CN117072405A - Multidirectional cooling device for air cylinder - Google Patents

Abstract

The application discloses a multi-azimuth cooling device for an air cylinder, which comprises a driving assembly, an executing assembly arranged at the upper end of the driving assembly, cooling assemblies arranged on the executing assembly, coolers arranged between the cooling assemblies, a heat dissipation assembly arranged on one side of the cooling assemblies, a connecting bracket arranged on the outer side of the coolers, a cooling pipeline arranged on the coolers and the air cylinder arranged between the driving assembly and the coolers, wherein the cooling assembly is arranged on the upper end of the driving assembly; the beneficial effects of the application are as follows: the water cooling device is used for realizing transposition, so that the water cooling device can cool and dissipate heat on the side face and the upper end face of the air cylinder, the situation that the local temperature of the air cylinder is low and the local temperature of the air cylinder is high is effectively avoided, and the effect of uniform heat dissipation of the whole air cylinder is realized.

Description

Multidirectional cooling device for air cylinder

Technical Field

The application relates to the technical field of heat dissipation of devices, in particular to a multidirectional cooling device for an air cylinder.

Background

The diaphragm compressor is a positive displacement compressor, has the advantages of good sealing performance and the like, and the gas side and the oil side of the diaphragm compressor can be completely separated by virtue of the middle diaphragm in the operation process of the diaphragm compressor, so that the gas side conveying medium is prevented from being polluted by the oil side, the diaphragm compressor is particularly suitable for conveying gas with high requirements on quality, and the diaphragm compressor is widely applied to high-temperature gas cooled reactors at present. According to the working mechanism of the diaphragm compressor, the oil side and the gas side need to be cooled during working, and particularly, for a large-sized diaphragm compressor with a large compression ratio, a higher requirement is put on the cooling effect. In the operation process of a large diaphragm compressor of a certain type, which is applied to a high-temperature gas cooled reactor, the problem that the exhaust temperature of a cylinder is too high exists because the compression ratio and the flow are both high parameters, so that the temperature of lubricating oil is indirectly increased, the normal operation requirement of the diaphragm compressor cannot be met, and potential safety hazards exist.

At present, a factory can adopt water cooling to cool a cylinder, but the water cooling only aims at a local area to cool, so that the phenomenon that the local temperature is low and the local temperature is high can be caused. The temperature of the lubricating oil is still increased, and the normal operation requirement of the diaphragm compressor cannot be met.

Disclosure of Invention

This section is intended to outline some aspects of embodiments of the application and to briefly introduce some preferred embodiments. Some simplifications or omissions may be made in this section as well as in the description of the application and in the title of the application, which may not be used to limit the scope of the application.

The present application has been made in view of the above-mentioned or existing problems occurring in the prior art.

Therefore, the application aims to provide a multidirectional cooling device for a cylinder, which solves the problems that water cooling heat dissipation is too limited and the heat dissipation of the cylinder cannot be realized in multiple directions.

In order to solve the technical problems, the application provides the following technical scheme: the utility model provides a diversified cooling device of cylinder, its include drive assembly, set up in the execution subassembly of drive assembly upper end, set up in cooling module on the execution subassembly, set up in cooler between the cooling module, set up in cooling module one side's radiator unit, set up in the linking bridge in the cooler outside, set up in cooling pipeline on the cooler, and set up in drive assembly with cylinder between the cooler.

As a preferable scheme of the multi-azimuth cooling device for the cylinder, the application comprises the following steps: the driving assembly comprises a motor, a rotating shaft arranged at one end of the motor and a resetting piece arranged on the rotating shaft.

As a preferable scheme of the multi-azimuth cooling device for the cylinder, the application comprises the following steps: the cooling assembly comprises a guide rail piece, a lifting piece arranged on one side of the guide rail piece and a cooling piece arranged on the other side of the guide rail piece.

As a preferable scheme of the multi-azimuth cooling device for the cylinder, the application comprises the following steps: the execution assembly comprises a center plate, a connecting rod arranged on the outer side of the center plate, and an annular rack arranged on the other end of the connecting rod.

