CN114135955A - Wearable heat sink of motion - Google Patents

Abstract

The invention relates to the field of sports wearability, in particular to a sports wearable cooling device. The speed of heat dissipation can be adjusted. Including knapsack subassembly, liquefaction subassembly, piston assembly and drive intercommunication subassembly, the knapsack subassembly is connected with the liquefaction subassembly, and the liquefaction subassembly is connected with the piston assembly, and the piston assembly is connected with drive intercommunication subassembly, and the knapsack subassembly is connected with drive intercommunication subassembly. The first clutch plate drives the first rotating shaft to move, and then power output is carried out through the first rotating shaft, so that the input motor is prevented from being suddenly started and stopped when being powered on and powered off, the power output through the input motor is larger instantaneously, and then the power output is released through relative rotation between the first clutch plate and the second clutch plate, and the effect of a protection device is further achieved. And the first clutch plate is tightly attached to the second clutch plate under the elastic action of the pushing spring of the clutch slide rod.

Description

Wearable heat sink of motion

Technical Field

The invention relates to the field of sports wearability, in particular to a sports wearable cooling device.

Background

For example, a wearable air cooling device with patent number CN03273470.0, the cooling device mainly comprises a liquid refrigerant tank, a heat exchanger, a miniature induced draft fan, a monitoring circuit board, an electromagnetic valve and a power supply. The refrigerant is gasified in the heat exchanger and mixed with the outer air sucked by the draught fan to form low temperature mixed gas, and the low temperature mixed gas is sent to the cold air dispersing device via the flexible air pipe and is dispersed to the periphery of the human body via the fine holes on the cold air dispersing device, so as to cool the human body.

Disclosure of Invention

The invention aims to provide a wearable sports cooling device, which can adjust the cooling speed.

The purpose of the invention is realized by the following technical scheme:

the utility model provides a wearable heat sink of motion, includes knapsack subassembly, liquefaction subassembly, piston assembly and drive intercommunication subassembly, the knapsack subassembly is connected with the liquefaction subassembly, and the liquefaction subassembly is connected with the piston assembly, and the piston assembly is connected with drive intercommunication subassembly, and the knapsack subassembly is connected with drive intercommunication subassembly.

As a further optimization of the technical scheme, the wearable sports cooling device of the invention comprises: the backpack assembly comprises a backpack plate, straps, a sleeve I, a sleeve II, a support I, a rotating shaft I, a clutch plate II, a support II, an input motor, a motor base, a clutch slide rod push spring and a spiral communication pipe, wherein the straps are provided with two straps which are fixedly connected with the backpack plate, a solution with smaller specific heat capacity is arranged in the sleeve I, the sleeve I is fixedly connected with the backpack plate, an interlayer is arranged at the inner end of the sleeve I, the spiral communication pipe is arranged in the interlayer arranged at the inner end of the sleeve I, the sleeve II is fixedly connected with the backpack plate, the inner end of the sleeve II is hollowed out, one end of the support I is fixedly connected with the sleeve I, the other end of the support I is rotatably connected with the rotating shaft I, the rotating shaft I is fixedly connected with the clutch plate I, the clutch plate I is connected with the clutch plate II in a matching manner, the clutch plate II is connected with the clutch slide rod in a sliding manner, the clutch slide rod push spring is arranged between the clutch plate II and the clutch slide rod, the clutch slide bar is rotatably connected with the second support, the input motor is fixedly connected with the motor base, the motor base is fixedly connected with the backpack plate, and an output shaft of the input motor is fixedly connected with the clutch slide bar.

