CN112068681A - Damper shock attenuation convulsions radiating data server device - Google Patents

Abstract

The invention discloses a data server device with damper for damping, air draft and heat dissipation, which comprises a heat dissipation damping box, a shock absorption cavity with a forward opening is arranged in the heat dissipation shock absorption box, two sliding pipes are fixedly connected between the side walls of the shock absorption cavity, the side walls of the shock absorption cavity are far away from each other, the two sliding pipes are symmetrically distributed and arranged in a left-right mode by taking the central line of the shock absorption cavity as a symmetric center, six damping slide blocks are connected on the peripheral surface of the sliding pipe in a sliding way, and are distributed symmetrically left and right by taking the central line of the damping cavity as a symmetric center, the heat generated by the data server is quickly discharged by carrying out the heat dissipation treatment of the air draft type and the rotation of the fan on a large amount of heat generated by the data server, and when the periphery of the data server vibrates, the damper consisting of the cam and the spring is used for buffering and absorbing shock for the data server to prevent the data server from being damaged or powered off due to vibration.

Description

Damper shock attenuation convulsions radiating data server device

Technical Field

The invention relates to the field related to data servers, in particular to a data server device with a damper for shock absorption, air draft and heat dissipation.

Background

In a series of heat dissipation and shock absorption devices of a traditional data server, the air-draft type heat dissipation treatment is not performed on a large amount of heat generated by the data server during data processing, and when vibration occurs around the data server, the data server is not buffered and damped through some mechanisms or dampers, so that the data server is damaged or powered off due to vibration and data loss occurs.

Disclosure of Invention

In order to solve the problems, the embodiment designs a data server device for damping, exhausting and radiating of a damper, the data server device for damping, exhausting and radiating of the damper comprises a radiating damping box, a damping cavity with a forward opening is arranged in the radiating damping box, two sliding pipes are fixedly connected between the side walls of the damping cavity, the two sliding pipes are distributed and arranged in a bilateral symmetry mode by taking the central line of the damping cavity as a symmetry center, six damping slide blocks are connected on the outer peripheral surface of the sliding pipes in a sliding mode, the six damping slide blocks are distributed and arranged in a bilateral symmetry mode by taking the central line of the damping cavity as a symmetry center, one end of each damping slide block, which is close to each other, is fixedly connected with a damping spring, the outer peripheral surface of each sliding pipe is wound and connected on the outer peripheral surface of the damping spring, the damping spring is fixedly connected on the side wall of the damping, the supporting and shock-absorbing frame is rotatably connected with a second shock-absorbing shaft at one end close to each other, the second shock-absorbing shaft is rotatably connected with a swinging shock-absorbing rod at one end close to each other, an intermediate shaft is rotatably connected between the swinging shock-absorbing rods, one end of the intermediate shaft close to each other is fixedly connected with a first shock-absorbing shaft, one end of the first shock-absorbing shaft close to each other is fixedly connected with a damping side plate, one end of the damping side plate close to each other is fixedly connected with three pressure-resisting rods, the three pressure-resisting rods are distributed and arranged in a bilateral symmetry mode by taking the central line of the shock-absorbing cavity as a symmetry center, one end of the pressure-resisting rods close to each other is rotatably connected with a wheel shaft, the front end of the wheel shaft is rotatably connected with a damping cam, a movable rod is rotatably connected between the two wheel shafts, a spring cavity, the two fixing blocks are arranged in bilateral symmetry with the damping cavity central line as a symmetry center, two damping cavities with opposite openings are arranged at the ends, far away from each other, of the damping side plates, the two damping cavities are arranged in bilateral symmetry with the damping side plate central line as a symmetry center, the damping cavities are mutually far away from the side walls and fixedly connected with side springs, the side springs are mutually close to one end and fixedly connected with supporting rods, the supporting rods are mutually close to one end and slidably connected with a pressing-close damping plate, the ends, close to each other, of the damping cams are in contact connection with the ends, far away from each other, of the pressing-close damping plates, when a data server in the damping cavities vibrates due to natural reasons and the like, the data server is prevented from power failure or even data loss, the data server is in contact with the pressing-close damping, thereby compressing the support rod and the side spring and further driving the damping cam to rotate, the rotation of the damping cam can adjust and absorb the vibration according to the vibration frequency of the data server, further driving the wheel shaft to rotate, the rotation of the wheel shaft further driving the movable rods to move close to each other and further compressing the transverse damping spring, the transverse damping spring absorbs the vibration generated by the data server by a first wave, the rotation of the wheel shaft drives the pressing rod and the damping side plate to move, further driving the first vibration absorbing shaft to move, further driving the intermediate shaft to rotate, further driving the swinging vibration absorbing rod to swing, further driving the second vibration absorbing shaft to rotate, further driving the support vibration absorbing frame to move, further driving the vibration absorbing slide blocks to move away from or close to each other and further compressing or stretching the damping spring, so that the damping slide block stably slides on the peripheral surface of the slide pipe, and the damping spring absorbs the second wave of the data server.

