CN217606343U - Wireless mouse - Google Patents

Abstract

The application provides a wireless mouse, including epitheca, drain pan, the module of charging and drive arrangement, the epitheca encloses into installation space with the drain pan, and installation space is located to the module of charging. The bottom shell is provided with a bottom wall and a lower peripheral side wall surrounding the periphery of the bottom wall, the lower peripheral side wall is provided with a charging port, and the charging port is communicated with the installation space and corresponds to the charging module. The driving device is arranged in the installation space and used for driving the upper shell to move relative to the bottom shell so as to shield the charging port or expose the charging port. The application provides a wireless mouse can not cover the mouth that charges when charging wireless mouse, can solve the mouth that charges and expose always in the air, hides the problem of dirty dirt easily.

Description

Wireless mouse

Technical Field

The application relates to the field of electronic equipment, in particular to a wireless mouse.

Background

With the development of science and technology, the wireless mouse gradually replaces the wired mouse by virtue of the characteristics of simplicity, portability and the like. However, the charging port of the wireless mouse is always exposed in the air, so that dirt is easily stored and taken, and the use of the wireless mouse is influenced.

SUMMERY OF THE UTILITY MODEL

The embodiment of the application provides a wireless mouse, can not cover the mouth that charges when charging at wireless mouse, can solve the mouth that charges and expose all the time in the air, hide the problem of dirty and holding easily.

The wireless mouse comprises an upper shell, a bottom shell, a charging module and a driving device, wherein the upper shell and the bottom shell are enclosed to form an installation space, and the charging module is arranged in the installation space. The bottom shell is provided with a bottom wall and a lower peripheral side wall surrounding the periphery of the bottom wall, the lower peripheral side wall is provided with a charging port, and the charging port is communicated with the installation space and corresponds to the charging module. The driving device is arranged in the installation space and used for driving the upper shell to move relative to the bottom shell so as to shield the charging port or expose the charging port. The utility model provides a wireless mouse can be nimble shield or expose the mouth that charges, can not only shield the mouth that will charge when wireless mouse does not charge, prevents that wireless mouse's the mouth that charges from hiding dirty and dirty, can also be through the height gesture of adjustment wireless mouse to satisfy different palm size users' user demand.

In one embodiment, the drive means is adapted to drive the upper housing in rotation relative to the bottom wall and/or to drive the upper housing in movement relative to the bottom wall in a direction perpendicular to the bottom wall. The drive arrangement drive epitheca rotates relative the diapire to and/or relative diapire removes, helps wireless mouse to adjust different motion gestures to can shield or expose the mouth that charges.

In one implementation, the bottom case has a hinge portion, and the hinge portion and the charging port are respectively located at two opposite ends of the bottom case. The upper shell is rotatably connected with the hinge part, and the driving device is used for driving the upper shell to rotate around the hinge part. In this scheme, the position of charging mouthful and articulated portion can design according to the product needs, for example the mouth that charges can be located wireless mouse's front end, and articulated portion can be located wireless mouse's rear end. One end of the upper shell rotates around the hinge portion, and the other end of the upper shell can adjust the distance from the bottom wall, so that the posture of the wireless mouse can be adjusted.

In one embodiment, the drive means is capable of driving the upper shell to move to a first extreme position, an intermediate position and a second extreme position and in each position is capable of locking the upper shell. The upper shell covers the charging port when located at the first limit position, the upper shell enables the charging port to be exposed when located at the second limit position, and the middle position is located between the first limit position and the second limit position. The upper shell can move to the first limit position, the second limit position and any middle position between the first limit position and the second limit position and be locked, so that the wireless mouse has a plurality of movement postures.

In one implementation, a drive device includes a drive mechanism and a diverter switch. The driving mechanism is arranged in the installation space, one part of the change-over switch is positioned in the installation space, the other part of the change-over switch is exposed out of the installation space, and the change-over switch is used for being operated by a user to control the driving mechanism to move, so that the driving mechanism drives the upper shell to move relative to the bottom shell. The exposed change-over switch of the driving device can facilitate a user to control the driving mechanism so as to control the movement of the upper shell.

In one implementation, the bottom wall is provided with an opening communicated with the installation space, and the other part of the change-over switch is exposed from the opening of the bottom wall. When the wireless mouse works, the bottom wall is in contact with the working table surface, the change-over switch exposed out of the bottom wall cannot influence the operation of the wireless mouse when the wireless mouse works, and the appearance of the wireless mouse is concise and consistent.