As a further optimization of the technical scheme, the wearable sports cooling device of the invention comprises: the liquefaction assembly comprises a sealing plate, a lower sleeve, a middle sleeve, an upper sleeve, a middle-end sliding rod, a tension spring, a connecting pipe, a liquefaction cavity, a conical dispersion body and an expansion sleeve, wherein the sealing plate is fixedly connected with the lower sleeve, the lower sleeve is fixedly connected and communicated with the middle sleeve, the middle sleeve is fixedly connected and communicated with the upper sleeve, the middle-end sliding rod is communicated with the upper sleeve and is in sliding connection with the upper sleeve, the tension spring is arranged between the middle-end sliding rod and the upper sleeve, the liquefaction cavity is arranged in the upper sleeve, the connecting pipe is communicated in a tee way, one end of the connecting pipe is fixedly connected and communicated with the middle sleeve, one end of the connecting pipe is fixedly connected and communicated with the upper sleeve, the other end of the connecting pipe is fixedly connected and communicated with a spiral communicating pipe, the conical dispersion body is fixedly connected to the lower end of the middle-end sliding rod, the conical dispersion body is arranged in the lower sleeve, the expansion sleeve is fixedly connected and communicated with the lower sleeve, and the expansion sleeve is connected with the piston assembly, the sealing plate is arranged in the second sleeve.

As a further optimization of the technical scheme, the wearable sports cooling device of the invention comprises: the piston assembly comprises a piston sleeve, a first communicating pipe, a second communicating pipe, a fixing ring, a flywheel, a rectangular chute, an inner end clamping groove, an inner end slider, a hinged connecting rod, an inner end piston, an inner end clamping rod and an inner end clamping rod push spring, wherein the first communicating pipe and the second communicating pipe are both fixedly connected and communicated with the piston sleeve, the fixing ring is fixedly connected with the piston sleeve, the rectangular chute is arranged on the flywheel, the inner end clamping groove is provided with a plurality of inner end clamping grooves which are uniformly distributed in the rectangular chute, the inner end slider is in sliding connection with the rectangular chute, the inner end clamping rod is in matching connection with the inner end clamping groove, the inner end clamping rod is in sliding connection with the inner end slider, the inner end clamping rod push spring is arranged on the two inner end clamping rods, one end of the hinged connecting rod is hinged to the inner end slider, the other end of the hinged connecting rod is hinged to the inner end piston, the inner end piston is in sliding connection with the piston sleeve, the first communicating pipe is fixedly connected and communicated with the expansion sleeve, and the driving communicating assembly is fixedly connected and communicated with the second communicating pipe.

As a further optimization of the technical scheme, the wearable sports cooling device comprises a connecting component, a fixing frame, a heat dissipation back plate, an inner end rotating rod, heat dissipation fan blades, a rotating bevel gear, a matching bevel gear shaft, a transmission belt and a connecting cavity, wherein the fixing frame is fixedly connected with the heat dissipation back plate, the inner end rotating rod penetrates through the fixing frame and is rotatably connected with the fixing frame, the heat dissipation fan blades are fixed on the inner end rotating rod and are arranged between the fixing frame and the heat dissipation back plate, the matching bevel gear is fixedly connected with the inner end rotating rod, the connecting cavity is arranged in the heat dissipation back plate, the matching bevel gear is in meshing transmission with the rotating bevel gear, the matching bevel gear is fixedly connected with the matching bevel gear shaft, the matching bevel gear shaft is in matching connection with the transmission belt, the transmission belt is in matching connection with an output shaft of an input motor, a second communication pipe is fixedly connected with the heat dissipation back plate, and a second communication pipe is communicated with the connecting cavity, the spiral communicating pipe is fixedly connected with the heat dissipation back plate and communicated with the communicating chamber.

The wearable sports cooling device has the beneficial effects that:

according to the wearable cooling device for movement, the first rotating shaft is driven to move through the first clutch plate, and power output is performed through the first rotating shaft, so that the input motor is prevented from being suddenly started and stopped when being powered on and powered off, and further, the power output instantaneously through the input motor is large, and further, the power is released through relative rotation between the first clutch plate and the second clutch plate, and the effect of a protection device is achieved. The first clutch plate and the second clutch plate are tightly attached through the elastic action of the push spring of the clutch slide rod

Drawings

The invention is described in further detail below with reference to the accompanying drawings and specific embodiments.

