CN113342189A

CN113342189A - Antiskid game mouse with built-in hand sweat drying structure

Info

Publication number: CN113342189A
Application number: CN202110656146.1A
Authority: CN
Inventors: 高田
Original assignee: Chuand Science And Technology Co ltd
Current assignee: Chuand Science And Technology Co ltd
Priority date: 2021-06-11
Filing date: 2021-06-11
Publication date: 2021-09-03
Anticipated expiration: 2041-06-11
Also published as: CN113342189B; CN115113745A

Abstract

The invention discloses an anti-skid game mouse with a built-in hand sweat drying structure, which comprises a shell, wherein a micro motor is installed in the shell through a bolt, and fan blades are fixedly installed on an output shaft of the micro motor; the movable block is movably arranged on the side of the protection box, and a heating wire is arranged in the movable block; the bottom of the connecting hose is mutually connected with the top of the movable block, and a fixed cavity is formed in a shell at the top of the connecting hose; the fixed cylinder is fixedly arranged at the bottom of the movable block, and the bottom of the fixed cylinder is movably connected with the inner bottom surface of the shell through a movable shaft; the sleeve block is sleeved on the outer side of the fixed cylinder. This antiskid type recreation mouse of built-in hand sweat dry construction has dry effect to the sweat that the long-time and mouse laminating of user's hand produced, prevents the phenomenon of skidding to can heat the hand through mouse according to the demand, and then promote the smooth and easy nature of operation.

Description

Antiskid game mouse with built-in hand sweat drying structure

Technical Field

The invention relates to the technical field of game mice, in particular to an anti-skid game mouse with a built-in hand sweat drying structure.

Background

The game mouse is a mouse which can improve game experience relative to a common mouse, and in order to meet the requirements of users, the functionality of the conventional game mouse needs to be improved, wherein a sweat drying structure is arranged in the game mouse, for example, a backlight-designed portable game mouse with the publication number of CN207718338U comprises a main body, a left side plate, a right side plate and a palm support … mouse and is further provided with a backlight effect, the scene mode can be randomly selected according to games by the portable game mouse with the backlight design, and meanwhile, the size can be conveniently adjusted, so that the use convenience is obviously improved. However, the portable game mouse with the backlight design still has the following disadvantages in the actual use process:

1. after a user holds the mouse for a long time, the hand part and the mouse are tightly attached, so that a large amount of sweat can appear on the hand part, the normal operation of the user can be influenced, and the phenomenon of slipping between the mouse and the hand part can be caused;

2. when the mouse is used under the condition of low air temperature, hands are exposed for a long time to cause discomfort of the hands, and normal operation is easily influenced, so that the hands need to be heated by other heating equipment, and the mouse is lack of a heating structure.

Aiming at the problems, innovative design is urgently needed on the basis of the original game mouse.

Disclosure of Invention

The invention aims to provide an anti-skid game mouse with a built-in hand sweat drying structure, and aims to solve the problems that after a user holds the mouse for a long time, the hand is tightly attached to the mouse, so that a large amount of sweat appears on the hand, the hand needs to be heated by other heating equipment, and the mouse is lack of a heating structure.

In order to achieve the purpose, the invention provides the following technical scheme: an antiskid game mouse with a built-in hand sweat drying structure comprises:

the fan blade protection device comprises a shell, wherein a micro motor is arranged in the shell through a bolt, a fan blade is fixedly arranged on an output shaft of the micro motor, and a protection box is fixedly arranged in the shell outside the fan blade;

the movable block is movably arranged on the side of the protection box, and a heating wire is arranged in the movable block;

the bottom of the connecting hose is mutually connected with the top of the movable block, a fixed cavity is formed in the shell at the top of the connecting hose, a first drying area is arranged on the outer side of the fixed cavity, and a second drying area is reserved on the inner side of the first drying area;

the fixed cylinder is fixedly arranged at the bottom of the movable block, the bottom of the fixed cylinder is movably connected with the inner bottom surface of the shell through a movable shaft, a worm wheel is sleeved on the outer side of the movable shaft, a worm is movably arranged on the side of the worm wheel, and an adjusting rod is fixed at the end of the worm;

the sleeve block is sleeved outside the fixed cylinder, two ends of the sleeve block are connected with a transmission pipe for transmitting gas, a fixing hole is reserved on a shell at the end of the transmission pipe, and an adjusting block is movably arranged at the disconnection position of the transmission pipe.