Preferably, a fixing frame is fixedly connected to the rear wall of the damping cavity, a sliding rack is fixedly connected to one end, close to each other, of the fixing frame, a cooling cavity with a forward opening is arranged in the sliding rack, a driving motor is fixedly connected to the upper wall of the cooling cavity, a power shaft is connected to the lower end of the driving motor in a power mode, a stop block is connected to the lower end of the power shaft in a rotating mode, a rotating wheel is fixedly connected to the outer peripheral surface of the power shaft, an extension rope is wound and connected to the outer peripheral surface of the rotating wheel, two rollers are rotatably connected to the rear wall of the cooling cavity and are distributed in a bilateral symmetry mode with the center line of the cooling cavity as the center line of symmetry, the extension ropes are far away from each other and extend downwards to be fixedly connected with a dragging rotating block, and starting the driving motor to drive the power shaft to rotate so as to drive the rotating wheel to rotate, so that the extension rope extends downwards, the extension rope extends downwards to drive the roller to rotate, and the extension rope extends to prepare for cooling on the next step.

Preferably, the inner peripheral surface of the dragging and rotating block is rotatably connected with a rotating shaft, one end of the rotating shaft, which is far away from each other, is fixedly connected with an accelerating gear, the outer peripheral surface of the accelerating gear is meshed with the front end surface of the sliding rack, one end of the rotating shaft, which is close to each other, is fixedly connected with a fan blade fixer, the outer peripheral surface of the fan blade fixer is fixedly connected with six cooling fan blades, the rear wall of the cooling cavity is in contact connection with a server, when the extension rope extends downwards, the rotating shaft, the fan blade fixer and the accelerating gear are driven to rotate, the rotation of the accelerating gear is meshed downwards along the sliding rack to slide downwards, the rotation of the accelerating gear plays an accelerating role on the fan blade fixer and the rotating shaft so that the fan blade fixer rotates more quickly, and the fan blade fixer rotates to, the cooling fan blades further cool the data server.

Preferably, four horizontal springs are fixedly connected to the left side wall and the right side wall of the damping cavity, the two horizontal springs on the left side and the right side are distributed and arranged in a bilateral symmetry mode with the horizontal center line of the damping cavity as a symmetry center, one end, close to each other, of each horizontal spring is fixedly connected to one end, far away from one end, in the vertical direction of the damping side plate, of each horizontal spring, when the data server vibrates, the damping side plates move and then compress the horizontal springs, and the horizontal springs compress the vibration of the data server to absorb the vibration of the data server so as to prevent the data server.

Preferably, four air blowers of fixedly connected with on the wall behind the shock attenuation chamber, four the air blower with the shock attenuation chamber central line is the symmetric distribution setting about the symmetric center, the air blower is close to one end fixedly connected with heat absorber each other, the one end fixedly connected with radiator is kept away from each other to the air blower, the outside extension of radiator is equipped with the thermovent, the thermovent intercommunication shock attenuation chamber and external world, when data server was overheated, start this moment the air blower, and then through the heat absorber will the heat in the shock attenuation chamber is absorbed extremely in the air blower, the rethread the radiator will be absorbed heat and discharge to the external world to reach the cooling process to data server.

The invention has the beneficial effects that: can carry out the pivoted heat dissipation processing of air-draft and fan to a large amount of heats that data server produced when data server carries out data processing, with the quick discharge of the heat that data server produced to through the attenuator that cam and spring constitute to data server when taking place vibrations around the data server, cushion the shock attenuation and prevent that data server from damaging or cutting off the power supply because of vibrations.

