CN113495636A

CN113495636A - Mouse device capable of zero-gap switching feedback elasticity

Info

Publication number: CN113495636A
Application number: CN202010200162.5A
Authority: CN
Inventors: 邱忆宁
Original assignee: Kessel Memory Co ltd
Current assignee: Kessel Memory Co ltd
Priority date: 2020-03-20
Filing date: 2020-03-20
Publication date: 2021-10-12

Abstract

The invention discloses a mouse device capable of switching feedback elasticity in a zero-clearance mode. The shell unit comprises a shell surrounding and defining an accommodating space. The pressing unit is connected with the shell unit and comprises a pressing body and an extending body. The switch unit is in contact with the pressing unit and comprises a switch module. The adjusting unit comprises an adjusting seat body and a first elastic body. The adjusting seat body can move between a first position and a second position. When the adjusting seat is at the first position, the first elastic body applies a force to the extending body in a direction towards the switch module. When the adjusting seat body is at the second position, the first elastic body applies a force opposite to the direction of the switch module to the extending body.

Description

Mouse device capable of zero-gap switching feedback elasticity

Technical Field

The invention relates to a mouse device capable of adjusting feedback elasticity, in particular to a mouse device capable of switching the feedback elasticity at zero clearance.

Background

A typical mouse has left and right pressing plates for respectively pressing down a microswitch and outputting a control command to a computer device. Wherein, the microswitch is provided with an elastic component, so that the microswitch has feedback elasticity and restores the initial state. The pressing force of the user is larger than the elastic force of the elastic component, so that the microswitch can be pressed down and a control instruction can be output.

The conventional mouse has the following disadvantages in practical use:

firstly, the elasticity cannot be changed:

the pressing force output by the user is larger than the feedback elastic force of the elastic component in the microswitch, the microswitch can be pressed down and a control instruction is output, and the elastic component arranged in the microswitch cannot be replaced easily, so that the feedback elastic force cannot be changed by a common mouse.

Secondly, the instruction output time is longer:

the pressing plate and the microswitch of a common mouse are spaced by a certain distance, so the moving stroke for triggering the microswitch is long, the pressing plate is firstly pressed down to be in contact with the microswitch when the mouse is pressed, and then the microswitch is pressed down to output an instruction, so the time for outputting a control instruction by the common mouse is long.

Thirdly, poor click feeling:

as mentioned above, the pressing plate and the micro switch of a conventional mouse are spaced apart from each other by a certain distance, and when the elastic force of the elastic member in the micro switch is too light, the user cannot feel the movement stroke of the pressing and the jerking of the micro switch, which results in poor clicking feeling of the pressing mouse.

Therefore, it is an urgent need to provide an effort to contact the pressing plate with the micro switch, to quickly adjust the feedback elastic force of the micro switch in the mouse, and to increase the click feeling of pressing the mouse.

Disclosure of Invention

In view of the above, an object of the present invention is to provide a mouse device capable of switching feedback elastic force with zero gap, which includes a housing unit, at least one pressing unit, at least one switch unit, and at least one adjusting unit.

The shell unit comprises a shell surrounding and defining an accommodating space.

The pressing unit is connected with the shell unit and comprises a pressing body and an extending body connected with the pressing body.

The switch unit is contacted with the pressing unit and comprises a switch module arranged in the accommodating space.

The adjusting unit comprises an adjusting seat body arranged in the accommodating space and a first elastic body arranged on the adjusting seat body and extending to the extending body, the adjusting seat body can move between a first position and a second position, when the adjusting seat body is at the first position, the first elastic body applies force towards the direction of the switch module to the extending body, and when the adjusting seat body is at the second position, the first elastic body applies force opposite to the direction of the switch module to the extending body.

Another technical means of the present invention is that the adjusting unit further includes a fixed base connected to the housing, a fixing hole disposed in the fixed base, a guiding groove disposed in the fixed base, a protruding body disposed in the adjusting base and combined with the fixing hole, and an adjusting rod disposed in the adjusting base and passing through the guiding groove, wherein the adjusting rod can move in the guiding groove, so that the adjusting base can move relative to the fixed base.

Another technical means of the present invention is that the housing unit further includes an adjustment hole disposed in the housing, and the adjustment rod penetrates through the adjustment hole.

The other technical means of the invention is that the shape of the through hole of the adjusting hole of the shell unit is in a reverse L shape, and the shape of the groove of the guiding groove corresponds to the shape of the through hole of the adjusting hole.

