1, the mouse 200 presses the first convex structure 211a of the first wire 21a due to the heavy pressure, and simultaneously contacts the first convex structure 211a of the first wire 21a and The second raised structure 221a of the second wire 22a, which in turn causes the sliding speed of the mouse 200 to move in the first direction D1, simultaneously comes from the frictional force contacting the first raised structure 211a and the second raised structure 221a. Thereby, when the user needs a better sliding speed to increase the control precision of the mouse 200, the sliding speed of the mouse 200 can be changed by the heavy pressure.

Please refer to the eighth figure, which is a schematic plan view of the partitioned mouse pad provided by the third preferred embodiment of the present invention. As shown, a zoned mouse pad 100b includes a mouse pad body 1b and an operating layer 2b, and the mouse pad body 1b has two operating regions R4 and R5.

The operation layer 2b in the operation region R4 is formed by interlacing a plurality of first wires 21b (only one is shown) and a plurality of second wires 22b (only one is shown), and the first wires 21b are interwoven. The second wire 22b extends in a second direction D4 perpendicular to the first direction D3, and in the embodiment, the first direction D3 is a bending direction, thereby making the first wire 21b a plurality of convex structures formed by interlacing with the second wire 22b (not shown, corresponding to the above-mentioned convex structure 251 and 252) Arranging the texture distribution along the curved curve; thereby, it is more stable when the user performs the arcuate movement in the first direction D3 on the operation layer 2b.

In addition, the operation layer 2b in the operation region R5 is formed by interlacing a plurality of first wires 23b (only one is shown) with a plurality of second wires 24b (only one is shown), and the first wire 23b The first wire is stretched along a first direction D5, and the second wire 24b extends in a second direction D6 perpendicular to the first direction D5. In the embodiment, the first direction D5 is an S-curve direction, thereby making the first wire A plurality of convex structures (not shown, corresponding to the above-mentioned convex structures 251 and 252) formed by interlacing 23b and the second wire 24b are distributed along an irregular curve; thereby, when the user is in the operation layer 2b It is more stable when the S-curve movement is performed in the first direction D5.

Please refer to the ninth and tenth drawings. The ninth figure shows a plan view of the partitioned mouse pad provided by the fourth preferred embodiment of the present invention. The tenth figure shows the fourth preferred embodiment of the present invention. A schematic plan view of another perspective view of the partitioned mouse pad.

As shown, the one-part mouse pad 100c has a mouse pad body 1c and an operation layer 2c, and the mouse pad body 1c is composed of a plurality of first wires 21c (only one is shown) and a plurality of Two wires 22c (only one is shown) are arranged, wherein the second wire 22c is a reflective wire with a higher reflectivity, and the second wire 22c is arranged in a bar code as shown in the tenth figure; Therefore, when the user controls the mouse 200 to sweep the bar code pattern arranged by the second wire 22c at the operation layer 2c, the mouse 200 can analyze the bar code texture to obtain corresponding information.

In summary, compared to the prior art mouse pad can only Providing a single sliding speed operation surface, the partitioned mouse pad of the present invention divides the operation surface of the mouse pad into a plurality of operation areas, and each operation area can generate surface roughness by a plurality of convex structure groups. The difference causes the user to move the mouse to each operating area, and the sliding speed difference in different directions can be generated due to the difference in surface roughness of different operating areas, so that the user can operate the mouse through different operating areas. Switching the operation performance of the mouse, effectively improving the convenience and functionality of use.

The features and spirit of the present invention are more clearly described in the above detailed description of the preferred embodiments, and the scope of the present invention is not limited by the preferred embodiments disclosed herein. On the contrary, it is intended to cover all kinds of changes and equivalences within the scope of the patent application to which the present invention is intended.

Claims (10)

A partitioned mouse pad suitable for use with a mouse, comprising: a mouse pad body having a plurality of operation regions; and a plurality of raised structure groups respectively correspondingly protruding from the operation regions Each of the raised structure groups includes a plurality of raised structures distributed according to a distribution pattern, and the protrusion sizes of the raised structure groups are different from each other, so that the surface roughness of the operation regions are mutually Wherein, the surface roughnesses are different from each other such that a sliding resistance generated by a user moving the mouse over the operating regions is different from each other. The partitioned mouse pad according to claim 1, wherein the raised structures are formed by overlapping a plurality of wires, and the wires are tied to one of the operation regions. The regions are respectively interlaced in a first direction and a second direction. The zoned mouse pad of claim 2, wherein the wires are respectively in a third operating direction and a fourth direction in one of the second operating regions Interlaced, and the third direction is different from the first direction and the second direction. The partitioned mouse pad of claim 2, wherein the first direction is perpendicular to the second direction, and the wires comprise a plurality of first wires and a plurality of second wires, a thread And extending along the first direction, the second wires are respectively extended along the second direction, and the wire diameters of the first wires are larger than the wire diameters of the second wires. The zoned mouse pad of claim 2, wherein the wires comprise a plurality of first wires and a plurality of second wires, and in the first operating region, the first wires are respectively along The first direction extends, and the second wires extend in the second direction respectively. The partitioned mouse pad of claim 2, wherein the wires further comprise a reflective wire, the reflective wire being woven to form a coded path. The partitioned mouse pad of claim 1, wherein the raised structures are elastic structures. The zoned mouse pad of claim 1, further comprising a plurality of sensor chips embedded in the operation areas. The zoned mouse pad of claim 8, wherein the sensor chip comprises a near field communication sensor chip or a radio frequency identification (Radio Frequency Identification) chip. The partitioned mouse pad of claim 1, wherein one of the operation areas is a wrist placement area.