FIG. 1 is a schematic view of an overall structure of a wearable sports cooling device according to the present invention;

FIG. 2 is a schematic view of the overall structure of a wearable sports cooling device according to the present invention;

FIG. 3 is a first schematic view of a backpack assembly of a wearable athletic cooling device of the present invention;

FIG. 4 is a schematic structural view of a backpack assembly of a wearable cooling device according to the present invention;

FIG. 5 is a schematic structural view of a backpack assembly of a wearable cooling device according to the present invention;

FIG. 6 is a first schematic view of a liquefaction assembly of the wearable athletic cooling device of the present invention;

FIG. 7 is a schematic structural diagram of a liquefaction assembly of the wearable exercise cooling device of the present invention;

FIG. 8 is a first schematic view of a piston assembly of a wearable athletic cooling device of the present invention;

FIG. 9 is a schematic structural view of a piston assembly of the wearable motion cooling device of the present invention;

FIG. 10 is a schematic view of a piston assembly of a wearable athletic cooling device of the present invention;

FIG. 11 is a first schematic view of a first configuration of a drive communication assembly of an athletic wearable cooling device in accordance with the present invention;

fig. 12 is a schematic structural diagram of a driving communication assembly of a wearable exercise cooling device according to a second embodiment of the present invention.

In the figure: a backpack assembly 1; a backpack plate 101; a harness 102; a first sleeve 103; a second sleeve 104; a first bracket 105; a first rotating shaft 106; a clutch plate I107; a second clutch plate 108; a second bracket 109; an input motor 1010; a motor base 1011; the clutch slide 1012; clutch slide rod push spring 1013; spiral communication tube 1014; a liquefaction assembly 2; a sealing plate 201; a lower casing 202; a middle sleeve 203; an upper sleeve 204; a middle slide bar 205; a tension spring 206; a connecting pipe 207; a liquefaction chamber 208; a cone dispersion 209; an extension sleeve 2010; a piston assembly 3; a piston sleeve 301; a first communication pipe 302; a second communicating pipe 303; a fixed ring 304; a flywheel 305; a rectangular chute 306; an inner end slot 307; an inner end slider 308; an articulation link 309; an inner end piston 3010; an inner end trip 3011; the inner end clamping rod push spring 3012; a drive communication assembly 4; a fixed frame 401; a heat-dissipating backplate 402; an inner end turn bar 403; heat dissipating fan blades 404; rotating the bevel gear 405; a mating bevel gear 406; a mating bevel gear shaft 407; a drive belt 408; communicating with the chamber 409.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

The fixed connection in the device is realized by fixing in modes of welding, thread fixing and the like, and different fixing modes are used in combination with different use environments; the rotary connection means that the bearing is arranged on the shaft in a drying mode, a spring retainer ring groove is formed in the shaft or the shaft hole, and the elastic retainer ring is clamped in the retainer ring groove to achieve axial fixation of the bearing and achieve rotation; the sliding connection refers to the connection through the sliding of the sliding block in the sliding groove or the guide rail, and the sliding groove or the guide rail is generally in a step shape, so that the sliding block is prevented from falling off in the sliding groove or the guide rail; the hinge joint is a movable connection mode on connecting parts such as a hinge, a pin shaft, a short shaft and the like; the required sealing positions are sealed by sealing rings or O-shaped rings.

The first embodiment is as follows:

the following describes this embodiment with reference to fig. 1 to 12, and a wearable sports cooling device includes a backpack assembly 1, a liquefaction assembly 2, a piston assembly 3, and a driving communication assembly 4, where the backpack assembly 1 is connected to the liquefaction assembly 2, the liquefaction assembly 2 is connected to the piston assembly 3, the piston assembly 3 is connected to the driving communication assembly 4, and the backpack assembly 1 is connected to the driving communication assembly 4.

The second embodiment is as follows:

the embodiment is described below with reference to fig. 1 to 12, and the embodiment further describes the first embodiment, where the backpack assembly 1 includes a backpack plate 101, two straps 102, a first sleeve 103, a second sleeve 104, a first support 105, a first rotating shaft 106, a first clutch plate 107, a second clutch plate 108, a second support 109, an input motor 1010, a motor base 1011, a first clutch slide 1012, a first clutch slide push spring 1013, and a spiral communication pipe 1014, where the two straps 102 are provided, the two straps 102 are both fixedly connected to the backpack plate 101, the first sleeve 103 is provided with a solution with a small specific heat capacity, the first sleeve 103 is fixedly connected to the backpack plate 101, the inner end of the first sleeve 103 is provided with an interlayer, the spiral communication pipe 1014 is disposed in the interlayer provided at the inner end of the first sleeve 103, the second sleeve 104 is fixedly connected to the backpack plate 101, the inner end of the second sleeve 104 is hollow, one end of the first support 105 is fixedly connected to the first sleeve 103, the other end of the first support 105 is rotatably connected to the first rotating shaft 106, the first rotating shaft 106 is fixedly connected with the first clutch plate 107, the first clutch plate 107 is matched and connected with the second clutch plate 108, the second clutch plate 108 is in sliding connection with a second clutch slide bar 1012, a second clutch slide bar push spring 1013 is arranged between the second clutch plate 108 and the second clutch slide bar 1012, the second clutch slide bar 1012 is rotatably connected with the second bracket 109, the input motor 1010 is fixedly connected with a motor base 1011, the motor base 1011 is fixedly connected with the backpack plate 101, and an output shaft of the input motor 1010 is fixedly connected with the second clutch slide bar 1012;

when the device is used, the whole device is carried on the back through the strap 102, the input motor 1010 is started, the input motor 1010 drives the clutch slide bar 1012 to move, the clutch slide bar 1012 drives the clutch plate II 108 to move, the clutch plate II 108 drives the clutch plate I107 to move, the clutch plate I107 drives the rotating shaft I106 to move, and power output is performed through the rotating shaft I106; meanwhile, in order to prevent the input motor 1010 from being suddenly started and stopped when the input motor 1010 is powered on and powered off, the power which is instantaneously output through the input motor 1010 is larger, and the power is released through the relative rotation between the clutch plate I107 and the clutch plate II 108, so that the function of a protection device is achieved; meanwhile, the first clutch plate 107 is tightly attached to the second clutch plate 108 under the elastic force of the pushing spring 1013 of the clutch slide rod; meanwhile, a solution with a small specific heat capacity is arranged in the first sleeve 103, and the temperature change amplitude of the solution is large due to the external temperature change of the solution, so that the solution is easy to absorb and release heat.

The third concrete implementation mode:

the present embodiment is described below with reference to fig. 1 to 12, and the present embodiment further describes an embodiment, where the liquefaction assembly 2 includes a sealing plate 201, a lower sleeve 202, a middle sleeve 203, an upper sleeve 204, a middle end slide bar 205, a tension spring 206, a connecting tube 207, a liquefaction chamber 208, a conical dispersion 209, and an extension sleeve 2010, the sealing plate 201 is fixedly connected to the lower sleeve 202, the lower sleeve 202 is fixedly connected to and communicated with the middle sleeve 203, the middle sleeve 203 is fixedly connected to and communicated with the upper sleeve 204, the middle end slide bar 205 is communicated with and slidably connected to the upper sleeve 204, the tension spring 206 is disposed between the middle end slide bar 205 and the upper sleeve 204, the upper sleeve 204 is internally provided with the liquefaction chamber 208, the connecting tube 207 is in a three-way communication, one end of the connecting tube 207 is fixedly connected to and communicated with the middle sleeve 203, one end of the connecting tube 207 is fixedly connected to and communicated with the upper sleeve 204, and communicated with the liquefaction chamber 208, the other end of the connecting tube 207 is fixedly connected to and communicated with a spiral communication tube 1014, the conical dispersion 209 is fixedly connected to the lower end of the middle slide bar 205, the conical dispersion 209 is arranged in the lower sleeve 202, the expanding sleeve 2010 is fixedly connected and communicated with the lower sleeve 202, the expanding sleeve 2010 is connected with the piston assembly 3, and the sealing plate 201 is arranged in the second sleeve 104.