Drawings

In order to more clearly illustrate the embodiments of the invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the invention, and it is obvious for those skilled in the art that other drawings can be obtained based on these drawings without creative efforts.

The invention is further illustrated with reference to the following figures and examples.

FIG. 1 is a schematic diagram of the overall structure of a damper-damped air-draft heat-dissipating data server device according to the present invention;

FIG. 2 is an enlarged schematic view of A in FIG. 1;

FIG. 3 is an enlarged schematic view of B of FIG. 1;

FIG. 4 is an enlarged schematic view of C in FIG. 1;

FIG. 5 is an enlarged schematic view of D of FIG. 1;

FIG. 6 is a schematic diagram of the structure of E-E in FIG. 4;

FIG. 7 is a schematic view of the structure of F-F in FIG. 4;

fig. 8 is a schematic diagram of the structure of G-G in fig. 5.

Detailed Description

The invention will now be described in detail with reference to fig. 1-8, wherein for ease of description the orientations described below are now defined as follows: the up, down, left, right, and front-back directions described below correspond to the up, down, left, right, and front-back directions in the projection relationship of fig. 1 itself.

The data server device for the shock absorption, air draft and heat dissipation of the damper comprises a heat dissipation shock absorption box 11, a shock absorption cavity 12 with a forward opening is arranged in the heat dissipation shock absorption box 11, two sliding pipes 25 are fixedly connected between the side walls of the shock absorption cavity 12 far away from each other, the two sliding pipes 25 are symmetrically distributed and arranged with the center line of the shock absorption cavity 12 as the symmetric center, six shock absorption slide blocks 27 are slidably connected on the outer peripheral surface of the sliding pipes 25, the six shock absorption slide blocks 27 are symmetrically distributed and arranged with the center line of the shock absorption cavity 12 as the symmetric center, one end of the shock absorption slide block 27 close to each other is fixedly connected with a damping spring 26, the outer peripheral surface of the sliding pipe 25 is wound and connected on the outer peripheral surface of the damping spring 26, the damping spring 26 is fixedly connected on the side wall of the shock absorption cavity 12, one end of, the supporting and shock absorbing frame 52 is rotatably connected with a second shock absorbing shaft 49 at one end close to each other, the second shock absorbing shaft 49 is rotatably connected with a swing shock absorbing rod 51 at one end close to each other, an intermediate shaft 28 is rotatably connected between the swing shock absorbing rods 51, a first shock absorbing shaft 50 is fixedly connected at one end close to each other of the intermediate shaft 28, a damping side plate 30 is fixedly connected at one end close to each other of the first shock absorbing shaft 50, three pressure resisting rods 35 are fixedly connected at one end close to each other of the damping side plate 30, the three pressure resisting rods 35 are distributed and arranged in a bilateral symmetry mode by taking the central line of the shock absorbing cavity 12 as a symmetry center, a wheel shaft 38 is rotatably connected at one end close to each other of the pressure resisting rods 35, a damping cam 37 is rotatably connected at the front end of the wheel shaft 38, a movable rod 31 is rotatably connected between the two wheel shafts 38, a spring, the lateral damping spring 34 and the lateral damping spring 34 are connected with two fixed blocks 32 in a sliding manner on the outer peripheral surface, the two fixed blocks 32 are arranged in a symmetrical and bilateral symmetrical manner by taking the central line of the damping cavity 12 as the symmetrical center, the damping side plate 30 is far away from one end to be provided with two damping cavities 29 with opposite openings, the two damping cavities 29 are arranged in a symmetrical and bilateral symmetrical manner by taking the central line of the damping side plate 30 as the symmetrical center, the damping cavities 29 are far away from the side wall to be fixedly connected with side springs 41, the side springs 41 are close to one end fixedly connected with supporting rods 40, the supporting rods 40 are close to one end to be connected with the damping plates 36 in a sliding manner, the damping cams 37 are close to one end to be connected with the damping plates 36 which are far away from one end to be contacted, when a data server in the, in order to avoid power failure or even data loss of the data server, the data server contacts the proximate damping plate 36, the proximate damping plate 36 is driven to move, the supporting rod 40 and the side spring 41 are compressed, and the damping cam 37 is driven to rotate, the rotation of the damping cam 37 is adjusted according to the frequency of the data server vibration and absorbs the vibration, and then the wheel shaft 38 is driven to rotate, the wheel shaft 38 rotates to drive the moving rod 31 to move close to each other, and then the transverse damping spring 34 is compressed, the transverse damping spring 34 absorbs the vibration generated by the data server, and the wheel shaft 38 rotates to drive the abutting rod 35 and the damping side plate 30 to move, and then the first damping shaft 50 is driven to move, and then the intermediate shaft 28 is driven to rotate, and then drive the swing to inhale shake pole 51 swing, and then drive the rotation of second axle 49 that shakes, and then drive support inhale shake frame 52 and remove, and then drive shock attenuation slider 27 is kept away from each other or is close to the removal each other, and then compression or extension damping spring 26 for shock attenuation slider 27 is in the stable slip on the sliding tube 25 outer peripheral face, damping spring 26 carries out the absorption of second ripples to the data server.

