CN115571468A - Computer hardware's transportation equipment - Google Patents

Abstract

The invention discloses a computer hardware transportation device, which belongs to the technical field of transportation devices and comprises a shell component, a movable component, a main carrier component and a secondary carrier component, wherein the shell component comprises a main shell, a fixed rod and a movable rod, the movable component comprises a movable part, a fixed arm and a movable arm, a plurality of main carrier components are assembled between the fixed arm and the movable arm in an array manner, and a plurality of secondary carrier components are assembled between the fixed rod and the movable rod in an array manner.

Description

Computer hardware's transportation equipment

Technical Field

The invention belongs to the technical field of transportation equipment, and particularly relates to transportation equipment of computer hardware.

Background

The computer hardware is a general term composed of electronic, mechanical and photoelectric elements, etc. these devices form an organic whole to provide a material basis for the operation of computer software according to the requirements of system structure, and from the appearance, the computer hardware is generally composed of a main case and external devices, including a CPU, a memory, a main board, a hard disk drive, an optical disk drive, an expansion card, a connection line, a power supply, etc.

In the transportation process of computer hardware, because the electronic unit structure is small and dense, once collision and vibration occur during storage and transportation, the hardware is easily damaged, and in the actual transportation process, the existing solution means is to add shock-proof padding and shock-absorbing structures, but the material structures not only increase the weight of transportation equipment, but also are inconvenient for storing and taking the hardware.

Disclosure of Invention

In view of the defects in the prior art, an embodiment of the present invention is directed to a transportation device for computer hardware, so as to solve the problems in the background art.

In order to achieve the purpose, the invention provides the following technical scheme:

the transportation equipment of the computer hardware comprises a shell component, wherein the shell component comprises a main shell, a storage cavity and a fixed rod, the storage cavity is distributed on one side of the main shell, the fixed rod is fixedly assembled in the storage cavity, a movable rod is movably distributed in the storage cavity, and a flow channel assembly is further distributed in the storage cavity;

the movable component comprises a movable piece, a channel and a fixed arm, the movable piece is assembled in the storage cavity in a sliding mode, the channel is distributed on the movable piece and is connected with the movable rod in a sliding mode, the fixed arm is fixedly assembled on the movable piece, a movable arm is movably distributed on one side of the fixed arm, and one end of the movable arm is assembled in the runner assembly in a sliding mode;

the main carrier assembly comprises main rollers and middle rollers, a middle roller is arranged between the two groups of main rollers, main material belts are assembled on the main rollers and the middle rollers, a side frame is assembled at one end of each main roller, middle frames are assembled at two ends of each middle roller, the middle frames are assembled on the side frames in a sliding mode through guide rods, main rotating arms are further assembled on one sides of the main rollers, main shaft cylinders are assembled at the tail ends of the main rotating arms, a plurality of main carrier assemblies are assembled between a fixed arm and a movable arm in an array mode, and the main carrier assemblies are respectively connected with the fixed arm and the movable arm in a rotating mode;

the auxiliary carrier assembly comprises auxiliary rollers, auxiliary middle rollers and auxiliary rotating arms, wherein the auxiliary middle rollers are arranged between the two groups of auxiliary rollers, auxiliary material belts are assembled on the auxiliary rollers and the auxiliary middle rollers, an auxiliary side frame is assembled at one end of each auxiliary roller, auxiliary middle frames are assembled at two ends of each auxiliary middle roller, the auxiliary middle frames are assembled on the auxiliary side frames in a sliding manner through auxiliary guide rods, the main rollers at one side are also assembled with the auxiliary rotating arms, an auxiliary shaft cylinder is assembled at the tail end of one side of each auxiliary rotating arm, a transmission arm is rotationally assembled at the other side of each auxiliary rotating arm, a plurality of auxiliary carrier assemblies are assembled between the fixed rods and the movable rods in an array manner, and the auxiliary carrier assemblies are respectively rotationally connected with the fixed rods and the movable rods; and

and the transmission mechanism is arranged in the storage cavity, movably abutted against the plurality of main carrier assemblies and used for driving the main carrier assemblies and the auxiliary carrier assemblies to tilt.

As a further aspect of the present invention, the inclination angle of the channel is matched with the flow channel assembly.

As a further scheme of the invention, a plurality of main carrier assemblies and auxiliary carrier assemblies are arranged in the storage cavity in a staggered mode, and the distance between the main carrier assemblies and the auxiliary carrier assemblies is matched with the thickness of computer hardware to be transported.