The present invention further provides a method for adjusting a position of a base of a housing unit, the housing unit further includes a first supporting wall disposed at a bottom side of the adjusting hole and disposed on the housing, and a second supporting wall disposed at the adjusting hole and spaced apart from the first supporting wall, wherein the first supporting wall is used to support the adjusting rod and maintain the adjusting base at the first position, and the second supporting wall is used to support the adjusting rod and maintain the adjusting base at the second position.

Another technical means of the present invention is that the adjusting unit further includes a second elastic body disposed between the adjusting base and the fixing base, and the second elastic body is used to push the adjusting base from the second position to the first position.

The present invention also provides a technical means that the adjusting unit further includes a screw hole disposed on the adjusting seat body, a round convex body disposed on the adjusting seat body and located outside the screw hole, a stud combined with the screw hole, and a disc body disposed on the stud, the first elastic body is disposed outside the round convex body and protrudes outward from the adjusting seat body, and the stud and the screw hole are combined to enable the disc body to be matched with the adjusting seat body to fix the first elastic body.

In another aspect of the present invention, the housing unit further includes an extending through hole disposed in the housing, and the extending body is disposed through the extending through hole.

Another technical means of the present invention is that the pressing unit further includes a first blocking wall disposed on the extending body, and a second blocking wall disposed on the extending body, wherein a distance between the first blocking wall and the pressing body is greater than a distance between the second blocking wall and the pressing body.

Another technical means of the present invention is that the pressing unit further includes a pressing wall disposed on the extending body, and the pressing wall contacts with the switch module.

The invention has the beneficial effect that the adjusting seat body can be rapidly switched to the first position or the second position through the Gamma-shaped adjusting hole. When the adjusting seat body is at the first position, the first elastic body is in contact with the first blocking wall and applies a downward force towards the switch module to the first blocking wall so as to reduce the feedback elastic force of the switch module. When the adjusting seat body is at the second position, the first elastic body is in contact with the second retaining wall and applies upward pressure to the second retaining wall in the direction opposite to the direction of the switch module so as to increase the feedback elastic force of the switch module. The pressing wall of the pressing unit is contacted with the switch module and is not separated no matter the adjusting seat body is at the first position or the second position.

Drawings

Fig. 1 is a schematic perspective view illustrating a perspective view of a mouse device capable of switching feedback elastic force with zero gap according to an embodiment of the present invention;

FIG. 2 is an exploded view illustrating an exploded view of a pressing unit, a housing unit, and an adjusting unit in the embodiment;

fig. 3 is a perspective view illustrating a perspective view of the pressing unit, the housing unit, and the adjusting unit in the embodiment;

FIG. 4 is an exploded view illustrating an exploded view of the adjustment unit in the embodiment;

FIG. 5 is a perspective view illustrating a perspective view of the adjustment unit in the embodiment;

FIG. 6 is a side view schematically illustrating a side view of an adjustment rod of the mouse device passing through an adjustment hole and located at a first position in the embodiment;

FIG. 7 is a partial side view illustrating a partial side view of the adjustment rod body passing through the adjustment hole and located at the first position in the embodiment;

FIG. 8 is a partial side sectional view illustrating a partial side sectional view of the pressing unit, the housing unit, the adjusting unit, and a switch unit in the embodiment;

FIG. 9 is a partial side view of the adjusting unit in the first position and supported against a first blocking wall of the housing unit, which is an enlarged view of a frame line A in FIG. 8;

FIG. 10 is a partial bottom view of the mouse device shown in FIG. 8, illustrating a partial bottom view of the housing unit, the adjustment unit, and the switch unit on the right side of the mouse device;

FIG. 11 is a schematic side view illustrating a side view of the mouse device with the adjustment rod passing through the adjustment hole and located at a second position in the embodiment;

FIG. 12 is a partial side view illustrating the adjustment rod body passing through the adjustment hole and being in the second position in the embodiment;

fig. 13 is a partial side sectional view schematically illustrating a partial side sectional view of the pressing unit, the housing unit, the adjusting unit, and the switch unit in the embodiment;

FIG. 14 is a partial side view of the adjustment unit in the second position and supported against a second stop wall of the housing unit, as enlarged from line B of FIG. 13;

FIG. 15 is a partial bottom view of the mouse device of FIG. 13 showing a partial bottom view of the housing unit, the adjustment unit, and the switch unit on the right side of the mouse device;

FIG. 16 is an analysis chart illustrating the feedback elastic force and the movement stroke of a conventional mouse button; and

fig. 17 is an analysis chart illustrating the feedback elastic force and the moving stroke of the embodiment.

