CN110902149A

CN110902149A - Computer shock attenuation conveyer

Info

Publication number: CN110902149A
Application number: CN201911276102.5A
Authority: CN
Inventors: 李裔米
Original assignee: Taizhou Jiaojiang Ruijiang Computer Co ltd
Current assignee: Taizhou Jiaojiang Ruijiang Computer Co ltd
Priority date: 2019-12-12
Filing date: 2019-12-12
Publication date: 2020-03-24

Abstract

The invention discloses a computer shock absorption transportation device, which comprises two boxes which are arranged symmetrically left and right, wherein the left and right boxes are connected in a rotating way, opposite end walls of the left and right boxes are provided with computer grooves with outward openings, the bottom wall of the box is provided with shock absorption grooves with downward openings, shock absorption blocks are connected in the shock absorption grooves in a sliding way, rotating wheel mechanisms are symmetrically arranged in the shock absorption blocks front and back, bottom shock absorption mechanisms are symmetrically arranged between the top walls of the shock absorption grooves and the top walls of the shock absorption blocks front and back, a first gear is in power connection with the left and right shock absorption mechanisms, the bottom end of a motor shaft is provided with a motor, the top end of the motor shaft is provided with a top shock absorption mechanism, a computer to be transported is placed in the computer grooves, the left and right boxes are closed, the motor is started, and the computer is protected by sponge blocks, the bottom shock absorption mechanism can reduce the influence of road bumping on the computer.

Description

Computer shock attenuation conveyer

Technical Field

The invention relates to the technical field of computers, in particular to a computer damping and conveying device.

Background

The computer is a modern electronic computing machine for high-speed computing, the application of the computer is more and more common in China, the number of computer users in China is continuously increased, the application level is continuously improved, and particularly, the application in the fields of Internet, communication, multimedia and the like obtains good results.

At present, the desktop computer is still in the dominance of the computer because of its low cost and strong operation capability, but the desktop computer is inconvenient to transport due to its large volume and many components, and is very easy to be damaged in the transportation process, and has low efficiency and inconvenience.

Disclosure of Invention

Aiming at the technical defects, the invention provides a computer damping transportation device which can overcome the defects.

The invention relates to a computer shock-absorbing conveying device, which comprises two box bodies which are arranged in a bilateral symmetry manner, wherein the left box body and the right box body are connected in a rotating manner, opposite end walls of the left box body and the right box body are provided with computer grooves with outward openings, the bottom wall of the box body is provided with shock absorption grooves with downward openings, shock absorption blocks are connected in the shock absorption grooves in a sliding manner, rotating wheel mechanisms are symmetrically arranged in the shock absorption blocks in a front-back manner, bottom shock absorption mechanisms are symmetrically arranged in the front-back manner between the top walls of the shock absorption grooves and the top walls of the shock absorption blocks in the front-back manner, belt cavities with openings facing the direction of the computer grooves are symmetrically arranged in the front-back manner on the end walls of the shock absorption grooves far away from the computer grooves in the front-back manner, bevel gear cavities positioned in the middle positions of the front belt cavities and the back are arranged in the, the first belt wheel shaft is connected with a first belt wheel in a matching way, the first belt wheel shaft is connected with a second belt wheel which is positioned in the direction of the first belt wheel far away from the bevel gear cavity in a matching way, a first gear is arranged in the first gear cavity and is in power connection with the left and right damping mechanisms, the first gear is matched and connected with a first gear shaft, the first gear shaft is rotationally connected with the box body, one end of the first gear shaft, which is far away from the bevel gear cavity, is connected with a third belt wheel in a matching way, the third belt wheel is connected with the first belt wheel through a first belt, one end of the first gear shaft close to the bevel gear cavity is connected with an upper bevel gear positioned in the bevel gear cavity in a matching way, the upper bevel gear is meshed with a lower bevel gear positioned below the upper bevel gear, the lower bevel gear is matched and connected with a motor shaft, the motor shaft bottom is provided with the motor, the motor shaft top is provided with top damper.