In one implementation, the drive device is an electric drive mechanism. The electrically driven driving device is quick in response, and can quickly adjust the motion posture of the wireless mouse, so that good user experience is guaranteed.

In one implementation, the driving mechanism comprises a motor and a motion output assembly, and an output shaft of the motor is connected with the motion output assembly; the change-over switch is used for the user to operate in order to control the motor and rotate, and then makes the motor drive motion output assembly and take place the mechanism motion. The driving mechanism formed by matching the motor with the motion output assembly is sensitive in response and good in stability, and a user can control the motor to rotate by using the change-over switch, so that the operation of the user is simple, convenient and efficient.

In one implementation, the upper shell has an upper wall and an upper peripheral sidewall surrounding a periphery of the upper wall, the upper peripheral sidewall surrounding an outer periphery of the upper peripheral sidewall, the upper wall being opposite the bottom wall. The upper wall is opposed to the bottom wall, and can constitute an installation space with the bottom wall, and the upper peripheral side wall of the upper wall can shield or expose the charging port of the bottom wall when the upper wall moves.

In one implementation, the upper wall has an opening, the wireless mouse further comprises a roller, one part of the roller is located in the installation space, the other part of the roller is exposed out of the opening of the upper wall, the roller can move along with the upper shell relative to the bottom shell, and the relative position of a rotating shaft of the roller and the upper shell is unchanged. When the roller moves on the upper shell, because the relative position of the roller and the upper shell is unchanged, the operation touch feeling of the user using the roller cannot be changed after the upper shell moves, and therefore good user experience is guaranteed.

Drawings

FIG. 1 is a schematic structural diagram of one attitude of a wireless mouse according to an embodiment of the present application;

FIG. 2 is a schematic cross-sectional view of a wireless mouse according to an embodiment of the present application;

FIG. 3 is a schematic view of the C-direction structure of FIG. 1;

FIG. 4 is a schematic structural diagram of another attitude of the wireless mouse according to the embodiment of the present application;

FIG. 5 is a schematic view of a usage scenario of the wireless mouse according to the embodiment of the present application;

fig. 6 is a schematic view of another usage scenario of the wireless mouse according to the embodiment of the present application.

Detailed Description

The technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings of the embodiments of the present application. It should be apparent that the described embodiments are only some of the embodiments of the present application, and not all embodiments. All other embodiments that can be derived by a person skilled in the art from the embodiments given herein without making any creative effort shall fall within the protection scope of the present application.

As shown in fig. 1 and 2, an embodiment of the present application provides a wireless mouse 10, which may include an upper case 1, a bottom case 2, a scroll wheel 3, a charging module 4, a driving device 5, and a storage battery. The upper case 1 and the bottom case 2 surround to form an installation space 10a, the charging module 4 and the driving device 5 are both disposed in the installation space 10a, one part of the roller 3 may be located in the installation space 10a, and the other part may be exposed out of the upper case 1. Schematically, the upper shell 1 is located at the upper part in the perspective of fig. 1 and 2, and the lower shell 2 is located at the lower part in the perspective of fig. 1 and 2, which is merely an example. In fact, the bottom case 2 in contact with the table top during the operation of the wireless mouse 10 may be called as the top case 1 in contact with the palm of the hand.

As shown in fig. 1, 2 and 3, the bottom case 2 has a bottom wall 21, a lower peripheral side wall 22 and a hinge 23.

The bottom wall 21 is in contact with the table top when the wireless mouse 10 is in operation. The bottom wall 21 has an opening 21a, and the opening 21a penetrates the bottom wall 21 to communicate with the installation space 10 a. The two ends of the opening 21a are an a end and a B end, respectively.

The lower peripheral sidewall 22 surrounds the periphery of the surrounding bottom wall 21. The lower peripheral side wall 22 is connected to the bottom wall 21, and may be, for example, integrally connected. The lower peripheral sidewall 22 has a charging port 22a, and the charging port 22a communicates with the mounting space 10 a.

The hinge portion 23 and the charging port 22a may be located at opposite ends of the bottom chassis 2, respectively. The hinge 23 is used to cooperate with the upper casing 1 to allow the upper casing 1 to rotate relative to the bottom casing 2.