Symbolic illustration in the drawings:

a, a frame line;

b, a frame line;

3 a housing unit;

301 an accommodating space;

302 a housing;

303 an adjustment hole;

304 a first support wall;

305 a second support wall;

306 extending the perforation;

4 a pressing unit;

401 a pressing body;

402 an extension;

403 a first retaining wall;

404 a second retaining wall;

405 pressing on the wall;

5 a switch unit;

501, a switch module;

6 an adjusting unit;

601 adjusting the base;

602 a first elastomeric body;

603 fixing the base;

604 fixing holes;

605 a guide groove;

606, a protruding body;

607 adjusting the rod body;

608 a second elastomeric body;

609 a screw hole;

610 a round convex body;

611 stud;

612 a circular disk body;

613 screws;

7 a base unit;

an X fold line;

a Y fold line;

a Z-fold line;

801 longitudinal axis;

the 802 horizontal axis;

811 horizontal axis;

812 longitudinal axis.

Detailed Description

Features and aspects of the present invention will become apparent from the following detailed description of an embodiment thereof, which is to be read in connection with the accompanying drawings.

Referring to fig. 1, 2 and 3, an embodiment of a mouse device capable of switching feedback elastic force with zero gap according to the present invention includes a housing unit 3, at least one pressing unit 4, at least one switch unit 5 (see fig. 8, 9, 10, 13 and 14), at least one adjusting unit 6, and a base unit 7. The switch unit 5 is fixed on the base unit 7, the housing unit 3 is disposed on the base unit 7 and combined together, the pressing unit 4 is disposed on the housing unit 3, and the adjusting unit 6 is fixed in the housing unit 3.

In this embodiment, the pressing unit 4, the switch unit 5 (please refer to fig. 8, 9, 10, 13, and 14), and the adjusting unit 6 are disposed on the right button of the mouse device, and in practical implementation, the pressing unit 4, the switch unit 5 (please refer to fig. 8, 9, 10, 13, and 14), and the adjusting unit 6 may also be disposed on the left button of the mouse device, or both the left button and the right button may be disposed, which should not be limited thereto.

The housing unit 3 includes a housing 302 surrounding and defining an accommodating space 301, an adjusting hole 303 disposed in the housing 302, a first supporting wall 304 (see fig. 7 and 12) disposed on the housing 302 and located at a bottom side of the adjusting hole 303, a second supporting wall 305 (see fig. 7 and 12) disposed on the housing 302 and located in the adjusting hole 303 and spaced apart from the first supporting wall 304, and an extending through hole 306 disposed in the housing 302. In this embodiment, the shape of the through hole 303 of the housing unit 3 is generally of a Γ shape, and in practical implementation, the shape of the through hole 303 may be other shapes, which should not be limited thereto.

The pressing unit 4 is disposed above the housing unit 3, and in fig. 2, the housing unit 3 and the pressing unit 4 are exploded perspective views after being turned over. The pressing unit 4 includes a pressing body 401, an extending body 402 connected to the pressing body 401, a first blocking wall 403 disposed on the extending body 402, a second blocking wall 404 disposed on the extending body 402, and a pressing wall 405 disposed on the extending body 402. Preferably, the pressing body 401 is disposed above the housing 302, and the extending body 402 protrudes from the lower surface of the pressing body 401 and passes through the extending through hole 306 to enter the accommodating space 301, so that the first elastic body 602 can abut against the first retaining wall 403 or the second retaining wall 404 disposed at the side of the extension body 402, the pressing wall 405 is disposed at the bottom end of the extension 402 and contacts the switch module 501 (see fig. 8, 9, 13, and 14), the distance between the first blocking wall 403 and the pressing body 401 is greater than the distance between the second blocking wall 404 and the pressing body 401 (see FIGS. 8, 9, 13, and 14), the first blocking wall 403 is closer to the switch module 501 than the second blocking wall 404 (see fig. 8, 9, 13, and 14), the first blocking wall 403 faces the pressing body 401, and the second blocking wall 404 faces the switch unit 5 (see fig. 9 and 14). In the embodiment, the first blocking wall 403 and the second blocking wall 404 are disposed at the side of the extension 402, and in practical implementation, the first blocking wall 403 and the second blocking wall 404 are disposed in the extension 402, which should not be limited thereto.