As a preferable scheme of the multi-azimuth cooling device for the cylinder, the application comprises the following steps: the reset piece comprises a spring, a fixed strip arranged at one end of the spring, a rotating fluted disc arranged at one side of the spring and a fixed shell piece arranged at the outer side of the rotating fluted disc.

As a preferable scheme of the multi-azimuth cooling device for the cylinder, the application comprises the following steps: the fixed shell comprises a shell, a supporting frame arranged on the outer side of the shell and a movable pawl arranged on the inner side of the shell.

As a preferable scheme of the multi-azimuth cooling device for the cylinder, the application comprises the following steps: the heat dissipation assembly comprises a side heat dissipation strip, a heat dissipation strip connecting rod arranged at one end of the side heat dissipation strip, a vertical threaded rod arranged at one side of the heat dissipation strip connecting rod, a meshing gear arranged at one end of the vertical threaded rod, a meshing rack arranged at one side of the meshing gear, a meshing rack guide rail arranged at the outer side of the meshing rack, an upper heat dissipation strip arranged at one end of the meshing rack, a sponge strip arranged below the upper heat dissipation strip, a limiting frame arranged on the meshing gear and a guide rail connecting frame arranged at the outer side of the meshing rack guide rail.

As a preferable scheme of the multi-azimuth cooling device for the cylinder, the application comprises the following steps: the lifting piece comprises a screw rod, a bevel gear arranged at one end of the screw rod, a fixed head arranged at the other end of the screw rod, a movable block arranged on the screw rod and a fixing frame arranged at one side of the fixed head.

As a preferable scheme of the multi-azimuth cooling device for the cylinder, the application comprises the following steps: the guide rail piece comprises a guide rail frame, a guide rail groove arranged in the guide rail frame and a baffle strip arranged in the guide rail groove.

As a preferable scheme of the multi-azimuth cooling device for the cylinder, the application comprises the following steps: the cooling piece comprises a first movable plate, a second movable plate arranged on one side of the first movable plate, rollers arranged on one side of the first movable plate and one side of the second movable plate, a connecting rod shaft arranged on the rollers, and a pull rod arranged between the first movable plate and the second movable plate.

As a preferable scheme of the multi-azimuth cooling device for the cylinder, the application comprises the following steps: the first movable plate is provided with a groove and fins arranged in the groove.

The application has the beneficial effects that: the application realizes transposition of the water cooling device, so that the water cooling device can cool and dissipate heat of the side surface and the upper end surface of the air cylinder, thereby effectively avoiding the situation that the local temperature of the air cylinder is low and the local temperature is high, and realizing the effect of uniformly and integrally dissipating heat of the air cylinder.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present application, the drawings that are needed in the description of the embodiments will be briefly described below, it being obvious that the drawings in the following description are only some embodiments of the present application, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art. Wherein:

fig. 1 is an overall schematic view of a cylinder multi-azimuth cooling device.

FIG. 2 is a schematic view of a cylinder multi-azimuth cooling device.

FIG. 3 is a schematic view of a cooling assembly of a multi-azimuth cooling device for a cylinder.

FIG. 4 is a schematic diagram of a drive assembly for a cylinder multi-azimuth cooling device.

Fig. 5 is a schematic view of a fixed housing of a cylinder multi-azimuth cooling device.

Fig. 6 is a schematic diagram showing the disassembly of cooling components of the multi-azimuth cooling device for the cylinder.

FIG. 7 is a schematic view of a part of a cylinder multi-azimuth cooling device.

Fig. 8 is a schematic view of a heat dissipating assembly of a multi-azimuth cooling device for a cylinder.

Fig. 9 is a detailed schematic diagram of the cylinder multi-azimuth cooling device.

FIG. 10 is a detailed schematic diagram of a reset element of the cylinder multi-azimuth cooling device.

Detailed Description

In order that the above-recited objects, features and advantages of the present application will become more readily apparent, a more particular description of the application will be rendered by reference to specific embodiments thereof which are illustrated in the appended drawings.

In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present application, but the present application may be practiced in other ways other than those described herein, and persons skilled in the art will readily appreciate that the present application is not limited to the specific embodiments disclosed below.