In one embodiment, the hinge 23 may be a solid structure. For example, the hinge 23 may include a base and a shaft connected to each other, and the base and the shaft may be fixedly connected or rotatably connected, and the axial direction of the shaft is the direction perpendicular to the paper surface in the view of fig. 2. Wherein the base is fixedly connected (e.g. integrally connected) with the bottom wall 21, and an upper peripheral sidewall 12 (described in more detail below) of the upper casing 1 can rotate relative to the bottom casing 2 via the rotating shaft. For example, when the shaft is fixedly connected to the base, the upper peripheral sidewall 12 rotates around the shaft to rotate relative to the bottom case 2. Alternatively, when the shaft is rotatably connected to the base, the upper peripheral sidewall 12 is fixedly connected to the shaft and rotates together with the shaft relative to the bottom case 2. The above-mentioned structure and movement design of the hinge 23 are only examples, and the embodiment is not limited thereto.

In another embodiment, the hinge 23 may be a structural feature formed of reduced material, such as a hole, slot, or the like. The upper peripheral side wall 12 may have a structure adapted to such a hinge 23 (e.g., the upper peripheral side wall 12 has a hinge structure), and this structure of the upper peripheral side wall 12 forms a rotational connection with the hinge 23 to rotate relative to the bottom case 2.

As shown in fig. 1 and 2, the upper case 1 has an upper wall 11 and an upper peripheral side wall 12. When the wireless mouse 10 is operated, the upper wall 11 is in contact with the human heart. The upper wall 11 may be curved to conform to ergonomics and to conform to the curvature of the palm. The upper wall 1 has an opening 11a and an upper peripheral side wall 12 surrounds the periphery of the upper wall 11. The upper peripheral sidewall 12 also surrounds the outer periphery of the lower peripheral sidewall 22. From one end of the upper wall 11 to the other end (from the left end to the right end of the upper wall 11 in the perspective of fig. 2), the height of the upper peripheral sidewall 12 tends to increase, so that the outer shape of the upper case 1 is approximately arched.

Illustratively, the inner walls of both sides of the end of the upper peripheral sidewall away from the opening 11a may have pin holes for forming a rotational connection with the rotational shaft of the hinge portion 23.

As shown in fig. 1, 2, and 4, when the upper case 1 is rotated upward to a predetermined position, the charging port 22a can be exposed. It is easy to understand that the upper peripheral sidewall 12 can shield the charging port 22a when the upper case 1 is rotated downward to a certain position.

As shown in fig. 2, a part of the roller 3 is disposed in the installation space 10a, and another part of the roller 3 may be exposed from the opening 11 a. The roller 3 can rotate. The roller 3 can follow the upper case 1 to move, and when the upper case 1 rotates, the relative position of the rotation axis of the roller 3 and the upper case 1 is not changed, that is, the volume of the portion of the roller 3 exposed from the opening 11a is not substantially changed. The design can ensure that the operation experience of the user on the roller 3 is basically unchanged after the position of the upper shell 1 is adjusted.

In other embodiments, the wireless mouse may not have a scroll wheel, and the wireless mouse may use a touch module instead of the scroll wheel, and the wireless mouse has a touch function.

As shown in fig. 2, the charging module 4 and the battery are both provided in the installation space 10 a. The port of the charging module 4 is provided corresponding to the charging port 22a. The user inserts the charging wire into charging port 22a, just can make the charging wire peg graft with this port to charge for the battery through charging module 4.

As shown in fig. 2 and 3, the driving device 5 includes a motor 51, a motion output assembly 52, and a changeover switch 53. Wherein, both the motor 51 and the motion output assembly 52 can belong to a driving mechanism.

Wherein, the output shaft of the motor 51 is connected with the motion output assembly 52 to drive the motion output assembly 52 to reciprocate. The motion output assembly 52 may be connected to the upper wall 11 and transmit motion to the upper wall 11, thereby driving the upper case 1 to reciprocate. The switch 53 is electrically connected to the motor 51, and the switch 53 is exposed from the opening 21a, so that the user can operate the switch 53 to control the rotation of the motor 51, thereby controlling the movement of the movement output assembly 52.

In this embodiment, illustratively, the motion output assembly 52 may include a gear and rack mechanism, the gear is connected to an output shaft of the motor 51, the gear and the rack cooperate to drive the rack to do linear motion when the gear rotates, the rack can move along two opposite directions respectively by the positive rotation and the negative rotation of the motor 51, and the rack can drive the upper shell 1 to move when moving. In other embodiments, motion-output assembly 52 may also include a worm gear assembly, a hydraulic lift mechanism, a lead screw, and the like.