Preferably, the rotating wheel mechanism comprises a rotating wheel groove which is arranged in the damping block and is communicated up and down, a second pulley shaft which is rotatably connected with the damping block is arranged above the rotating wheel groove, the second pulley shaft is connected with a fourth pulley in a matching way, the fourth pulley is connected with the second pulley through a second belt, the second pulley shaft is connected with a second gear which is positioned on the fourth pulley and close to the bevel gear cavity in a matching way, the second gear is connected with a third gear positioned below the second gear in a meshing way, the third gear is connected with a second gear shaft in a matching way, the second gear shaft is rotatably connected with the damping block, a first connecting hinge is fixedly connected with one end of the second gear shaft far away from the bevel gear cavity, the first connecting hinge is hinged with an upper connecting frame rod, one end of the upper connecting frame rod far away from the computer groove is hinged with a second connecting hinge, and the second connecting hinge is hinged with a connecting rod, the connecting rod bottom is articulated with a third connecting hinge, the third connecting hinge is articulated with a lower connecting rod, a lower supporting block is fixedly arranged on the end wall of the rotating wheel groove far away from the computer groove, a rotating groove with an opening facing the direction of the computer groove is arranged in the lower supporting block, a rotating shaft is rotatably arranged between the front end wall and the rear end wall of the rotating groove, the rotating shaft is articulated with one end of the lower connecting rod far away from the computer groove, one end of the lower connecting rod close to the computer groove is rotatably connected with a rotating wheel shaft, and the rotating wheel shaft is rotatably connected with a rotating wheel.

Preferably, bottom damper is including setting up in the last supporting block of shock attenuation groove roof, last supporting block in be provided with the shock attenuation shaft groove that open side down, the fixed shock attenuation axle that is provided with of shock attenuation block roof, shock attenuation shaft groove and shock attenuation axle sliding connection, go up the first spring of fixedly connected with between supporting block diapire and the shock attenuation block roof.

Preferably, the left and right shock absorption mechanisms comprise a lower rack which is positioned above the first gear and is in meshed connection with the first gear, the top wall of the first gear cavity is provided with a lower rack groove with an opening facing the direction of the computer groove, the lower rack groove is connected with the lower rack in a sliding way, the end wall of the lower rack close to the computer slot is fixedly connected with an inner slide block, the end wall of the lower rack slot close to the computer slot is provided with an inner slide block cavity, the inner slide block cavity is connected with the inner slide block in a sliding way, an inner air bag is arranged in the inner slide block cavity, the inner wall of the computer groove is provided with an outer sliding block groove with an opening facing the direction of the computer groove, an outer airbag is arranged in the outer sliding block groove, the outer air bag and the inner air bag are connected through a vent pipe fixedly connected to the box body, the outer sliding block groove is in sliding connection with an outer sliding block positioned in the outer sliding block groove, and a left sponge block and a right sponge block are fixedly connected to the end wall, close to the computer groove, of the outer sliding block.

Preferably, the top damping mechanism comprises a third gear connected with the top end of the motor shaft in a matching manner, the third gear is located in a second gear cavity, the third gear is meshed with a fourth gear located in the direction close to the computer groove and located in the second gear cavity, the fourth gear is connected with a third gear shaft in a matching manner, the third gear shaft is rotatably connected with the box body, the top end of the third gear shaft is connected with a fifth gear in a matching manner, the fifth gear is located in the third gear cavity, the fifth gear is meshed with an upper rack located behind the fifth gear, an upper rack groove with an opening facing the computer groove direction is arranged on the rear end wall of the third gear cavity, the upper rack groove is slidably connected with an upper rack located in the upper rack groove, an upper sliding block is fixedly arranged on the end wall of the upper rack close to the computer groove, and an upper damping sliding block groove communicated with the upper sliding block is arranged in the upper sliding block, go up shock attenuation slider inslot sliding connection has last shock attenuation slider, go up the fixed sponge piece that is provided with of shock attenuation slider diapire, go up through second spring coupling between shock attenuation slider and the last slider, it sets up in there being the mechanism that surges to go up the rack top.

Preferably, the mechanism surges is including setting up in last rack groove top and the ejector pad groove of opening towards computer groove direction, ejector pad groove and the ejector pad sliding connection who is located it, ejector pad bottom and last rack fixed connection, fixedly connected with connecting block on the ejector pad is close to the end wall in computer groove, fixedly connected with extrusion piece on the end wall that the connecting block is close to the computer groove, be provided with interior hydraulic pressure chamber on the end wall that the ejector pad groove is close to the computer groove, interior hydraulic pressure chamber and the extrusion piece sliding connection who is located it, computer groove roof is provided with the outer hydraulic pressure groove that the opening is decurrent, outer hydraulic pressure groove passes through hydraulic pipe with interior hydraulic pressure chamber and is connected, outer hydraulic pressure groove and the lower ejector pad sliding connection who is located it, outer hydraulic pressure groove roof fixedly connected with third spring, third spring bottom and lower ejector pad fixed connection.