The fourth concrete implementation mode:

the present embodiment is described below with reference to fig. 1 to 12, and the present embodiment further describes the first embodiment, where the piston assembly 3 includes a piston sleeve 301, a first communication pipe 302, a second communication pipe 303, a fixing ring 304, a flywheel 305, a rectangular sliding groove 306, an inner end clamping groove 307, an inner end slider 308, a hinge connecting rod 309, an inner end piston 3010, an inner end clamping rod 3011, and an inner end clamping rod push spring 3012, where the first communication pipe 302 and the second communication pipe 303 are both fixedly connected and communicated with the piston sleeve 301, the fixing ring 304 is fixedly connected with the piston sleeve 301, the rectangular sliding groove 306 is disposed on the flywheel 305, the inner end clamping grooves 307 are provided with a plurality of inner end clamping grooves 307, the inner end clamping grooves 307 are uniformly distributed in the rectangular sliding groove 306, the inner end slider 308 is slidably connected with the rectangular sliding groove 306, the inner end clamping rod 3011 is connected with the inner end clamping groove 307 in a matching manner, the inner end clamping rod 3011 is slidably connected with the inner end slider 308, and the inner end clamping rod 3011 is provided with two, the inner end clamping rod push springs 3012 are arranged on the two inner end clamping rods 3011, one end of the hinged connecting rod 309 is hinged to the inner end slider 308, the other end of the hinged connecting rod 309 is hinged to the inner end piston 3010, the inner end piston 3010 is connected with the piston sleeve 301 in a sliding mode, the first communicating pipe 302 is fixedly connected and communicated with the expansion sleeve 2010, and the driving communicating component 4 is fixedly connected and communicated with the second communicating pipe 303;

the flywheel 305 is started, the rectangular chute 306 is driven to move by the flywheel 305, the inner end slider 308 is driven to move by the rectangular chute 306, the hinged connecting rod 309 is driven to move by the inner end slider 308, the inner end piston 3010 is driven to move by the hinged connecting rod 309, the inner end piston 3010 reciprocates at the inner end of the piston sleeve 301, the cooling liquid in the driving communicating component 4 flows into the piston sleeve 301 through the communicating pipe two 303, flows out through the communicating pipe one 302 and flows into the expansion sleeve 2010, the cooling liquid impacts the conical dispersion 209 under the action of pressure, the cooling liquid is atomized, the atomized cooling liquid flows into the upper sleeve 204 through the middle sleeve 203 under the action of internal pressure, flows into the liquefaction cavity 208 through the connecting pipe 207 for pressure relief, and flows into the spiral communicating pipe 1014 through the connecting pipe 207, then flows into the communicating component 4 through the spiral communicating pipe 1014, is liquefied through the communicating component 4, completes circulation, and absorbs and dissipates heat of the solution with smaller specific heat capacity which is arranged in the sleeve I103; meanwhile, the inner end slider 308 can slide along the rectangular sliding groove 306, so that the center distance between the inner end slider 308 and the flywheel 305 changes, and the hinged connecting rod 309 driven by the inner end slider 308 enables the hinged connecting rod 309 to drive the inner end piston 3010 to change the stroke of the Wangfu movement at the inner end of the piston sleeve 301, so that the throughput of the cooling liquid in unit time changes, and the cooling speed is adjusted; the coolant in spiral communication pipe 1014 flows into communication chamber 409, and flows into communication pipe two 303 through communication chamber 409, thereby completing the circulation of the coolant.

The fifth concrete implementation mode:

the following describes the present embodiment with reference to fig. 1 to 12, and the present embodiment further describes the first embodiment, where the communicating component 4 includes a fixing frame 401, a heat-dissipating back plate 402, an inner end rotating rod 403, heat-dissipating fan blades 404, a rotating bevel gear 405, a matching bevel gear 406, a matching bevel gear shaft 407, a transmission belt 408, and a communicating chamber 409, the fixing frame 401 is fixedly connected to the heat-dissipating back plate 402, the inner end rotating rod 403 penetrates through the fixing frame 401 and is rotatably connected to the fixing frame 401, the heat-dissipating fan blades 404 are fixed on the inner end rotating rod 403 and are disposed between the fixing frame 401 and the heat-dissipating back plate 402, the matching bevel gear 406 is fixedly connected to the inner end rotating rod 403, the communicating chamber 409 is disposed in the heat-dissipating back plate 402, the matching bevel gear 406 is in meshing transmission with the rotating bevel gear 405, the matching bevel gear 406 is fixedly connected to the matching bevel gear shaft 407, the matching bevel gear shaft 407 is in matching connection with the transmission belt 408, the transmission belt 408 is in matching connection with the output shaft of the input motor 1010, the second communication pipe 303 is fixedly connected with the heat dissipation back plate 402, the second communication pipe 303 is communicated with the communication chamber 409, the spiral communication pipe 1014 is fixedly connected with the heat dissipation back plate 402, and the spiral communication pipe 1014 is communicated with the communication chamber 409;