Further, reference herein to "one embodiment" or "an embodiment" means that a particular feature, structure, or characteristic can be included in at least one implementation of the application. The appearances of the phrase "in one embodiment" in various places in the specification are not necessarily all referring to the same embodiment, nor are separate or alternative embodiments mutually exclusive of other embodiments.

Example 1

Referring to fig. 1 and 2, a cylinder multi-directional cooling apparatus according to a first embodiment of the present application is provided, which includes a driving unit 101, an actuating unit 103 disposed at an upper end of the driving unit 101, a cooling unit 102 disposed on the actuating unit 103, a cooler 105 disposed between the cooling units 102, a heat dissipating unit 108 disposed at one side of the cooling unit 102, a connection bracket 106 disposed at an outer side of the cooler 105, a cooling pipe 107 disposed on the cooler 105, and a cylinder 104 disposed between the driving unit 101 and the cooler 105.

Preferably, four cooling modules 102 are provided and connected to the actuator module 103, but both are not fixed, and the number of cooling modules 102 can be appropriately reduced and increased in consideration of cost and heat dissipation effects.

Preferably, the cooler 105 is fixed to the connecting bracket 106, and the connecting bracket 106 is connected to the cooling module 102.

Preferably, one end of the cooling pipeline 107 is connected with the cooler 105, and the other end is connected with the cooling assembly 102; in view of the actual cooling demand, a plurality of cooling pipes 107 may be provided, with a portion of the cooling pipes 107 for water inlet and a portion of the cooling pipes 107 for water outlet.

Preferably, cooler 105 is model DYH-40.

Preferably, the driving component 101 drives the cooling component 102 to perform displacement overturning through the executing component 103, the cooler 105 is provided with a separate switch, and the cooling function of the cooling component 102 is determined by the cooler 105.

In summary, the device is installed outside the cylinder 104, and is used for performing water cooling heat dissipation on the cylinder 104, the driving assembly 101 and the executing assembly 103 realize the position change of the cooling assembly 102, and the cooler 105 is used for realizing heat dissipation and circulation of cooling water through the cooling assembly 102.

Example 2

Referring to fig. 1 and 3, a second embodiment of the present application is different from the first embodiment in that: the cylinder multi-azimuth cooling device comprises a driving assembly 101, an executing assembly 103 arranged at the upper end of the driving assembly 101, a cooling assembly 102 arranged on the executing assembly 103, a cooler 105 arranged between the cooling assemblies 102, a heat dissipation assembly 108 arranged on one side of the cooling assembly 102, a connecting bracket 106 arranged on the outer side of the cooler 105, a cooling pipeline 107 arranged on the cooler 105 and a cylinder 104 arranged between the driving assembly 101 and the cooler 105.

The driving assembly 101 includes a motor 101a, a rotating shaft 101b disposed at one end of the motor 101a, and a reset element 101c disposed on the rotating shaft 101 b.

The cooling assembly 102 includes a rail member 102b, a lift member 102a disposed on one side of the rail member 102b, and a cooling member 102c disposed on the other side of the rail member 102 b.

The actuator assembly 103 includes a center plate 103a, a link 103b disposed outside the center plate 103a, and an annular rack 103c disposed at the other end of the link 103 b.

The motor 101a is connected to the central disk 103a through the rotary shaft 101 b; the reset element 101c is interposed between the motor 101a and the central disk 103 a.

Preferably, the central disk 103a is fixedly connected with the connecting rod 103 b; the other end of the connecting rod 103b is fixedly connected with the bottom surface of the annular rack 103c.

Preferably, the lifting member 102a drives the cooling member 102c to move and turn along the guide rail member 102b, so that the guide rail member 102b can complete ninety degrees of conversion.

Preferably, the motor 101a is of the type having a 200W output shaft 22mm35-95 ratio.