The beneficial effects are that: the device has simple structure and convenient operation, when the device works, a computer to be transported is placed into a computer groove, a left box body and a right box body are closed, a motor is started, a motor shaft rotates, an inner sliding block moves towards the direction close to the computer groove through a series of transmissions, gas enters an outer air bag from the inner air bag through a vent pipe, the outer sliding block moves towards the direction close to the computer groove, a left sponge block and a right sponge block move towards the direction close to the computer groove, the left side and the right side of the computer are protected by the left sponge block and the right sponge block in the transportation process, the motor shaft rotates, an upper damping sliding block which slides to the upper part of the computer downwards moves through a series of transmissions, the upper sponge block moves downwards, the left side and the right side of the computer are protected by the upper sponge block in the transportation process, a first gear shaft rotates, a rotating wheel extends out of a rotating wheel groove through a series of transmissions, the bottom shock absorption mechanism can reduce the influence of road bumping on the computer.

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.

FIG. 1 is a schematic structural view of a computer shock-absorbing transporter according to the present invention;

FIG. 2 is a schematic view of A-A in FIG. 1 according to an embodiment of the present invention;

FIG. 3 is a schematic view of B-B in FIG. 1 according to an embodiment of the present invention;

FIG. 4 is a schematic view of C-C in FIG. 1 according to an embodiment of the present invention;

Detailed Description

All of the features disclosed in this specification, or all of the steps in any method or process so disclosed, may be combined in any combination, except combinations of features and/or steps that are mutually exclusive.

The invention will now be described in detail with reference to fig. 1-4, for convenience of description, the following orientations will now be defined: 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 computer damping transportation device comprises two box bodies 1 which are arranged symmetrically left and right, wherein the two box bodies 1 are connected with each other in a rotating mode, opposite end walls of the two box bodies 1 are provided with computer grooves 33 with outward openings, the bottom wall of each box body 1 is provided with a damping groove 64 with a downward opening, a damping block 62 is connected in the damping groove 64 in a sliding mode, rotating wheel mechanisms are symmetrically arranged in the damping block 62 front and back, bottom damping mechanisms are symmetrically arranged between the top wall of the damping groove 64 and the top wall of the damping block 62 front and back, belt cavities 2 with openings facing the direction of the computer grooves 33 are symmetrically arranged on the end wall, far away from the computer grooves 33, of the damping groove 64 front and back, a bevel gear cavity 65 located in the middle position of the front and back belt cavities 2 is arranged in the box body 1, the gear cavity 65 is communicated with the front and back belt cavities 2 through two first gear cavities 69 which are symmetrically arranged front and, a first pulley shaft 5 is rotatably connected to the end wall of the belt cavity 2 close to the bevel gear cavity 65, the first pulley shaft 5 is connected with a first pulley 3 in a matched manner, the first pulley shaft 5 is connected with a second pulley 4 which is located on the first pulley 3 in the direction far away from the bevel gear cavity 65 in a matched manner, a first gear 10 is arranged in the first gear cavity 69, the first gear 10 is in power connection with a left-right damping mechanism, the first gear 10 is connected with a first gear shaft 12 in a matched manner, the first gear shaft 12 is connected with the box body 1 in a rotated manner, one end of the first gear shaft 12 far away from the bevel gear cavity 65 is connected with a third pulley 11 in a matched manner, the third pulley 11 is connected with the first pulley 3 through a first belt 6, one end of the first gear shaft 12 close to the bevel gear cavity 65 is connected with an upper bevel gear 68 located in the bevel gear cavity 65 in a matched manner, and the upper bevel gear 68 is connected with a lower bevel gear 66 located, the lower bevel gear 66 is connected with the motor shaft 14 in a matched mode, a motor 67 is arranged at the bottom end of the motor shaft 14, and a top damping mechanism is arranged at the top end of the motor shaft 14.