Referring to fig. 8 and 9, the switch unit 5 contacts the pressing wall 405 of the pressing unit 4 and includes a switch module 501 disposed in the accommodating space 301. The switch module 501 of the switch unit 5 is disposed on the base unit 7 (not shown in the drawings), and the switch module 501 is a micro switch commonly disposed in a mouse, and since a switch assembly is disposed on a base, it is a commonly used technology, and is not described in detail herein.

Referring to fig. 2, 3, 4 and 5, the adjusting unit 6 includes an adjusting base 601 disposed in the accommodating space 301, a first elastic body 602 (see fig. 7 and 14) disposed on the adjusting base 601 and extending to the extending body 402, a fixing base 603 connected to the housing 302, a fixing hole 604 disposed on the fixing base 603, a guiding groove 605 disposed on the fixing base 603, a protruding body 606 disposed on the adjusting base 601 and combined with the fixing hole 604, an adjusting rod 607 disposed on the adjusting base 601, a second elastic body 608 disposed between the adjusting base 601 and the fixing base 603, a screw hole 609 disposed on the adjusting base 601, a circular protrusion 610 disposed on the adjusting base 601 and located outside the screw hole 609, a stud 611 capable of being combined with the screw hole 609, and a disc body 612 disposed on the stud 611. The fixing base 603 is locked in the housing 302 by two screws 613, and the adjusting rod 607 can move in the guiding groove 605, so that the adjusting base 601 can move relative to the fixing base 603.

Referring to fig. 4, 5, 7, and 12, the adjustment rod 607 penetrates through the guide recess 605 and the adjustment hole 303 and protrudes out of the housing 302 to be exposed to the outside, the recess shape of the guide recess 605 corresponds to the through hole shape of the adjustment hole 303, and the adjustment rod 607 can move in the guide recess 605 and the adjustment hole 303.

Referring to fig. 4, 5, 9, and 14, preferably, the first elastic body 602 surrounds the first blocking wall 403 or the second blocking wall 404 disposed outside the circular protrusion 610 and protruding outward from the adjustment seat 601 to extend to the side of the extension 402 of the pressing unit 4, and the combination of the stud 611 and the screw hole 609 enables the disc body 612 and the adjustment seat 601 to cooperate to fix the first elastic body 602.

Referring to fig. 5, 7 and 12, the adjusting body 601 can move between a first position and a second position, the user can move the adjusting rod 607 to control the position of the adjusting body 601, and the adjusting hole 303 in the r shape, the second elastic body 608 and the adjusting rod 607 cooperate to maintain the adjusting body 601 at the first position or the second position.

Referring to fig. 6, 7, 8, 9 and 10, fig. 9 is a partial cross-sectional view of a frame line a in fig. 8, wherein only the components related to the present invention are shown in fig. 8 for convenience of illustration and inspection, and others are not shown. When the adjustment base 601 is at the first position, the first elastic body 602 supports downward against the first blocking wall 403, and the first elastic body 602 applies a force toward the switch module 501 to the first blocking wall 403 on the side of the extension body 402 so that the pressing wall 405 presses against the switch module 501, thereby reducing the feedback elastic force of the switch module 501 and the pressing body 401, allowing a user to press the switch module 501 with a smaller pressing force, and in addition, the switch of the switch module 501 can be pressed down for a certain distance, so that the moving stroke of the switch module 501 is shortened. The first supporting wall 304 is used for supporting the adjusting rod 607, and the elasticity of the second elastic body 608 can make the adjusting rod 607 support the first supporting wall 304 and maintain the adjusting base 601 at the first position.

Referring to fig. 11, 12, 13, 14 and 15, fig. 14 is a partial cross-sectional view of a frame line B in fig. 13. When the adjustment base 601 is at the second position, the first elastic body 602 supports the second blocking wall 404 upward, and the first elastic body 602 applies a force opposite to the direction of the switch module 501 to the second blocking wall 404 on the side of the extension body 402 to increase the feedback elastic force of the switch module 501 and the pressing body 401, so that the user must press the switch module 501 with a larger pressing force, and in addition, the switch of the switch module 501 is moved upward by a certain distance to increase the moving stroke of the switch module 501. The second supporting wall 305 is used for supporting the adjusting rod 607, and the elasticity of the second elastic body 608 can make the adjusting rod 607 support the second supporting wall 305 and maintain the adjusting base 601 at the second position.