Preferably, the air outlet has been seted up to one side that the protection box is close to the movable block, and one side that is close to the protection box of movable block reserves first air intake and second air intake respectively to protection box and movable block are the sliding connection of laminating, and both sliding parts are the cambered surface setting simultaneously, and wind-force when the flabellum rotates can get into in the air inlet through the air outlet like this.

Preferably, a partition plate is fixed in the movable block between the first air inlet and the second air inlet, the section of the movable block is of a fan-shaped structure, and wind power can be discharged from different outlets after entering from different air inlets.

Preferably, one side that is provided with the heater strip in the movable block is linked together through coupling hose and fixed chamber, and fixed chamber is annular structure to the equidistance distributes in the fixed chamber has latticed first drying zone, and the wind that has the heat can blow out through first drying zone, plays the effect of heating hand.

Preferably, one side of the movable block, which is not provided with the heating wire, is communicated with the second drying area through another connecting hose, the second drying area is of a honeycomb structure, and wind without heat can be discharged from the second drying area to dry hand sweat.

Preferably, a through hole is reserved in the surface of the fixed cylinder, the fixed cylinder is rotatably connected with the sleeve block, and the sleeve block is communicated with the inside of the movable block through the through hole and the fixed cylinder, so that the communication of gas between the transmission pipe and the movable block cannot be influenced when the movable block and the fixed cylinder rotate.

Preferably, the two ends of the transmission pipe are respectively communicated with the sleeve block and the fixing holes, the fixing holes are obliquely arranged downwards, the fixing holes are distributed at the corners of the shell at equal intervals, and when wind blows from the fixing holes, dust adhered to the surface of the mouse pad can be blown away, so that the moving smoothness of the mouse is guaranteed.

Preferably, the adjusting block comprises a connecting hole, a supporting rod, a return spring and a fixing groove,

the connecting hole is seted up in the inside of regulating block, the bottom of regulating block is fixed with the bracing piece, and the cross-section of bracing piece is for invering "T" shape structure, can play the support to mouse through the bracing piece, and can drive the bracing piece through pressure when using mouse and accomodate into in the fixed slot.

Preferably, the outside winding of bracing piece has reset spring, and has seted up the fixed slot in the casing in the bracing piece outside to the movement distance of bracing piece is greater than the aperture of connecting hole, and the motion of bracing piece drives the regulating block and goes up and down, can adjust the intercommunication and the shutoff of transmission pipe.

Preferably, a phase change material layer is arranged on the inner surface of the shell, and the phase change material layer is polyethylene glycol (PEG-500) with the average molecular weight of 500. Wherein, PEG-500 is an organic solid-solid phase transition material, and the phase transition temperature of the PEG-500 is increased along with the increase of the polymerization degree, so the average relative molecular weight of the PEG-500 cannot be too high or too low, and when the PEG-500 reaches the phase transition temperature (20-25 ℃), solid-solid phase transition can occur to absorb or release heat. Therefore, by arranging the phase change material layer on the inner surface of the shell, when the working temperature of the mouse is too high and exceeds the phase change temperature of the phase change material, solid-solid phase change occurs, heat is absorbed, the temperature of the mouse is reduced, and the service life of the mouse is prolonged; when the working temperature of the mouse is too low and is lower than the phase change temperature of the phase change material, solid-solid phase change occurs, heat is released, the phenomenon that the working performance of the mouse is affected due to too low temperature is avoided, and sweat generated by long-time adhesion of the hand of a user and the mouse can be dried.