Beneficially, a fixed frame 23 is fixedly connected to the rear wall of the damping cavity 12, a sliding rack 22 is fixedly connected to one end of the fixed frame 23 close to each other, a cooling cavity 13 with a forward opening is arranged in the sliding rack 22, a driving motor 18 is fixedly connected to the upper wall of the cooling cavity 13, a power shaft 16 is in power connection with the lower end of the driving motor 18, a stop 21 is in rotation connection with the lower end of the power shaft 16, a rotating wheel 19 is fixedly connected to the outer peripheral surface of the power shaft 16, an extension rope 17 is wound and connected to the outer peripheral surface of the rotating wheel 19, two rollers 20 are in rotation connection with the rear wall of the cooling cavity 13, the two rollers 20 are distributed and arranged in bilateral symmetry with the central line of the cooling cavity 13 as the symmetry center, the extension rope 17 is far away from each other and extends downwards to be fixedly connected with a, when the data server is overheated due to overload, the driving motor 18 is started at the moment, so that the power shaft 16 is driven to rotate, the rotating wheel 19 is driven to rotate, the extension rope 17 extends downwards to drive the roller 20 to rotate, and at the moment, the extension rope 17 is extended to prepare for cooling in the next step.

Advantageously, a rotating shaft 48 is rotatably connected to an inner peripheral surface of the dragging and rotating block 47, an accelerating gear 46 is fixedly connected to an end of the rotating shaft 48 away from each other, an outer peripheral surface of the accelerating gear 46 is engaged and connected to a front end surface of the sliding rack 22, a fan blade holder 44 is fixedly connected to an end of the rotating shaft 48 close to each other, six cooling fan blades 45 are fixedly connected to an outer peripheral surface of the fan blade holder 44, a server 15 is in contact connection with a rear wall of the cooling chamber 13, when the extension cord 17 extends downward, the rotating shaft 48, the fan blade holder 44 and the accelerating gear 46 are driven to rotate, the rotating shaft 46 rotates and slides downward along the sliding rack 22 in an engaged manner, the rotating shaft 46 accelerates the fan blade holder 44 and the rotating shaft 48 so that the fan blade holder 44 rotates more rapidly, the fan blade holder 44 rotates to drive the cooling fan blades 45 to rotate rapidly, and the cooling fan blades 45 further cool the data server.

Beneficially, four horizontal springs 14 are fixedly connected to the left and right side walls of the damping cavity 12, the two horizontal springs 14 on the left and right sides are symmetrically distributed with the horizontal center line of the damping cavity 12 as a symmetry center, one end of each horizontal spring 14 close to each other is fixedly connected to one end of each damping side plate 30 far away from each other in the vertical direction, when the data server vibrates, the damping side plates 30 move to further compress the horizontal springs 14, and the compression of the horizontal springs 14 absorbs the vibration of the data server to prevent the data server from being damaged.

Beneficially, four air blowers 42 are fixedly connected to the rear wall of the damping cavity 12, the four air blowers 42 are arranged in a left-right symmetrical distribution mode by taking the central line of the damping cavity 12 as a symmetrical center, the air blowers 42 are close to one end fixedly connected with heat absorbers 39, the air blowers 42 are far away from one end fixedly connected with radiators 24, the radiators 24 are provided with radiating ports 43 in an outward extending mode, the radiating ports 43 are communicated with the damping cavity 12 and the outside, when a data server is overheated, the air blowers 42 are started at the moment, and then the heat absorbers 39 absorb heat in the damping cavity 12 into the air blowers 42, and the absorbed heat is discharged to the outside through the radiators 24, so that the cooling treatment of the data server is achieved.