As a further scheme of the invention, the main carrier assembly further comprises an elastic member, a guide groove, a sliding block and a main connecting arm, wherein the elastic member is sleeved on the guide rod and is arranged between the middle frame and the side frame for driving the elastic reset between the main roller and the middle roller, the guide groove is fixedly arranged on the middle roller, the sliding block is assembled on the guide groove in a sliding manner, two ends of the sliding block are rotatably connected with the main connecting arm, and the tail end of the main connecting arm is rotatably connected with the main rotating arm for driving the main rotating arm to rotate.

As a further scheme of the invention, the transmission mechanism comprises a transmission frame, a butting arm and L-shaped pieces, the transmission frame is elastically assembled in the storage cavity in a sliding manner, a plurality of butting arms are distributed at one end of the transmission frame, the butting arms face one side of the main carrier assembly, a plurality of L-shaped pieces are distributed at the other end of the transmission frame in an array manner, the L-shaped pieces are rotatably assembled in the main shell, one end of each L-shaped piece is movably butted with the transmission frame, and the other end of each L-shaped piece is assembled and connected with the auxiliary connecting arm, so that the transmission frame drives the auxiliary connecting arms to rotate.

As a further scheme of the invention, the flow channel assembly comprises a linear flow channel and an inclined flow channel, the linear flow channel is arranged at the inner wall end of the storage cavity, one side of the linear flow channel is connected with the inclined flow channel, and the inclined flow channel is connected with the movable arm in a sliding mode and used for limiting the sliding direction of the movable arm.

As a further scheme of the invention, a spur rack is further arranged in the main shell, a sliding rail piece is further arranged in the movable piece, and the sliding rail piece is assembled on the spur rack in a sliding mode through a locking piece and used for locking the main shell and the movable piece.

In summary, compared with the prior art, the embodiment of the invention has the following beneficial effects:

according to the invention, through the plurality of main carrier assemblies and the plurality of auxiliary carrier assemblies which are staggered and stacked, the main material belts and the auxiliary material belts in the main carrier assemblies can be used for positioning and clamping the hardware in the process of storing and transporting the computer hardware, so that the vibration in the transportation process can be reduced, and a non-rigid contact clamping mode is adopted, so that the computer hardware has better impact resistance.

Drawings

FIG. 1 is a side sectional view of a transport apparatus for computer hardware provided in an embodiment of the invention.

Fig. 2 is a schematic structural diagram of a transportation device of computer hardware according to an embodiment of the present invention.

Fig. 3 is an enlarged view of the graphic symbol a in fig. 2.

Fig. 4 is a side sectional view of a main carrier assembly in a transport apparatus of computer hardware provided in an embodiment of the invention.

Fig. 5 is a side sectional view of a sub-carrier assembly in a transport apparatus of computer hardware provided in an embodiment of the invention.

Fig. 6 is a schematic diagram illustrating an operation principle of a transportation device of computer hardware according to an embodiment of the present invention.

Fig. 7 is a top view of a main carrier assembly in a transport apparatus for computer hardware provided in an embodiment of the invention.

Fig. 8 is a perspective view of a main carrier assembly in a transportation device of computer hardware according to an embodiment of the present invention.

Reference numerals: 1-shell component, 101-main shell, 102-storage cavity, 103-fixed rod, 104-movable rod, 105-spur rack, 2-movable component, 201-movable component, 202-movable wheel, 203-channel, 204-fixed arm, 205-movable arm, 206-external plate, 207-charging port, 208-slide rail component, 209-locking component, 3-main carrier component, 301-main roller, 302-middle roller, 303-middle rack, 304-side rack, 305-guide rod, 306-elastic component, 307-main rotating arm, 308-main shaft barrel, 309-guide groove, 310-slide block, 311-main connecting arm, 312-main material belt, 4-auxiliary carrier component, 401-auxiliary roller, 402-auxiliary roller, 403-auxiliary middle rack, 404-auxiliary side rack, 405-auxiliary guide rod, 406-auxiliary elastic component, 407-auxiliary rotating arm, 408-auxiliary shaft barrel, 409-auxiliary guide groove, 410-auxiliary slide block, 411-auxiliary connecting arm, 412-auxiliary belt, 413-auxiliary belt mechanism, 5-auxiliary guide rod, 501-auxiliary slide block, 3-inclined flow channel, and straight-inclined flow channel, 601-inclined flow channel.

Detailed Description

To more clearly illustrate the structural features and effects of the present invention, the present invention will be described in detail below with reference to the accompanying drawings and specific embodiments.