Advantageously, the rotating wheel mechanism comprises a rotating wheel groove 52 which is arranged in a shock absorption block 62 and is communicated up and down, a second pulley shaft 51 which is rotatably connected with the shock absorption block 62 is arranged above the rotating wheel groove 52, the second pulley shaft 51 is in fit connection with a fourth pulley 50, the fourth pulley 50 is connected with the second pulley 4 through a second belt 63, the second pulley shaft 51 is in fit connection with a second gear 49 which is positioned on the fourth pulley 50 in the direction close to a bevel gear cavity 65, the second gear 49 is in mesh connection with a third gear 72 which is positioned below the second gear, the third gear 72 is in fit connection with a second gear shaft 71, the second gear shaft 71 is rotatably connected with the shock absorption block 62, a first connecting hinge 48 is fixedly connected to one end of the second gear shaft 71 far from the bevel gear cavity 65, the first connecting hinge 48 is hinged to an upper connecting rod 47, one end of the upper connecting rod 47 far from the computer groove 33 is hinged to the second connecting hinge 45, the second connecting hinge 45 is hinged to the connecting rod 46, the bottom end of the connecting rod 46 is hinged to a third connecting hinge 55, the third connecting hinge 55 is hinged to a lower connecting rod 56, a lower supporting block 59 is fixedly arranged on the end wall of the rotating wheel groove 52 far away from the computer groove 33, a rotating groove 58 with an opening facing the computer groove 33 is arranged in the lower supporting block 59, a rotating shaft 58 is rotatably arranged between the front end wall and the rear end wall of the rotating groove 58, the rotating shaft 58 is hinged to one end of the lower connecting rod 56 far away from the computer groove 33, one end of the lower connecting rod 56 near the computer groove 33 is rotatably connected with a rotating wheel shaft 53, and the rotating wheel shaft 53 is rotatably connected with a rotating wheel 54.

Beneficially, the bottom damper includes an upper support block 8 disposed on the top wall of the damper groove 64, the upper support block 8 is provided with a damper shaft groove 9 with a downward opening therein, the damper shaft 61 is fixedly disposed on the top wall of the damper block 62, the damper shaft groove 9 is slidably connected with the damper shaft 61, and a first spring 7 is fixedly connected between the bottom wall of the upper support block 8 and the top wall of the damper block 62.

Advantageously, the left and right shock absorbing mechanism comprises a lower rack 13 engaged with and disposed above the first gear 10, the top wall of the first gear cavity 69 is provided with a lower rack slot 73 with an opening facing the computer slot 33, the lower rack slot 73 is slidably connected with the lower rack 13, the end wall of the lower rack 13 close to the computer slot 33 is fixedly connected with an inner slide block 15, the end wall of the lower rack slot 73 close to the computer slot 33 is provided with an inner slide block cavity 40, the inner slide block cavity 40 is slidably connected with the inner slide block 15 disposed therein, the inner slide block cavity 40 is provided with an inner air bag 16, the inner wall of the computer slot 33 is provided with an outer slot 44 with an opening facing the computer slot 33, the outer air bag 44 is disposed in the outer slot 44, the outer air bag 43 is connected with the inner air bag 16 through a vent pipe 39 fixedly connected with the box 1, the outer slide block slot 44 is slidably connected with an outer slide block 42 disposed therein, the end wall of the outer sliding block 42 close to the computer slot 33 is fixedly connected with a left sponge block 41 and a right sponge block 41.

Advantageously, the top damping mechanism comprises a third gear 17 engaged with the top end of the motor shaft 14, the third gear 17 is located in a second gear cavity 18, the third gear 17 is engaged with a fourth gear 20 located in the second gear cavity 18 and located in the direction close to the computer slot 33, the fourth gear 20 is engaged with a third gear shaft 22, the third gear shaft 22 is rotatably connected with the case 1, a fifth gear 23 is engaged with the top end of the third gear shaft 22, the fifth gear 23 is located in a third gear cavity 70, the fifth gear 23 is engaged with an upper rack 21 located behind the fifth gear, the rear end wall of the third gear cavity 70 is provided with an upper rack slot 19 with an opening facing the computer slot 33, the upper rack slot 19 is slidably connected with the upper rack 21 located therein, an upper slider 28 is fixedly arranged on the end wall of the upper rack 21 close to the computer slot 33, an upper shock absorption slide block groove 35 which is communicated up and down is formed in the upper slide block 28, an upper shock absorption slide block 37 is connected in the upper shock absorption slide block groove 35 in a sliding mode, an upper sponge block 38 is fixedly arranged on the bottom wall of the upper shock absorption slide block 37, the upper shock absorption slide block 37 is connected with the upper slide block 28 through a second spring 36, and a hydraulic mechanism is arranged above the upper rack 21.