Preferably, a graphene heat dissipation layer is arranged between the shell and the phase change material layer, and the stoneThe thermal diffusion coefficient of the graphene heat dissipation layer is 2000mm²/s-2500mm²(ii)/s, the thermal conductivity of the graphene heat dissipation layer is 3000W/(m K) -3500W/(m K); graphene has splendid heat conduction heat dispersion, and its heat conductivity is 10 times stronger than silver, through addding graphite alkene heat dissipation layer, and it can go out the quick conduction of phase change material heat dissipation layer absorbed heat, avoids the heat to gather, and the radiating effect that will set up phase change material heat dissipation layer than single like this is better. Therefore, the dual heat-conducting heat dissipation layer of the graphene heat dissipation layer and the phase-change material heat dissipation layer can greatly improve the heat dissipation effect of the mouse.

Preferably, the phase change material layer surrounds the shell and is arranged in a zigzag structure to form a first zigzag structure, the graphene heat dissipation layer surrounds the shell and is arranged in a zigzag structure to form a second zigzag structure which is embedded with the first zigzag structure, and the phase change material layer and the graphene heat dissipation layer are the same in thickness and are on the same horizontal plane. The whole thickness of double-layer laminated arrangement can be reduced by the arrangement, and meanwhile, the heat dissipation effect of the double-layer laminated arrangement is not influenced.

Compared with the prior art, the invention has the beneficial effects that: the antiskid game mouse with the built-in hand sweat drying structure has a drying effect on sweat generated by long-time adhesion of a hand of a user to the mouse, prevents slipping, and can heat the hand through the mouse according to requirements, so that the smoothness of operation is improved;

1. when the first air inlet is communicated with the air outlet, air can enter the second drying area from the connecting hose to dry sweat between the hand and the mouse, and when the movable block is rotated to drive the second air inlet to be communicated with the air outlet, wind power with heat can be input into the first drying area through the connecting hose, so that the hand can be heated when the mouse is used at low temperature;

2. when the mouse is placed on the mouse pad, the supporting rod can support the mouse, and the transmission pipe is in a communicated state through the connecting hole, so that the wind entering the movable block enters the sleeve block from the fixed cylinder and finally enters the transmission pipe to be blown out from the fixed hole, dust on the mouse pad is blown away, and the moving smoothness of the mouse is guaranteed;

3. when the mouse is in a use state, the pressure applied to the mouse can drive the supporting rod to be retracted into the fixing groove, and the adjusting block is driven to move at the disconnected position of the transmission pipe to block the disconnected position of the transmission pipe, so that wind power cannot be transmitted from the transmission pipe, and the drying or heating efficiency of hands is ensured.

Drawings

FIG. 1 is a schematic top view of the present invention;

FIG. 2 is a schematic side sectional view of the present invention;

FIG. 3 is a schematic top view of the present invention;

FIG. 4 is a schematic view of a movable block of the present invention in a top-down view;

FIG. 5 is a schematic cross-sectional view taken along line A-A of FIG. 2 according to the present invention;

FIG. 6 is a schematic cross-sectional view taken at a in FIG. 5 according to the present invention;

FIG. 7 is a schematic view of a front cross-sectional structure of the nest block of the present invention.

In the figure: 1. a housing; 2. a micro motor; 3. a fan blade; 4. a protective case; 41. an air outlet; 5. a movable block; 51. a first air inlet; 52. a second air inlet; 53. a partition plate; 6. heating wires; 7. a connecting hose; 8. a fixed cavity; 9. a first drying zone; 10. a second drying zone; 11. a fixed cylinder; 111. a through hole; 12. a movable shaft; 13. a worm gear; 14. a worm; 15. adjusting a rod; 16. sleeving blocks; 17. a conveying pipe; 18. a fixing hole; 19. an adjusting block; 191. connecting holes; 192. a support bar; 193. a return spring; 194. and fixing the grooves.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which 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 invention.