meanwhile, the input motor 1010 drives the transmission belt 408 to move, and then drives the matching bevel gear shaft 407 to move through the transmission belt 408, and then drives the matching bevel gear 406 to move through the matching bevel gear shaft 407, and further drives the rotating bevel gear 405 to move through the matching bevel gear 406, and further drives the inner rotating rod 403 to move through the rotating bevel gear 405, and further drives the heat dissipating fan blades 404 to rotate through the inner rotating rod 403, and further takes away the heat of the heat dissipating back plate 402 through the heat dissipating fan blades 404, thereby completing the liquefaction of the cooling liquid in the communicating chamber 409.

It is to be understood that the above description is not intended to limit the present invention, and the present invention is not limited to the above examples, and that various changes, modifications, additions and substitutions which are within the spirit and scope of the present invention and which may be made by those skilled in the art are also within the scope of the present invention.

Claims (5)

1. A wearable heat sink of motion, includes knapsack subassembly (1), liquefaction subassembly (2), piston assembly (3) and drive intercommunication subassembly (4), its characterized in that: backpack assembly (1) is connected with liquefaction subassembly (2), and liquefaction subassembly (2) are connected with piston assembly (3), and piston assembly (3) are connected with drive intercommunication subassembly (4), and backpack assembly (1) is connected with drive intercommunication subassembly (4).

2. An athletic wearable cooling device according to claim 1, wherein: the backpack assembly (1) comprises a backpack plate (101), straps (102), a first sleeve (103), a second sleeve (104), a first support (105), a first rotating shaft (106), a first clutch plate (107), a second clutch plate (108), a second support (109), an input motor (1010), a motor base (1011), two clutch slide rods (1012), a clutch slide rod push spring (1013) and a spiral communicating pipe (1014), wherein the straps (102) are provided with two, the two straps (102) are both fixedly connected with the backpack plate (101), a solution with smaller specific heat capacity is arranged in the first sleeve (103), the first sleeve (103) is fixedly connected with the backpack plate (101), an interlayer is arranged at the inner end of the first sleeve (103), the spiral communicating pipe (1014) is arranged in the interlayer arranged at the inner end of the first sleeve (103), the second sleeve (104) is fixedly connected with the backpack plate (101), and the inner end of the second sleeve (104) is hollow, one end of a first support (105) is fixedly connected to a first sleeve (103), the other end of the first support (105) is rotatably connected with a first rotating shaft (106), the first rotating shaft (106) is fixedly connected with a first clutch plate (107), the first clutch plate (107) is matched and connected with a second clutch plate (108), the second clutch plate (108) is slidably connected with a second clutch slide rod (1012), a second clutch slide rod pushing spring (1013) is arranged between the second clutch plate (108) and the second clutch slide rod (1012), the second clutch slide rod (1012) is rotatably connected with a second support (109), an input motor (1010) is fixedly connected with a motor base (1011), the motor base (1011) is fixedly connected with a backpack plate (101), and an output shaft of the input motor (1010) is fixedly connected with the second clutch slide rod (1012).