When the cooling device is used, the motor 101a drives the center disc 103a to rotate through the rotating shaft 101b, the annular rack 103c can rotate along with the center disc 103a, and when the annular rack 103c rotates, the lifting piece 102a drives the cooling piece 102c to move and overturn along the guide rail piece 102b, wherein the motor 101a is a gear motor and drives the annular rack 103c to slowly rotate, so that the movement reversion of the cooling piece 102c is slower, the cooling piece 102c can achieve a slower and uniform cooling effect, the overturning is avoided to be too fast, and the side surface of the air cylinder 104 does not achieve a better cooling effect; when the cooling element 102c is turned over to be parallel to the upper end surface of the air cylinder 104, the cooling element 102c is not moved, and the lifting element 102a does not drive the cooling element 102c to move; when the motor is turned off, i.e. after heat dissipation is completed, the reset element 101c drives the motor 101a to rotate reversely, and at this time, the cooling element 102c moves from the upper end surface of the cylinder 104 to the side surface of the cylinder 104 in the same manner as described above.

In summary, the motor 101a is used as a drive, the cooling element 102c is slowly moved and reversely rotated from the side surface of the cylinder 104 through the annular rack 103c and the lifting element 102a, and in the process, the cooling assembly 102 and the cooler 105 continuously perform water cooling and heat dissipation; when the cooling element 102c is parallel to the upper end surface of the cylinder 104, the cooling element 102c does not move any more, but the cooler 105 and the motor 101a still work; when the motor 101a stops working, the reset element 101c drives the motor 101a to complete the reset of the cooling element 102c.

Example 3

Referring to fig. 1 to 10, a third embodiment of the present application is different from the previous embodiment in that: the device further comprises a driving assembly 101, an executing assembly 103 arranged at the upper end of the driving assembly 101, a cooling assembly 102 arranged on the executing assembly 103, a cooler 105 arranged between the cooling assemblies 102, a heat dissipation assembly 108 arranged on one side of the cooling assembly 102, a connecting bracket 106 arranged on the outer side of the cooler 105, a cooling pipeline 107 arranged on the cooler 105 and a cylinder 104 arranged between the driving assembly 101 and the cooler 105.

The driving assembly 101 includes a motor 101a, a rotating shaft 101b disposed at one end of the motor 101a, and a reset element 101c disposed on the rotating shaft 101 b.

The cooling assembly 102 includes a rail member 102b, a lift member 102a disposed on one side of the rail member 102b, and a cooling member 102c disposed on the other side of the rail member 102 b.

The actuator assembly 103 includes a center plate 103a, a link 103b disposed outside the center plate 103a, and an annular rack 103c disposed at the other end of the link 103 b.

The reset piece 101c comprises a spring 101c-1, a fixed strip 101c-2 arranged at one end of the spring 101c-1, a rotary fluted disc 101c-3 arranged at one side of the spring 101c-1, and a fixed shell piece 101c-4 arranged at the outer side of the rotary fluted disc 101 c-3.

The stationary housing part 101c-4 includes a casing 101c-7, a supporting frame 101c-5 provided outside the casing 101c-7, and a movable pawl 101c-6 provided inside the casing 101 c-7.

The heat dissipation assembly 108 includes a side heat dissipation bar 108a, a heat dissipation bar connecting rod 108i disposed at one end of the side heat dissipation bar 108a, a vertical threaded rod 108b disposed at one side of the heat dissipation bar connecting rod 108i, a meshing gear 108f disposed at one end of the vertical threaded rod 108b, a meshing rack 108c disposed at one side of the meshing gear 108f, a meshing rack guide rail 108h disposed at the outer side of the meshing rack 108c, an upper heat dissipation bar 108d disposed at one end of the meshing rack 108c, a sponge bar 108e disposed below the upper heat dissipation bar 108d, a limit frame 108j disposed on the meshing gear 108f, and a guide rail connecting frame 108g disposed at the outer side of the meshing rack guide rail 108 h.

Preferably, the side heat dissipating strips 108a and the upper heat dissipating strip 108d are connected to water pipes, and the side heat dissipating strips 108a and the upper heat dissipating strip 108d are hollow, and can slowly discharge water to the cylinder 104 for cooling.

Preferably, the heat sink assembly 108 is provided in four.

Preferably, the meshing rack rail 108h is secured to the rail member 102b by a rail attachment bracket 108 g; the heat sink bar connecting bar 108i is fixed to the movable block 102 a-4.

Preferably, the engaging gear 108f is fixed to the engaging rack rail 108h by a limiting frame 108j, and the limiting frame 108j is embedded in the engaging gear 108f, so that the rotation of the engaging gear 108f is not affected.