The following describes in detail the use steps of a damper shock-absorbing, air-extracting and heat-dissipating data server device in the present document with reference to fig. 1 to 8: initially, the driving motor 18 and the exhaust fan 42 are in a closed state, the extension rope 17 is in a contracted state, the cooling fan blades 45, the fan blade holders 44, the rotating shaft 48, the dragging and rotating block 47 and the accelerating gear 46 are in any positions in the cooling cavity 13, the damping sliding block 27, the intermediate shaft 28, the damping side plate 30, the pressing rod 35, the damping cam 37 and the pressing damping plate 36 are in any positions, the horizontal spring 14 is in a loose state, the swinging shock-absorbing rod 51, the second shock-absorbing shaft 49, the first shock-absorbing shaft 50 and the supporting shock-absorbing frame 52 are in any positions, and the damping spring 26 is in a loose state.

When the shock absorption device is used, when a data server in the shock absorption cavity 12 vibrates due to natural reasons and the like, in order to avoid power failure or even data loss of the data server, the data server is in contact with the damping plate 36, the damping plate 36 is driven to move by being close to the data server, the supporting rod 40 and the side spring 41 are compressed, the damping cam 37 is driven to rotate, the damping cam 37 rotates to adjust and absorb shock according to the frequency of the data server, the wheel shaft 38 is driven to rotate, the wheel shaft 38 rotates to drive the moving rod 31 to move close to each other, the transverse damping spring 34 is compressed, the transverse damping spring 34 absorbs the shock generated by the data server, the wheel shaft 38 rotates to drive the abutting rod 35 and the damping side plate 30 to move, the first shock absorption shaft 50 is driven to move, and the intermediate shaft 28 is driven to rotate, and then drive the swing and inhale the swing of shake pole 51, and then drive the second and inhale shake axle 49 and rotate, and then drive and support and inhale shake frame 52 and remove, and then drive shock attenuation slider 27 and keep away from each other or be close to the removal each other, and then compression or extension damping spring 26 for shock attenuation slider 27 is stable slip on the slide pipe 25 outer peripheral face, damping spring 26 carries out the absorption of second ripples to data server, the removal of damping curb plate 30 and then compression horizontal spring 14 this moment, horizontal spring 14 compression carries out the absorbing action to data server's vibrations and prevents that data server from damaging.

When the data server is overheated due to overload, the driving motor 18 is started at the moment, the power shaft 16 is further driven to rotate, the rotating wheel 19 is further driven to rotate, the extension rope 17 extends downwards to drive the roller 20 to rotate, the extension of the extension rope 17 is further prepared for cooling on the next step, when the extension rope 17 extends downwards, the rotating shaft 48, the fan blade fixer 44 and the accelerating gear 46 are driven to rotate, the rotation of the accelerating gear 46 is meshed and slides downwards along the sliding rack 22, the rotation of the accelerating gear 46 plays an accelerating role in rotating the fan blade fixer 44 and the rotating shaft 48 to enable the fan blade fixer 44 to rotate more quickly, the fan blade fixer 44 rotates to drive the cooling fan blades 45 to rotate quickly, and the cooling fan blades 45 are further used for cooling the data server.

When the data server is overheated, the exhaust fan 42 is started, heat in the shock absorption cavity 12 is absorbed into the exhaust fan 42 through the heat absorber 39, and the absorbed heat is exhausted to the outside through the radiator 24, so that the cooling treatment of the data server is achieved.

The invention has the beneficial effects that: the invention can perform air draft type and fan rotation heat dissipation treatment on a large amount of heat generated by the data server when the data server performs data processing, quickly discharge the heat generated by the data server, and perform buffering and shock absorption on the data server through the damper consisting of the cam and the spring when the periphery of the data server vibrates, thereby preventing the data server from being damaged or powered off due to vibration.

The above embodiments are merely illustrative of the technical ideas and features of the present invention, and the purpose thereof is to enable those skilled in the art to understand the contents of the present invention and implement the present invention, and not to limit the protection scope of the present invention. All equivalent changes and modifications made according to the spirit of the present invention should be covered within the protection scope of the present invention.