Beneficially, the hydraulic mechanism comprises a push block groove 24 which is arranged above the upper rack groove 19 and opens towards the computer groove 33, the push block groove 24 is slidably connected with a push block 25 which is arranged in the push block groove, the bottom end of the push block 25 is fixedly connected with the upper rack 21, a connecting block 26 is fixedly connected with the end wall of the push block 25 which is close to the computer groove 33, a squeezing block 27 is fixedly connected with the end wall of the connecting block 26 which is close to the computer groove 33, an inner hydraulic cavity 29 is arranged on the end wall of the push block groove 24 which is close to the computer groove 33, the inner hydraulic cavity 29 is slidably connected with the squeezing block 27 which is arranged in the inner hydraulic cavity, an outer hydraulic groove 31 which opens downwards is arranged on the top wall of the computer groove 33, the outer hydraulic groove 31 is connected with the inner hydraulic cavity 29 through a hydraulic pipe 30, the outer hydraulic groove 31 is slidably connected with a lower squeezing block 34 which is arranged in the outer hydraulic groove 31, a third spring 32 is fixedly connected on the top wall, the bottom end of the third spring 32 is fixedly connected with the lower pressing block 34.

In the initial state, the first spring 7, the second spring 36 and the third spring 32 are all in the normal stretching state, the inner air bag 16 is filled with gas, the outer air bag 43 is not filled with gas, and the rotating wheel mechanism is in the rotating wheel folding state;

sequence of mechanical actions of the whole device:

1. putting a computer to be transported into the computer groove 33, closing the left and right box bodies 1, starting the motor 67, rotating the motor shaft 14, rotating the lower bevel gear 66, rotating the upper bevel gear 68, rotating the first gear shaft 12, rotating the first gear 10, moving the lower rack 13 in a direction close to the computer groove 33, moving the inner slide block 15 in a direction close to the computer groove 33, allowing gas to enter the outer slide block 43 from the inner slide block 16 through the vent pipe 39, moving the outer slide block 42 in a direction close to the computer groove 33, moving the left and right sponge blocks 41 in a direction close to the computer groove 33, and protecting the left and right sides of the computer by the left and right sponge blocks 41 in the transportation process;

2. the motor shaft 14 is rotated, thereby rotating the third gear 17, thereby rotating the fourth gear 20, thereby rotating the third gear shaft 22, and thus the fifth gear 23, thereby moving the upper rack 21 in a direction to approach the computer slot 33, thereby moving the upper slide 28 in a direction to approach the computer slot 33, thereby moving the upper shock-absorbing slide 37 in a direction to approach the computer slot 33, moving the upper slide 28 in a direction to approach the computer slot 33, thereby moving the push block 25 in a direction to approach the computer slot 33, thereby moving the connecting block 26 in a direction to approach the computer slot 33, thereby moving the pressing block 27 in a direction to approach the computer slot 33, so that the lower pressing block 34, and thus the upper shock-absorbing slider 37 sliding over the computer is moved downward by hydraulic pressure, so that the upper sponge block 38 moves downward, and the left and right sides of the computer are protected by the upper sponge block 38 during transportation;

3. the first gear shaft 12 rotates to rotate the third pulley 11, thereby rotating the first pulley 3, thereby rotating the first pulley shaft 5, thereby rotating the second pulley 4, thereby rotating the fourth pulley 50, thereby rotating the second pulley shaft 51, thereby rotating the second gear 49, thereby rotating the third gear 72, thereby rotating the second gear shaft 71, thereby rotating the first connecting hinge 48, thereby rotating the lower link lever 56, thereby extending the pulley 54 out of the pulley groove 52;