Referring to fig. 5, 6, 7, 9, 12, and 14, the through hole of the adjusting hole 303 is shaped like a r, when the adjusting base 601 is at the first position, a user can use a finger to move the adjusting rod 607 upward to push forward, so that the adjusting base 601 moves to the second position, and after the user releases the finger, the second elastic body 608 supports against the adjusting base 601, so that the adjusting rod 607 supports against the second supporting wall 305, and the adjusting base 601 is maintained at the second position.

Referring to fig. 5, 7, 9, 11, 12, and 14, when the adjustment base 601 is at the second position, the user can push the adjustment rod 607 backward by using the finger, and when the user releases the finger, the second elastic body 608 pushes the adjustment base 601 to make the adjustment rod 607 abut against the first supporting wall 304, and make the adjustment base 601 reach and maintain the first position.

Referring to fig. 16, which is a graph of the feedback elastic force and the movement stroke of a general mouse button, a vertical axis 801 is the feedback elastic force (in gf, gf = gram force, i.e., force per gram) when the mouse button is pressed, a horizontal axis 802 is the movement stroke (in mm) when the mouse button is pressed, a Z-fold line is a measurement result of the general mouse button, and a structure for changing the feedback elastic force is not provided in the general mouse button. The microswitch has a pressing moving stroke, the mouse button (plastic sheet) has elasticity, and the microswitch and the mouse button are spaced from each other, so when the pressing button of a common mouse is pressed, the mouse button is moved for a certain distance to be in contact with the microswitch, and then the microswitch is pressed to trigger a control instruction. As can be seen from the Z-fold line, since the mouse button and the microswitch are spaced from each other, the feedback elastic force when the mouse button is pressed is not started from the zero point position (i.e. 0mm) of the moving stroke, but is sensed from about 0.05mm, which may cause a poor clicking feeling.

Referring to fig. 9, 14, and 17, which are graphs of the feedback elastic force and the movement stroke of the mouse device capable of switching the feedback elastic force with zero gap according to the present invention, a horizontal axis 811 is the movement stroke (in mm) when the mouse button is pressed down, and a vertical axis 812 is the feedback elastic force (in gf, gf = gram force, i.e., force per gram) when the mouse button is pressed down. The X-line is the measurement result of the light-load feedback elastic force (the adjusting base 601 is at the first position), and the Y-line is the measurement result of the heavy-load feedback elastic force (the adjusting base 601 is at the second position). Wherein the pressing wall 405 contacts the switch module 501 and the origin of the moving stroke starts from 0mm of the horizontal axis, a negative value indicates that the switch module 501 is lifted up to cause the moving stroke to increase (e.g., Y-fold), and a positive value indicates that the switch module 501 is pressed down to cause the moving stroke to decrease (e.g., X-fold). As can be seen from fig. 17, in the X-fold line, the first elastic body 602 of the adjusting unit 6 presses the first blocking wall 403 and shortens the moving stroke of the switch module 501 by about 0.05mm to 0.07mm, and at this time, the switch module 501 reduces the feedback elastic force by about 5 gf. In the Y-fold line, the first elastic body 602 of the adjusting unit 6 lifts the second blocking wall 404 to increase the moving stroke of the switch module 501 by about 0.03mm to 0.05mm, and at this time, the switch module 501 will increase the feedback elastic force by about 5gf, so that the user will always bear the feedback elastic force of the first elastic body 602 when pressing the pressing unit 4, thereby effectively improving the click feeling of the key. In practical implementation, the test data is influenced by the distance between the first elastic body 602, the first blocking wall 403 and the second blocking wall 404, or the moving distance of the adjusting base 601, which should not be limited to this.

Referring to fig. 1 to 17, it can be seen from the above description that the mouse device capable of switching feedback elastic force with zero gap of the present invention indeed has the following functions:

firstly, the feedback elasticity when the key is pressed can be changed:

the adjusting rod 607 controls the adjusting base 601 at the first position or the second position, so that the feedback elasticity of the switch unit 5 can be reduced when the adjusting base 601 is at the first position, and the feedback elasticity of the switch unit 5 can be increased when the adjusting base 601 is at the second position.