Preferably, the engagement gear 108f is threadedly coupled to the vertical threaded rod 108 b.

When the movable block 102a-4 moves upwards, the side radiating strip 108a moves upwards along with the movement, the vertical threaded rod 108b passes through the meshing gear 108f, the meshing gear 108f rotates, the meshing gear 108f is meshed with the meshing rack 108c, the meshing rack 108c translates along the meshing rack guide rail 108h, and the side radiating strip 108a and the upper radiating strip 108d cover a layer of water on the outer surface of the air cylinder 104, so that the heat dissipation effect on the air cylinder 104 is improved.

The lifting member 102a includes a screw 102a-1, a bevel gear 101a-2 provided at one end of the screw 102a-1, a fixed head 101a-5 provided at the other end of the screw 102a-1, a movable block 102a-4 provided on the screw 102a-1, and a fixed frame 102a-3 provided at one side of the fixed head 101 a-5.

The rail member 102b includes a rail housing 102b-1, a rail groove 102b-2 provided in the rail housing 102b-1, and a barrier rib 102b-3 provided in the rail groove 102 b-2.

The cooling member 102c includes a first movable plate 102c-1, a second movable plate 102c-2 provided at one side of the first movable plate 102c-1, a roller 102c-3 provided at one side of the first movable plate 102c-1 and the second movable plate 102c-2, a link shaft 102c-4 provided on the roller 102c-3, and a pull rod 102c-7 provided between the first movable plate 102c-1 and the second movable plate 102 c-2.

The first movable plate 102c-1 is provided with a groove 102c-5 and a fin 102c-6 disposed in the groove 102 c-5.

The spiral spring 101c-1 is threaded, one end of which is fixed to the rotary shaft 101b, and the other end of which is fixed to the fixing strip 101 c-2; one end of the fixing strip 101c-2 is fixed with the rotary fluted disc 101 c-3; the rotary fluted disc 101c-3 is arranged inside the casing 101c-7, barbs are arranged inside the casing 101c-7 and used for connecting the rotary fluted disc 101c-3, and the rotation of the rotary fluted disc 101c-3 is not affected; the movable pawl 101c-6 is disposed on the inner sidewall of the housing 101c-7 and does not interfere with the counterclockwise rotation of the rotary toothed disc 101c-3, but prevents the clockwise rotation of the rotary toothed disc 101 c-3.

Preferably, the bevel gear 101a-2 is meshed with the annular rack 103c, and when the annular rack 103c rotates, the screw rod 102a-1 is driven to rotate by the bevel gear 101a-2, and at the moment, the movable block 102a-4 moves on the screw rod 102 a-1; the threaded port of the screw rod 102a-1 is spaced from the threaded port of the screw rod 102a-1, and when the movable block 102a-4 moves to the threaded port, the movable block 102a-4 is separated from the threads, and the movable block 102a-4 presses the spring at one end of the fixed head 101a-5 and maintains this state.

Preferably, the link shaft 102c-4 penetrates one of the rollers 102c-3 on the side surface of the second movable plate 102c-2 to connect the second movable plate 102c-2 and the movable block 102a-4, and the link shaft 102c-4 does not affect the rotation of the roller 102 c-3; the second movable plate 102c-2 is raised by the link shaft 102c-4 along with the raising of the movable block 102 a-4; both ends of the pull rod 102c-7 are respectively hinged with the first movable plate 102c-1 and the second movable plate 102 c-2; the primary purpose of the pull rod 102c-7 is to allow the first movable plate 102c-1 to move with the second movable plate 102 c-2.

Preferably, the guide rail frame 102b-1 and the guide rail groove 102b-2 are L-shaped, wherein the corners of the guide rail groove 102b-2 are provided with arc chamfers, so that the roller 102c-3 of the first movable plate 102c-1 can smoothly pass through the corners, and then the first movable plate 102c-1 smoothly completes ninety-degree overturning; one end of the rail frame 102b-1 is fixed to the connection bracket 106, and since the cooler 105 is fixed to the cylinder 104, the position of the rail frame 102b-1 cannot be changed.

Preferably, eight fins 102c-6 are provided in the groove 102c-5 of the first movable plate 102c-1, and the fins 102c-6 have a main function of enhancing the cooling effect.