4. when the device needs to be reset, the motor shaft 14 is reversed to reverse the lower bevel gear 66 and the upper bevel gear 68 and the first gear shaft 12 and the first gear 10 and the lower rack 13 and the inner slide 15 are moved away from the computer slot 33 and the air is introduced from the inner air bag 16 into the outer air bag 43 through the air duct 39 and the outer slide 42 is moved away from the computer slot 33 and the left and right sponge blocks 41 and the computer slot 33 are moved, the motor shaft 14 is reversed to reverse the third gear 17 and the fourth gear 20 and the third gear shaft 22 and the fifth gear 23 and the upper rack 21 and the push block 25 are moved away from the computer slot 33, thereby moving the connecting block 26 in a direction away from the computer slot 33 and thereby moving the pressing block 27 in a direction away from the computer slot 33, thereby moving the lower pressing block 34 by hydraulic pressure and thereby moving the upper cushion slider 37 sliding above the computer upward and thereby moving the upper sponge block 38 upward, and moving the upper slider 28 in a direction away from the computer slot 33 and thereby moving the upper cushion slider 37 in a direction away from the computer slot 33, reversing the first gear shaft 12 and thereby reversing the third pulley 11 and thereby reversing the first pulley 3 and thereby reversing the first pulley shaft 5 and thereby reversing the second pulley 4 and thereby reversing the fourth pulley 50 and thereby reversing the second pulley shaft 51 and thereby reversing the second gear 49 and thereby reversing the third gear 72 and thereby reversing the second pulley shaft 71, thereby reversing the first connecting hinge 48 and the lower connecting rod 56, thereby retracting the rotating wheel 54 out of the rotating wheel groove 52, turning off the motor 67, opening the left and right case bodies 1 to take out the computer, and completing the reset of the device.

The above description is only an embodiment of the invention, but the scope of the invention is not limited thereto, and any changes or substitutions that are not thought of through the inventive work should be included in the scope of the invention. Therefore, the protection scope of the invention should be subject to the protection scope defined by the claims.

Claims

1. The utility model provides a computer shock attenuation conveyer, includes two boxes that bilateral symmetry set up, its characterized in that: the left box body and the right box body are connected in a rotating way, a computer groove with an outward opening is arranged on the opposite end walls of the left box body and the right box body, a shock absorption groove with a downward opening is arranged on the bottom wall of the box body, shock absorption blocks are connected in the shock absorption groove in a sliding way, rotating wheel mechanisms are symmetrically arranged in the shock absorption blocks in a front-back way, bottom shock absorption mechanisms are symmetrically arranged in the shock absorption groove between the top wall of the shock absorption groove and the top wall of the shock absorption block in a front-back way, belt cavities with openings facing the direction of the computer groove are symmetrically arranged in the front-back way on the end wall of the shock absorption groove far away from the computer groove in a front-back way, bevel gear cavities positioned in the middle positions of the front belt cavity and the rear belt cavity are arranged in the box body, the bevel gear cavities are communicated with the front-, the first belt wheel shaft is connected with a second belt wheel which is located on the first belt wheel in a matched mode in the direction away from the bevel gear cavity, a first gear is arranged in the first gear cavity and is in power connection with a left damping mechanism and a right damping mechanism, the first gear is connected with a first gear shaft in a matched mode, the first gear shaft is connected with the box body in a rotating mode, one end, away from the bevel gear cavity, of the first gear shaft is connected with a third belt wheel in a matched mode, the third belt wheel is connected with the first belt wheel through a first belt, one end, close to the bevel gear cavity, of the first gear shaft is connected with an upper bevel gear located in the bevel gear cavity in a matched mode, the upper bevel gear is connected with a lower bevel gear located below the upper bevel gear in a meshed mode, the lower bevel gear is connected with a motor shaft in a matched.

2. The computer shock absorbing transporter according to claim 1, wherein: the rotating wheel mechanism comprises a rotating wheel groove which is arranged in the damping block and is communicated up and down, a second belt wheel shaft which is rotatably connected with the damping block is arranged above the rotating wheel groove, the second belt wheel shaft is connected with a fourth belt wheel in a matched manner, the fourth belt wheel is connected with the second belt wheel through a second belt, the second belt wheel shaft is connected with a second gear which is positioned on the fourth belt wheel and close to the bevel gear cavity in a matched manner, the second gear is connected with a third gear positioned below the second gear in a meshed manner, the third gear is connected with a second gear shaft in a matched manner, the second gear shaft is rotatably connected with the damping block, a first connecting hinge is fixedly connected with one end of the second gear shaft, which is far away from the bevel gear cavity, the first connecting hinge is hinged with an upper connecting frame rod, one end of the upper connecting frame rod, which is far away from the computer groove, is hinged with a second connecting hinge, the second connecting hinge is hinged with a connecting rod, the third connecting hinge is hinged to the lower connecting rod, a lower supporting block is fixedly arranged on the end wall, away from the computer groove, of the rotating wheel groove, a rotating groove with an opening facing the direction of the computer groove is formed in the lower supporting block, a rotating shaft is rotatably arranged between the front end wall and the rear end wall of the rotating groove, the rotating shaft is hinged to one end, away from the computer groove, of the lower connecting rod, one end, close to the computer groove, of the lower connecting rod is rotatably connected with a rotating wheel shaft, and the rotating wheel shaft is rotatably connected with a rotating wheel.