In the present embodiment, the driving device 5 is an electric driving device. In other embodiments, the driving device 5 may be driven purely mechanically (without using an electrically driven component), for example, the switch 53 may be used in conjunction with other mechanisms capable of purely mechanical motion, such as a linkage mechanism, to cause the driving device 5 to output reciprocating motion.

The drive device 5 of the present embodiment also enables a self-locking of the mechanism, so that when the switch 53 stays at a certain position, the stroke of the movement output component 52 remains unchanged, so that the upper shell 1 is locked at the corresponding position.

The principle of the driving device 5 for driving the upper shell 1 to move relative to the bottom shell 2 is as follows:

referring to fig. 3 and 4, the wireless mouse 10 is in the initial state, the upper case 1 is in the first limit position, the switch 53 is located at the a end of the opening 21a, and the upper peripheral sidewall 12 shields the charging port 22a. At this time, the user can toggle the switch 53 to the end B of the opening 21a to control the motor 51 to drive the motion output assembly 52 to move, and further drive the upper casing 1 to rotate around the hinge portion 23, so that the upper peripheral sidewall 12 gradually separates from the lower peripheral sidewall 22 and gradually exposes the charging port 22a. When the switch 53 reaches the B terminal, as shown in fig. 1 and 2, the charging port 22a is completely exposed, and the upper case 1 is at the second limit position.

On the contrary, referring to fig. 3 and 4, the user can toggle the switch 53 to the end a of the opening 21a to control the motor 51 to drive the motion output component 52 to move, and further drive the upper casing 1 to rotate around the hinge portion 23, so that the upper peripheral sidewall 12 is gradually buckled with the lower peripheral sidewall 22, and the charging port 22a is gradually shielded. When the switch 53 reaches the end a, as shown in fig. 4, the charging port 22a is completely shielded, and the wireless mouse 10 returns to the initial state when the upper case 1 is at the first limit position.

The above-mentioned changeover switch 53 can stay at the a and B ends in the opening 21a and enables the movement output member 52 to be locked at the corresponding positions, thereby enabling the upper case 1 to be locked at both extreme positions. It will be appreciated that this is merely an example. The switch 53 can stay at virtually any position within the opening 21a, thus enabling the movement output assembly 52, and thus the upper casing 1, to be locked at a corresponding arbitrary position, according to product needs. For example, the upper case 1 can be locked at the first limit position, the intermediate position, which may be different depending on the position at which the changeover switch 53 is stopped, and the second limit position, so that the upper case 1 can have an infinite number of intermediate positions.

As shown in fig. 1, when the charging port 22a of the wireless mouse 10 is exposed, it is possible to use the wireless mouse 10 while charging. Since the charging port 22a is located in front of the wireless mouse 10, the charging cable does not contact with the hand to disturb the user, thereby ensuring the user experience. When the wireless mouse 10 is no longer charged, the user can control the upper case 1 to rotate by the switch 53 to shield the charging port 22a, which can prevent dust, foreign matter, etc. from entering the charging port 22a and also can make the wireless mouse 10 have a neat and uniform appearance.

In addition, the upper shell 1 of the wireless mouse 10 can be adjusted relative to the bottom shell 2, and the design meets human factors engineering and can meet the requirements of different users.

As shown in FIG. 5, a large-handed user needs a higher space for the lateral side surface to place the thumb while using the mouse, and the fingers are longer, requiring a higher mouse to fit the arch of his palm. Therefore, when a large-handed user uses the wireless mouse 10, the upper case 1 thereof can be adjusted to the second limit position, so that the posture of the upper position is obtained, and the operation is convenient.

In contrast, when a small-handed user uses a mouse, the larger mouse supports the arch of the palm, and the fingers are likely to be fatigued to operate thereon for a long period of time, so that the small-handed user needs a smaller mouse. As shown in fig. 6, the small-handed user can adjust the upper case 1 of the wireless mouse 10 to a first extreme position, facilitating the hand-holding operation of the wireless mouse 10.