Referring to fig. 1-7, the present invention provides a technical solution: an anti-skid game mouse with a built-in hand sweat drying structure comprises a shell 1, a micro motor 2, fan blades 3, a protective box 4, an air outlet 41, a movable block 5, a first air inlet 51, a second air inlet 52, a partition plate 53, a heating wire 6, a connecting hose 7, a fixed cavity 8, a first drying area 9, a second drying area 10, a fixed cylinder 11, a through hole 111, a movable shaft 12, a worm wheel 13, a worm 14, an adjusting rod 15, a sleeve block 16, a transmission pipe 17, a fixed hole 18, an adjusting block 19, a connecting hole 191, a supporting rod 192, a reset spring 193 and a fixed groove 194,

the device comprises a shell 1, wherein a micro motor 2 is installed in the shell through a bolt, a fan blade 3 is fixedly installed on an output shaft of the micro motor 2, and a protection box 4 is fixed in the shell 1 outside the fan blade 3;

the movable block 5 is movably arranged on the side of the protection box 4, and a heating wire 6 is arranged in the movable block 5;

the bottom of the connecting hose 7 is connected with the top of the movable block 5, a fixed cavity 8 is formed in the shell 1 at the top of the connecting hose 7, a first drying area 9 is arranged on the outer side of the fixed cavity 8, and a second drying area 10 is reserved on the inner side of the first drying area 9;

the fixed cylinder 11 is fixedly arranged at the bottom of the movable block 5, the bottom of the fixed cylinder 11 is movably connected with the inner bottom surface of the shell 1 through a movable shaft 12, a worm wheel 13 is sleeved on the outer side of the movable shaft 12, a worm 14 is movably arranged on the side of the worm wheel 13, and an adjusting rod 15 is fixed at the end of the worm 14;

the sleeve block 16 is sleeved outside the fixed cylinder 11, two ends of the sleeve block 16 are connected with a transmission pipe 17 for transmitting gas, a fixed hole 18 is reserved on the shell 1 at the end of the transmission pipe 17, and an adjusting block 19 is movably arranged at the disconnection position of the transmission pipe 17.

An air outlet 41 is formed in one side, close to the movable block 5, of the protection box 4, a first air inlet 51 and a second air inlet 52 are reserved in one side, close to the protection box 4, of the movable block 5, the protection box 4 and the movable block 5 are in sliding connection in a fitting mode, and meanwhile sliding positions of the protection box 4 and the movable block 5 are both arranged in an arc surface mode; a partition plate 53 is fixed in the movable block 5 between the first air inlet 51 and the second air inlet 52, and the section of the movable block 5 is of a fan-shaped structure; one side of the movable block 5, which is internally provided with a heating wire 6, is communicated with a fixed cavity 8 through a connecting hose 7, the fixed cavity 8 is of an annular structure, and first grid-shaped drying areas 9 are distributed on the fixed cavity 8 at equal angles; one side of the movable block 5, which is not provided with the heating wire 6, is communicated with a second drying area 10 through another connecting hose 7, and the second drying area 10 is of a honeycomb structure;

as shown in fig. 1-4, the wind in the movable block 5 can enter the second drying area 10 through one of the connection hoses 7, and is uniformly blown to the palm through the second drying area 10, so as to dry sweat between the palm and the shell 1, thereby ensuring the comfort of holding, and the phenomenon of slipping does not occur, when the temperature is lower, the mouse is used, the worm 14 can be rotated through the adjusting rod 15, the movable shaft 12 is driven to rotate through the worm wheel 13, and further the movable block 5 is driven to rotate through the fixed cylinder 11, the movable block 5 is always attached to the protective box 4 when rotating, when the movable block 5 drives the second air inlet 52 to coincide with the air outlet 41, the rotation is stopped, so that the wind can contact with the heat heated by the heating wire 6 when blowing into the movable block 5, so that the wind blown into the fixed cavity 8 through the other connection hose 7 is hot wind, and finally the hot wind is blown to the hand of the user from the first drying area 9, so as to heat the hands when the temperature is low, thereby ensuring the smoothness of operation;