Claims (5)

1. The utility model provides a radiating data server device of attenuator shock attenuation convulsions, includes the heat dissipation damper box, its characterized in that: a shock absorption cavity with a forward opening is arranged in the heat dissipation shock absorption box, two sliding pipes are fixedly connected between the far side walls of the shock absorption cavity, the two sliding pipes are arranged in a bilateral symmetry manner by taking the central line of the shock absorption cavity as a symmetry center, six shock absorption sliding blocks are connected on the outer peripheral surfaces of the sliding pipes in a sliding manner, the six shock absorption sliding blocks are arranged in a bilateral symmetry manner by taking the central line of the shock absorption cavity as a symmetry center, the shock absorption sliding blocks are mutually close to one end and fixedly connected with a damping spring, the outer peripheral surfaces of the sliding pipes are wound and connected on the outer peripheral surface of the damping spring, the damping spring is fixedly connected on the side walls of the shock absorption cavity, the shock absorption sliding blocks are mutually close to one end up and down and are fixedly connected with a supporting shock absorption frame, one end of the, an intermediate shaft is rotatably connected between the swinging shock absorption rods, a first shock absorption shaft is fixedly connected at one end of the intermediate shaft, which is close to each other from top to bottom, a damping side plate is fixedly connected at one end of the first shock absorption shaft, three pressure-resisting rods are fixedly connected at one end of the damping side plate, which is close to each other, and are distributed in a bilateral symmetry manner by taking the central line of the shock absorption cavity as the center of symmetry, wheel shafts are rotatably connected at one ends of the pressure-resisting rods, damping cams are rotatably connected at the front ends of the wheel shafts, a movable rod is rotatably connected between the two wheel shafts, a spring cavity is arranged between the movable rods, a transverse damping spring is fixedly connected between the movable rods, two fixed blocks are slidably connected with the outer peripheral surfaces of the transverse damping springs, and are distributed in a bilateral symmetry manner by taking, the utility model discloses a damping device, including damping curb plate, lateral wall, bracing piece, damping cam, damping curb plate, lateral wall, lateral.

2. The data server device for damper shock absorption, air draft and heat dissipation of claim 1, wherein: the utility model discloses a damping chamber, including damping chamber, fixed frame, one end fixedly connected with slip rack, be equipped with the cooling chamber that the opening is forward in the slip rack, cooling chamber upper wall fixedly connected with driving motor, driving motor lower extreme power is connected with the power shaft, the power shaft lower extreme rotates and is connected with the dog, fixedly connected with runner on the power shaft outer peripheral face, the winding is connected with the extension rope on the runner outer peripheral face, it is connected with two gyro wheels, two to rotate on the cooling chamber rear wall the gyro wheel with the cooling chamber central line is symmetry center bilateral symmetry and distributes the setting, extension rope is kept away from each other and downwardly extending fixedly connected with pulls the turning block, extension rope outer peripheral face sliding connection in on the gyro wheel outer peripheral face.

3. The data server device for damper shock absorption, air draft and heat dissipation of claim 2, wherein: the inner peripheral surface of the dragging and rotating block is rotatably connected with a rotating shaft, one end of the rotating shaft, which is far away from each other, is fixedly connected with an accelerating gear, the outer peripheral surface of the accelerating gear is meshed and connected with the front end surface of the sliding rack, the rotating shaft is close to one end of a fan blade fixer, six cooling fan blades are fixedly connected to the outer peripheral surface of the fan blade fixer, and a server is in contact connection with the rear wall of the cooling cavity.

4. The data server device for damper shock absorption, air draft and heat dissipation of claim 1, wherein: four horizontal springs are fixedly connected to the left side wall and the right side wall of the damping cavity, the two horizontal springs on the left side and the right side are distributed and arranged in a bilateral symmetry mode with the horizontal center line of the damping cavity as a symmetry center, and one end, close to each other, of each horizontal spring is fixedly connected to one end, far away from each other, of each damping side plate in the vertical direction.

5. The data server device for damper shock absorption, air draft and heat dissipation of claim 1, wherein: four air blowers of fixedly connected with on the wall behind the shock attenuation chamber, four the air blower with the shock attenuation chamber central line is about the symmetric distribution setting from top to bottom for the symmetric center, the air blower is close to one end fixedly connected with heat absorber each other, the air blower keeps away from one end fixedly connected with radiator each other, the radiator outwards extends and is equipped with the thermovent, the thermovent intercommunication shock attenuation chamber and external.

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