Preferably, a hollow area exists inside the first movable plate 102c-1 for circulating cooling water.

When in use, the cooler 105 is firstly opened, so that cooling water flows to each cooling piece 102c, and the heat dissipation effect is started; then, the motor is turned on, so that the motor 101a drives the annular rack 103c to rotate; simultaneously, the spring 101c-1 is tightened to the maximum extent and drives the rotary fluted disc 101c-3 to rotate anticlockwise; at this time, the movable block 102a-4 drives the second movable plate 102c-2 to slowly move upwards; when the movable block 102a-4 moves to the maximum extent and is separated from the threads of the screw rod 102a-1, the second movable plate 102c-2 drives the first movable plate 102c-1 to move and turn along the guide rail groove 102b-2 through the pull rod 102c-7, and at this time, the first movable plate 102c-1 is leveled with the upper end surface of the air cylinder 104; after the cooling work of the air cylinder 104 is completed, the motor stops working, at the moment, the spring 101c-1 is released to drive the rotating shaft 101b to rotate reversely, and at the moment, the rotating fluted disc 101c-3 does not rotate any more due to the movable pawl 101 c-6; the movable block 102a-4 smoothly enters the screw thread of the screw rod 102a-1 due to the extrusion of the spring at one end of the fixed head 101a-5, and continuously moves downwards, and the first movable plate 102c-1 is reset, and finally, the cooler 105 is closed.

In summary, the forward rotation and the reverse rotation of the screw rod 102a-1 are realized through the forward rotation and the reverse rotation of the motor 101a, so that the movable block 102a-4 completes the ascending and descending work, and the cooling part 102c is driven by the connecting rod shaft 102c-4 to complete the moving, overturning and resetting along the guide rail part 102 b.

It is important to note that the construction and arrangement of the application as shown in the various exemplary embodiments is illustrative only. Although only a few embodiments have been described in detail in this disclosure, those skilled in the art who review this disclosure will readily appreciate that many modifications are possible (e.g., variations in sizes, dimensions, structures, shapes and proportions of the various elements, values of parameters (e.g., temperature, pressure, etc.), mounting arrangements, use of materials, colors, orientations, etc.) without materially departing from the novel teachings and advantages of the subject matter described in this application. For example, elements shown as integrally formed may be constructed of multiple parts or elements, the position of elements may be reversed or otherwise varied, and the nature or number of discrete elements or positions may be altered or varied. Accordingly, all such modifications are intended to be included within the scope of present application. The order or sequence of any process or method steps may be varied or re-sequenced according to alternative embodiments. In the claims, any means-plus-function clause is intended to cover the structures described herein as performing the recited function and not only structural equivalents but also equivalent structures. Other substitutions, modifications, changes and omissions may be made in the design, operating conditions and arrangement of the exemplary embodiments without departing from the scope of the present applications. Therefore, the application is not limited to the specific embodiments, but extends to various modifications that nevertheless fall within the scope of the appended claims.

Furthermore, in order to provide a concise description of the exemplary embodiments, all features of an actual implementation may not be described (i.e., those not associated with the best mode presently contemplated for carrying out the application, or those not associated with practicing the application).

It should be appreciated that in the development of any such actual implementation, as in any engineering or design project, numerous implementation-specific decisions may be made. Such a development effort might be complex and time consuming, but would nevertheless be a routine undertaking of design, fabrication, and manufacture for those of ordinary skill having the benefit of this disclosure.

It should be noted that the above embodiments are only for illustrating the technical solution of the present application and not for limiting the same, and although the present application has been described in detail with reference to the preferred embodiments, it should be understood by those skilled in the art that the technical solution of the present application may be modified or substituted without departing from the spirit and scope of the technical solution of the present application, which is intended to be covered in the scope of the claims of the present application.

Claims (10)

1. Diversified cooling device of cylinder, its characterized in that: comprising the steps of (a) a step of,

the cooling device comprises a driving assembly (101), an executing assembly (103) arranged at the upper end of the driving assembly (101), a cooling assembly (102) arranged on the executing assembly (103), a cooler (105) arranged between the cooling assemblies (102), a heat dissipation assembly (108) arranged on one side of the cooling assembly (102), a connecting bracket (106) arranged on the outer side of the cooler (105), a cooling pipeline (107) arranged on the cooler (105) and a cylinder (104) arranged between the driving assembly (101) and the cooler (105).