a through hole 111 is reserved on the surface of the fixed cylinder 11, the fixed cylinder 11 is rotatably connected with the sleeve block 16, and the sleeve block 16 is communicated with the inside of the movable block 5 through the through hole 111 and the fixed cylinder 11; two ends of the transmission pipe 17 are respectively communicated with the sleeve block 16 and the fixing holes 18, the fixing holes 18 are arranged obliquely downwards, and the fixing holes 18 are distributed at the corners of the shell 1 at equal intervals; the adjusting block 19 comprises a connecting hole 191, a supporting rod 192, a return spring 193 and a fixing groove 194, the connecting hole 191 is formed in the adjusting block 19, the supporting rod 192 is fixed at the bottom of the adjusting block 19, and the section of the supporting rod 192 is of an inverted T-shaped structure; a return spring 193 is wound on the outer side of the support rod 192, a fixing groove 194 is formed in the shell 1 on the outer side of the support rod 192, and the movement distance of the support rod 192 is larger than the aperture of the connecting hole 191;

as shown in fig. 5-7, when the mouse is placed on the mouse pad, the support rod 192 can support the housing 1, such that the broken part of the transmission tube 17 is in a connected state through the connection hole 191, such that part of the wind power in the movable block 5 can enter the fixed cylinder 11, then enter the sleeve block 16 through the through hole 111, and finally blow out from the fixed hole 18 through the transmission tube 17, and the wind power can just blow on the mouse pad near the mouse, so as to blow off the dust on the mouse pad, and ensure the smoothness of the movement of the mouse, when the mouse is in a use state, the pressure of the housing 1 by the hand can drive the support rod 192 to be accommodated in the fixed groove 194, and drive the reset spring 193 to contract, the adjustment block 19 can be pushed upwards through the support rod 192, such that the connection hole 191 and the transmission tube 17 are in a disconnected state, the broken part of the transmission tube 17 can be blocked through the adjustment block 19, avoid the entering of wind-force, wind-force can all pass through the drying zone like this and transmit out, plays the drying of hand sweat or the heating to the hand, and can drive fixed section of thick bamboo 11 at the cover block 16 internal rotation when the movable block 5 rotates, consequently can not influence the transmission of wind-force.

The working principle is as follows: as shown in fig. 1-7, when the hand sweat needs to be dried, the micro motor 2 drives the fan blade 3 to rotate to generate wind power, then the wind power enters the inner side of the movable block 5 through the air outlet 41 and the first air inlet 51 and is blown into the second drying area 10 through the connecting hose 7, so that the hand sweat is dried, or the movable block 5 is rotated, so that the wind with heat is blown into the first drying area 9 to heat the hand, and when the mouse is placed on the mouse pad, the dust on the mouse pad can be blown away through the transmission of the wind power.

As a preferred embodiment of the present application, the inner surface of the shell 1 is provided with a phase change material layer, and the phase change material layer is polyethylene glycol (PEG-500) having an average molecular weight of 500. The PEG-500 is an organic solid-solid phase transition material (a solid ordered molecular connection structure is changed into a solid disordered molecular connection structure), and the phase transition temperature of the PEG-500 is increased along with the increase of the polymerization degree, so the average relative molecular weight of the PEG-500 cannot be too high or too low, and when the PEG-500 reaches the phase transition temperature (20-25 ℃), the PEG-500 can undergo solid-solid phase transition to absorb or release heat. Therefore, by arranging the phase change material layer on the inner surface of the shell 1, when the working temperature of the mouse is too high and exceeds the phase change temperature of the phase change material, solid-solid phase change occurs, heat is absorbed, the temperature of the mouse is reduced, and the service life of the mouse is prolonged; when the working temperature of the mouse is too low and is lower than the phase change temperature of the phase change material, solid-solid phase change occurs, heat is released, the phenomenon that the working performance of the mouse is affected due to too low temperature is avoided, and sweat generated by long-time adhesion of the hand of a user and the mouse can be dried.

As the preferred scheme of this application, casing 1 with be provided with graphite alkene heat dissipation layer between the phase change material layer, just graphite alkene heat dissipation layer's thermal diffusivity is 2000mm²/s-2500mm²(ii)/s, the thermal conductivity of the graphene heat dissipation layer is 3000W/(m K) -3500W/(m K); graphene has splendid heat conduction heat dispersion, and its heat conductivity is 10 times stronger than silver, through addding graphite alkene heat dissipation layer, and it can go out the quick conduction of phase change material heat dissipation layer absorbed heat, avoids the heat to gather, and the radiating effect that will set up phase change material heat dissipation layer than single like this is better. Therefore, the dual heat-conducting heat dissipation layer of the graphene heat dissipation layer and the phase-change material heat dissipation layer can greatly improve the heat dissipation effect of the mouse.