Secondly, switching of feedback elasticity can be carried out at zero distance:

when the adjustment base 601 is at the first position or the second position, the pressing wall 405 of the pressing unit 4 is always in contact with the switch module 501, so that the feedback elastic force can be switched at zero distance, the moving stroke of the switch module 501 can be reduced at the first position, and the moving stroke of the switch module 501 can be increased at the second position.

And thirdly, improving click feeling of the keys:

when the adjusting base 601 is at the second position and the user presses the pressing unit 4, the pressing unit 4 always bears more elastic force of the first elastic body 602, and the user can obviously feel the pressing distance and trigger the hand feeling of the switch module 501, so that the clicking feeling of the key can be improved.

In summary, the adjusting hole 303, the second elastic body 608, and the adjusting rod 607 cooperate to maintain the adjusting base 601 at the first position or the second position, so that when the adjusting base 601 is at the first position, the feedback elastic force and the moving stroke of the switch module 501 can be reduced, and when the adjusting base 601 is at the second position, the feedback elastic force and the moving stroke of the switch module 501 can be increased, and the click feeling of the key can be enhanced, thereby achieving the objective of the present invention.

The above description is only an example of the present invention, and the scope of the present invention should not be limited by this description, and all the simple equivalent changes and modifications made according to the claims and the description of the present invention are still included in the scope of the present invention.

Claims

1. A mouse device capable of switching feedback elasticity in zero clearance, comprising:

the shell unit comprises a shell surrounding and defining an accommodating space;

at least one pressing unit connected with the shell unit and comprising a pressing body and an extending body connected with the pressing body;

at least one switch unit, which is contacted with the pressing unit and comprises a switch module arranged in the accommodating space; and

at least one adjusting unit, including an adjusting seat body disposed in the accommodating space, and a first elastic body disposed on the adjusting seat body and extending to the extending body, wherein the adjusting seat body can move between a first position and a second position, when the adjusting seat body is at the first position, the first elastic body applies a force toward the switch module to the extending body, and when the adjusting seat body is at the second position, the first elastic body applies a force opposite to the switch module to the extending body.

2. The mouse device as claimed in claim 1, wherein the adjustment unit further comprises a fixing base connected to the housing, a fixing hole disposed on the fixing base, a guiding groove disposed on the fixing base, a protrusion disposed on the adjustment base and coupled to the fixing hole, and an adjustment rod disposed on the adjustment base and passing through the guiding groove, the adjustment rod being movable in the guiding groove to allow the adjustment base to move relative to the fixing base.

3. The mouse device as claimed in claim 1, wherein the housing unit further comprises an adjustment hole disposed in the housing, the adjustment unit further comprises an adjustment rod disposed on the adjustment base, and the adjustment rod is disposed through the adjustment hole.

4. The mouse device with zero-gap switching feedback elastic force according to claim 1, wherein the housing unit further includes an adjustment hole disposed in the housing, and a through hole of the adjustment hole of the housing unit is of a r shape.

5. The mouse device as claimed in claim 4, wherein the housing unit further includes a first supporting wall disposed at a bottom side of the adjusting hole and disposed on the housing, and a second supporting wall disposed at the adjusting hole and spaced apart from the first supporting wall, the adjusting unit further includes an adjusting rod disposed on the adjusting base and passing through the adjusting hole, the first supporting wall is used to support the adjusting rod and maintain the adjusting base at the first position, and the second supporting wall is used to support the adjusting rod and maintain the adjusting base at the second position.

6. The mouse device as claimed in claim 1, wherein the adjustment unit further comprises a fixed base connected to the housing and a second elastic body disposed between the adjustment base and the fixed base.

7. The mouse device as claimed in claim 1, wherein the adjusting unit further comprises a screw hole disposed on the adjusting base, a convex body disposed on the adjusting base and located outside the screw hole, a stud combined with the screw hole, and a disc body disposed on the stud, the first elastic body is disposed outside the convex body and protrudes from the adjusting base, and the combination of the stud and the screw hole enables the disc body to be matched with the adjusting base to fix the first elastic body.

8. The mouse device as claimed in claim 1, wherein the housing unit further includes an extension hole disposed on the housing, the extension body passing through the extension hole.

9. The mouse device as claimed in claim 1, wherein the pressing unit further comprises a first wall disposed on the extending body and a second wall disposed on the extending body, the first wall being spaced from the pressing body by a distance greater than the second wall.

10. The mouse device with zero-gap switchable feedback elastic force of claim 1, wherein the pressing unit further comprises a pressing wall disposed on the extension body, the pressing wall contacting the switch module.