2. The cylinder multi-azimuth cooling device of claim 1, wherein: the driving assembly (101) comprises a motor (101 a), a rotating shaft (101 b) arranged at one end of the motor (101 a), and a reset piece (101 c) arranged on the rotating shaft (101 b).

3. The cylinder multi-azimuth cooling device of claim 2, wherein: the cooling assembly (102) comprises a guide rail piece (102 b), a lifting piece (102 a) arranged on one side of the guide rail piece (102 b) and a cooling piece (102 c) arranged on the other side of the guide rail piece (102 b).

4. A cylinder multi-azimuth cooling device as claimed in claim 3, wherein: the execution assembly (103) comprises a center disc (103 a), a connecting rod (103 b) arranged on the outer side of the center disc (103 a), and an annular rack (103 c) arranged on the other end of the connecting rod (103 b).

5. The cylinder multi-azimuth cooling device of claim 4, wherein: the reset piece (101 c) comprises a spring (101 c-1), a fixed strip (101 c-2) arranged at one end of the spring (101 c-1), a rotary fluted disc (101 c-3) arranged at one side of the spring (101 c-1), and a fixed shell piece (101 c-4) arranged at the outer side of the rotary fluted disc (101 c-3);

the fixed shell (101 c-4) comprises a casing (101 c-7), a supporting frame (101 c-5) arranged on the outer side of the casing (101 c-7), and a movable pawl (101 c-6) arranged on the inner side of the casing (101 c-7).

6. The cylinder multi-azimuth cooling device of claim 5, wherein: the heat dissipation assembly (108) comprises a side heat dissipation strip (108 a), a heat dissipation strip connecting rod (108 i) arranged at one end of the side heat dissipation strip (108 a), a vertical threaded rod (108 b) arranged at one side of the heat dissipation strip connecting rod (108 i), a meshing gear (108 f) arranged at one end of the vertical threaded rod (108 b), a meshing rack (108 c) arranged at one side of the meshing gear (108 f), a meshing rack guide rail (108 h) arranged at the outer side of the meshing rack (108 c), an upper heat dissipation strip (108 d) arranged at one end of the meshing rack (108 c), a sponge strip (108 e) arranged below the upper heat dissipation strip (108 d), a limiting frame (108 j) arranged on the meshing gear (108 f) and a guide rail connecting frame (108 g) arranged at the outer side of the meshing rack guide rail (108 h).

7. A cylinder multi-azimuth cooling device according to claim 3 or 6, wherein: the lifting piece (102 a) comprises a screw rod (102 a-1), a bevel gear (101 a-2) arranged at one end of the screw rod (102 a-1), a fixed head (101 a-5) arranged at the other end of the screw rod (102 a-1), a movable block (102 a-4) arranged on the screw rod (102 a-1), and a fixed frame (102 a-3) arranged at one side of the fixed head (101 a-5).

8. The cylinder multi-azimuth cooling device of claim 7, wherein: the guide rail piece (102 b) comprises a guide rail frame (102 b-1), a guide rail groove (102 b-2) arranged in the guide rail frame (102 b-1), and a barrier strip (102 b-3) arranged in the guide rail groove (102 b-2).

9. A cylinder multi-azimuth cooling device according to claim 3 or 8, wherein: the cooling element (102 c) comprises a first movable plate (102 c-1), a second movable plate (102 c-2) arranged on one side of the first movable plate (102 c-1), rollers (102 c-3) arranged on one side of the first movable plate (102 c-1) and the second movable plate (102 c-2), a connecting rod shaft (102 c-4) arranged on the rollers (102 c-3), and a pull rod (102 c-7) arranged between the first movable plate (102 c-1) and the second movable plate (102 c-2).

10. The cylinder multi-azimuth cooling device of claim 9, wherein: the first movable plate (102 c-1) is provided with a groove (102 c-5) and a fin (102 c-6) arranged in the groove (102 c-5).