As the preferred scheme of this application, the phase change material layer centers on casing 1 is back shape structure setting and forms first shape structure, graphite alkene heat dissipation layer centers on casing 1 is back shape structure setting and form with the second of first shape structure looks gomphosis returns shape structure, just the phase change material layer with the thickness on graphite alkene heat dissipation layer is the same to on same horizontal plane. The whole thickness of double-layer laminated arrangement can be reduced by the arrangement, and meanwhile, the heat dissipation effect of the double-layer laminated arrangement is not influenced.

In the description of the present invention, "a plurality" means two or more unless otherwise specified; the terms "upper", "lower", "left", "right", "inner", "outer", "front", "rear", "head", "tail", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, are only for convenience in describing and simplifying the description, and do not indicate or imply that the device or element referred to must have a particular orientation, be constructed in a particular orientation, and be operated, and thus, should not be construed as limiting the invention. Furthermore, the terms "first," "second," "third," and the like are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "connected" and "connected" are to be interpreted broadly, e.g., as being fixed or detachable or integrally connected; can be mechanically or electrically connected; may be directly connected or indirectly connected through an intermediate. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that various changes in the embodiments and/or modifications of the invention can be made, and equivalents and modifications of some features of the invention can be made without departing from the spirit and scope of the invention.

Claims

1. The utility model provides a built-in hand sweat dry construction's antiskid type recreation mouse which characterized in that includes:

2. The slide-resistant gaming mouse with built-in hand sweat drying structure of claim 1, wherein: the protection box is close to one side of movable block and has seted up the air outlet, and one side that is close to the protection box of movable block reserves first air intake and second air intake respectively to protection box and movable block are the sliding connection of laminating, and both slip departments are the cambered surface setting simultaneously.

3. The anti-skid game mouse with built-in hand sweat drying structure of claim 2, wherein: a partition plate is fixed in the movable block between the first air inlet and the second air inlet, and the section of the movable block is of a fan-shaped structure.

4. The slide-resistant gaming mouse with built-in hand sweat drying structure of claim 1, wherein: one side of the movable block, which is provided with the heating wires, is communicated with the fixed cavity through a connecting hose, the fixed cavity is of an annular structure, and first latticed drying areas are distributed at equal angles in the fixed cavity.

5. The slide-resistant gaming mouse with built-in hand sweat drying structure of claim 1, wherein: one side of the movable block, which is not provided with the heating wire, is communicated with the second drying area through another connecting hose, and the second drying area is of a honeycomb structure.

6. The slide-resistant gaming mouse with built-in hand sweat drying structure of claim 1, wherein: a through hole is reserved in the surface of the fixed cylinder, the fixed cylinder is rotatably connected with the sleeve block, and the sleeve block is communicated with the inside of the movable block through the through hole and the fixed cylinder.

7. The slide-resistant gaming mouse with built-in hand sweat drying structure of claim 1, wherein: the two ends of the transmission pipe are respectively communicated with the sleeve block and the fixing holes, the fixing holes are obliquely and downwards arranged, and the fixing holes are distributed at the corners of the shell at equal intervals.

8. The slide-resistant gaming mouse with built-in hand sweat drying structure of claim 1, wherein: the adjusting block comprises a connecting hole, a supporting rod, a return spring and a fixing groove,

the connecting hole is formed in the adjusting block, a supporting rod is fixed at the bottom of the adjusting block, and the cross section of the supporting rod is of an inverted T-shaped structure.

9. The slide-resistant gaming mouse with built-in hand sweat drying structure of claim 8, wherein: the outside winding of bracing piece has reset spring, and has seted up the fixed slot in the casing in the bracing piece outside to the movement distance of bracing piece is greater than the aperture of connecting hole.