The above is for two typical users. In the actual use process, the user can also arbitrarily adjust the posture of the wireless mouse 10 according to the preference of the user. Meanwhile, the wireless mouse 10 can be self-locked in any posture, and after the user sets the favorite posture of the wireless mouse 10, the posture of the wireless mouse 10 cannot be changed at will, so that good product experience of the user is maintained.

When the wireless mouse 10 of the present embodiment is in operation, the switch 53 located on the bottom wall 21 is covered and invisible, so that the appearance of the wireless mouse 10 can be kept simple and consistent. In other embodiments, the switch 53 may be provided on any side of the wireless mouse 10. Alternatively, the switch 53 may not be used to trigger the movement of the upper case 1, and for example, the hand may directly apply a force to the upper case 1 to adjust the position of the upper case 1.

Unlike the above-described embodiments, in other embodiments, the driving device 5 of the wireless mouse 10 can drive the upper case 1 to move relative to the bottom wall 21 in a direction perpendicular to the bottom wall 21, or the driving device 5 can drive the upper case 1 to move relative to the bottom wall 21 in a direction perpendicular to the bottom wall 21 and can drive the upper case 1 to rotate relative to the bottom wall 21, so as to adjust the position of the upper case 1.

The above description is only for the specific embodiments of the present application, but the scope of the present application is not limited thereto, and any person skilled in the art can easily conceive of the changes or substitutions within the technical scope of the present application, and shall be covered by the scope of the present application. Therefore, the protection scope passed by this application shall be subject to the protection scope of the claims.

Claims (10)

1. A wireless mouse is characterized in that a wireless mouse is provided,

the charging device comprises an upper shell, a bottom shell, a charging module and a driving device;

the upper shell and the bottom shell form an installation space in an enclosing mode, and the charging module is arranged in the installation space; the bottom shell is provided with a bottom wall and a lower peripheral side wall surrounding the periphery of the bottom wall, the lower peripheral side wall is provided with a charging port, and the charging port is communicated with the mounting space and corresponds to the charging module;

the driving device is arranged in the installation space and used for driving the upper shell to move relative to the bottom shell so as to shield the charging port or expose the charging port.

2. The wireless mouse of claim 1,

the driving device is used for driving the upper shell to rotate relative to the bottom wall and/or driving the upper shell to move relative to the bottom wall along the direction perpendicular to the bottom wall.

3. The wireless mouse of claim 2,

the bottom shell is provided with a hinged part, and the hinged part and the charging port are respectively positioned at two opposite ends of the bottom shell; the upper shell is rotatably connected with the hinge part; the driving device is used for driving the upper shell to rotate around the hinge part.

4. The wireless mouse of any one of claims 1-3,

the driving device can drive the upper shell to move to a first limit position, a middle position and a second limit position, and the upper shell can be locked at each position; wherein the upper case shields the charging port when the upper case is located at the first limit position, the charging port is exposed when the upper case is located at the second limit position, and the intermediate position is located between the first limit position and the second limit position.

5. The wireless mouse according to any one of claims 1 to 3,

the driving device comprises a driving mechanism and a change-over switch; the driving mechanism is arranged in the mounting space; one part of the change-over switch is positioned in the installation space, the other part of the change-over switch is exposed out of the installation space, and the change-over switch is used for being operated by a user to control the driving mechanism to move, so that the driving mechanism drives the upper shell to move relative to the bottom shell.

6. The wireless mouse of claim 5,

the bottom wall is provided with an opening communicated with the installation space, and the other part of the change-over switch is exposed out of the opening of the bottom wall.

7. The wireless mouse of claim 5,

the driving device is an electric driving mechanism.

8. The wireless mouse of claim 7,

the driving mechanism comprises a motor and a motion output assembly, and an output shaft of the motor is connected with the motion output assembly; the change-over switch is used for being operated by a user to control the motor to rotate, so that the motor drives the motion output assembly to move.

9. The wireless mouse according to any one of claims 1 to 3,

the upper shell has an upper wall and an upper peripheral side wall surrounding a periphery of the upper wall, the upper peripheral side wall surrounds an outer periphery of the upper peripheral side wall, and the upper wall is opposite to the bottom wall.

10. The wireless mouse of claim 9,

the upper wall has an opening;

the wireless mouse further comprises a roller, one part of the roller is located in the installation space, the other part of the roller is exposed out of the opening of the upper wall, the roller can move relative to the bottom shell along with the upper shell, and the relative position of a rotating shaft of the roller and the upper shell is unchanged.

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