3. The computer shock absorbing transporter according to claim 1, wherein: bottom damper is including setting up in the last supporting block of shock attenuation groove roof, last supporting block in be provided with the shock attenuation shaft groove that the opening is decurrent, the fixed shock attenuation axle that is provided with of shock attenuation block roof, shock attenuation shaft groove and shock attenuation axle sliding connection, go up the first spring of fixedly connected with between supporting block diapire and the shock attenuation block roof.

4. The computer shock absorbing transporter according to claim 1, wherein: the left and right shock absorption mechanisms comprise lower racks which are positioned above the first gear and are meshed with the first gear, the top wall of the first gear cavity is provided with a lower rack groove with an opening facing the direction of the computer groove, the lower rack groove is connected with the lower rack in a sliding way, the end wall of the lower rack close to the computer groove is fixedly connected with an inner sliding block, an inner slide block cavity is arranged on the end wall of the lower rack slot close to the computer slot and is in sliding connection with an inner slide block positioned in the inner slide block cavity, an inner air bag is arranged in the inner sliding block cavity, an outer sliding block groove with an opening facing the direction of the computer groove is arranged on the inner wall of the computer groove, the outer air sac is arranged in the outer sliding block groove, the outer air sac is connected with the inner air sac through an air pipe fixedly connected on the box body, the outer sliding block groove is connected with an outer sliding block in the outer sliding block groove in a sliding mode, and a left sponge block and a right sponge block are fixedly connected to the end wall, close to the computer groove, of the outer sliding block.

5. The computer shock absorbing transporter according to claim 1, wherein: the top damping mechanism comprises a third gear which is connected with the top end of a motor shaft in a matching way, the third gear is positioned in a second gear cavity, the third gear is meshed with a fourth gear which is positioned on the third gear and close to the direction of a computer groove and positioned in the second gear cavity, the fourth gear is matched and connected with a third gear shaft, the third gear shaft is rotatably connected with the box body, the top end of the third gear shaft is connected with a fifth gear in a matching way, the fifth gear is positioned in the third gear cavity and meshed and connected with an upper rack positioned behind the fifth gear, the rear end wall of the third gear cavity is provided with an upper rack groove with an opening facing the direction of the computer groove, the upper rack groove is slidably connected with an upper rack positioned in the upper rack groove, an upper sliding block is fixedly arranged on the end wall of the upper rack close to the computer groove, and an upper damping sliding block groove which is communicated up and down is arranged in the upper sliding block, go up shock attenuation slider inslot sliding connection has last shock attenuation slider, go up the fixed sponge piece that is provided with of shock attenuation slider diapire, go up through second spring coupling between shock attenuation slider and the last slider, it sets up in there being the mechanism that surges to go up the rack top.

6. The computer shock absorbing transporter according to claim 5, wherein: the mechanism surges is including setting up in last rack groove top and the ejector pad groove of opening towards computer groove direction, ejector pad groove and the ejector pad sliding connection who is located it, ejector pad bottom and last rack fixed connection, the ejector pad is close to fixedly connected with connecting block on the end wall in computer groove, fixedly connected with extrusion piece on the end wall that the connecting block is close to the computer groove, be provided with interior hydraulic pressure chamber on the end wall that the ejector pad groove is close to the computer groove, interior hydraulic pressure chamber and the extrusion piece sliding connection who is located it, computer groove roof is provided with the outer hydraulic pressure groove that the opening is decurrent, outer hydraulic pressure groove passes through hydraulic pipe with interior hydraulic pressure chamber and is connected, outer hydraulic pressure groove and the lower ejector pad sliding connection who is located it, outer hydraulic pressure groove roof fixedly connected with third spring, third spring bottom and lower ejector pad fixed connection.