3. An athletic wearable cooling device according to claim 1, wherein: the liquefaction assembly (2) comprises a sealing plate (201), a lower sleeve (202), a middle sleeve (203), an upper sleeve (204), a middle-end sliding rod (205), a tension spring (206), a connecting pipe (207), a liquefaction cavity (208), a conical dispersion body (209) and an expansion sleeve (2010), wherein the sealing plate (201) is fixedly connected with the lower sleeve (202), the lower sleeve (202) is fixedly connected and communicated with the middle sleeve (203), the middle sleeve (203) is fixedly connected and communicated with the upper sleeve (204), the middle-end sliding rod (205) is communicated and slidably connected with the upper sleeve (204), the tension spring (206) is arranged between the middle-end sliding rod (205) and the upper sleeve (204), the upper sleeve (204) is internally provided with the liquefaction cavity (208), the connecting pipe (207) is communicated in a tee way, one end of the connecting pipe (207) is fixedly connected and communicated with the middle sleeve (203), one end of the connecting pipe (207) is fixedly connected with the upper sleeve (204) and communicated with the liquefaction cavity (208), the other end of the connecting pipe (207) is fixedly connected and communicated with the spiral communicating pipe (1014), the conical dispersion body (209) is fixedly connected to the lower end of the middle-end sliding rod (205), the conical dispersion body (209) is arranged in the lower sleeve (202), the expansion sleeve (2010) is fixedly connected and communicated with the lower sleeve (202), the expansion sleeve (2010) is connected with the piston assembly (3), and the sealing plate (201) is arranged in the second sleeve (104).

4. An athletic wearable cooling device according to claim 1, wherein: the piston assembly (3) comprises a piston sleeve (301), a first communicating pipe (302), a second communicating pipe (303), a fixing ring (304), a flywheel (305), a rectangular sliding groove (306), an inner end clamping groove (307), an inner end slider (308), a hinged connecting rod (309), an inner end piston (3010), an inner end clamping rod (3011) and an inner end clamping rod push spring (3012), wherein the first communicating pipe (302) and the second communicating pipe (303) are fixedly connected and communicated with the piston sleeve (301), the fixing ring (304) is fixedly connected with the piston sleeve (301), the rectangular sliding groove (306) is arranged on the flywheel (305), the inner end clamping grooves (307) are provided with a plurality of inner end clamping grooves (307) which are uniformly distributed in the rectangular sliding groove (306), the inner end slider (308) is connected with the rectangular sliding groove (306) in a sliding manner, the inner end clamping rod (3011) is connected with the inner end slider (307) in a matching manner, and the inner end clamping rod (3011) is connected with the inner end slider (308) in a sliding manner, the two inner end clamping rods (3011) are arranged, the inner end clamping rod push springs (3012) are arranged on the two inner end clamping rods (3011), one end of each hinged connecting rod (309) is hinged to the corresponding inner end slider (308), the other end of each hinged connecting rod (309) is hinged to the corresponding inner end piston (3010), the corresponding inner end piston (3010) is connected with the corresponding piston sleeve (301) in a sliding mode, the corresponding communicating pipe I (302) is fixedly connected with the corresponding expansion sleeve (2010) and communicated with the corresponding expansion sleeve, and the corresponding communicating driving component (4) is fixedly connected with the corresponding communicating pipe II (303) and communicated with the corresponding expansion sleeve.

5. An athletic wearable cooling device according to claim 1, wherein: the communication component (4) comprises a fixing frame (401), a heat dissipation back plate (402), an inner end rotating rod (403), heat dissipation fan blades (404), rotating bevel teeth (405), a matching bevel tooth (406), a matching bevel gear shaft (407), a transmission belt (408) and a communication chamber (409), wherein the fixing frame (401) is fixedly connected with the heat dissipation back plate (402), the inner end rotating rod (403) penetrates through the fixing frame (401) and is rotatably connected with the fixing frame (401), the heat dissipation fan blades (404) are fixed on the inner end rotating rod (403) and are arranged between the fixing frame (401) and the heat dissipation back plate (402), the matching bevel teeth (406) are fixedly connected with the inner end rotating rod (402), the communication chamber (409) is arranged in the heat dissipation back plate (402), the matching bevel teeth (406) are in meshed transmission with the rotating bevel teeth (405), the matching bevel teeth (406) are fixedly connected with the matching bevel gear shaft (407), and the matching bevel gear shaft (407) is in matched connection with the transmission belt (408), the transmission belt (408) is connected with an output shaft of the input motor (1010) in a matched mode, the second communicating pipe (303) is fixedly connected with the heat dissipation back plate (402) and the second communicating pipe (303) is communicated with the communicating chamber (409), and the spiral communicating pipe (1014) is fixedly connected with the heat dissipation back plate (402) and the spiral communicating pipe (1014) is communicated with the communicating chamber (409).

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