Referring to fig. 1 to 8, a transportation apparatus of computer hardware in an embodiment of the present invention includes a housing member 1, where the housing member 1 includes a main housing 101, a storage cavity 102, and a fixing rod 103, the storage cavity 102 is disposed at one side of the main housing 101, the fixing rod 103 is fixedly disposed in the storage cavity 102, the movable rod 104 is movably disposed in the storage cavity 102, and the flow channel assembly 6 is further disposed in the storage cavity 102; the movable component 2 comprises a movable piece 201, a channel 203 and a fixed arm 204, wherein the movable piece 201 is slidably assembled in the storage cavity 102, the channel 203 is arranged on the movable piece 201, a movable wheel 202 is assembled at the bottom of the movable piece 201, the channel 203 is slidably connected with the movable rod 104, the fixed arm 204 is fixedly assembled on the movable piece 201, a movable arm 205 is movably arranged on one side of the fixed arm 204, one end of the movable arm 205 is slidably assembled in the runner assembly 6, an external plate 206 is also fixedly assembled at one end of the movable piece 201, and a plurality of charging ports 207 are arrayed on the external plate 206; the main carrier component 3 comprises main rollers 301 and middle rollers 302, a middle roller 302 is arranged between two groups of the main rollers 301, main material belts 312 are assembled on the main rollers 301 and the middle rollers 302, a side frame 304 is assembled at one end of each main roller 301, middle frames 303 are assembled at two ends of each middle roller 302, the middle frames 303 are slidably assembled on the side frames 304 through guide rods 305, main rotating arms 307 are further assembled on one sides of the main rollers 301, main shaft cylinders 308 are assembled at the tail ends of the main rotating arms 307, elastic members 306 are sleeved on the guide rods 305 and arranged between the middle frames 303 and the side frames 304 and used for driving elastic reset between the main rollers 301 and the middle rollers 302, guide grooves 309 are fixedly arranged on the middle rollers 302, sliders 310 are slidably assembled on the guide grooves 309 and rotatably connected with main connecting arms 311 at two ends of the sliders 310, the tail ends of the main connecting arms 311 are rotatably connected with the main rotating arms 307 and used for driving the rotation of the main rotating arms 307, a plurality of the main carrier component 3 are assembled between the fixed arms 204 and the movable arms 205, and the main carrier components 205 are respectively connected with the fixed arms 307 and the movable arms 205; the auxiliary carrier component 4 comprises an auxiliary roller 401, an auxiliary middle roller 402 and an auxiliary rotating arm 407, the auxiliary middle roller 402 is arranged between two groups of auxiliary rollers 401, auxiliary material belts 412 are assembled on the auxiliary roller 401 and the auxiliary middle roller 402, an auxiliary side frame 404 is assembled at one end of the auxiliary roller 401, auxiliary middle frames 403 are assembled at two ends of the auxiliary middle roller 402, the auxiliary middle frames 403 are slidably assembled on the auxiliary side frames 404 through auxiliary guide rods 405, an auxiliary elastic piece 406 is sleeved on the auxiliary guide rods 405, an auxiliary rotating arm 407 is also assembled on the main roller 301 at one side, an auxiliary shaft cylinder 408 is assembled at the tail end of one side of the auxiliary rotating arm 407, a transmission arm 413 is rotatably assembled at the other side of the auxiliary middle frame 403, an auxiliary guide groove 409 is fixedly arranged on the auxiliary middle frame 403, an auxiliary slider 410 is slidably assembled on the auxiliary guide groove 409, one end of the auxiliary slider 410 is rotatably connected with an auxiliary connecting arm 411, the tail end of the auxiliary connecting arm 411 is rotatably connected with the auxiliary rotating arm 407, and a plurality of the auxiliary carrier components 4 are arranged between the fixed rod 103 and the movable rod 104, and the auxiliary carrier component 4 is respectively rotatably connected with the fixed rod 103 and the movable rod 104; and the transmission mechanism 5 is arranged in the storage cavity 102, movably abutted against the plurality of main carrier assemblies 3 and used for driving the main carrier assemblies 3 and the auxiliary carrier assemblies 4 to tilt.

In practical application, when the computer hardware is transported by the transportation device, firstly, the device is in a closed state, a plurality of main carrier assemblies 3 and sub-carrier assemblies 4 therein are in a staggered horizontal stacking state, and when the hardware to be transported is loaded, the hardware to be transported can be horizontally fed to the surfaces of a plurality of main carrier assemblies 3 and sub-carrier assemblies 4 through a plurality of charging openings 207 on an external plate 206 at one end of a movable member 201, at this time, a main material belt 312 in the main carrier assembly 3 is tightly assembled on a main roller 301 and a middle roller 302, so that the hardware can be horizontally placed on the main material belt 312, the sub-carrier assemblies 4 are similar, and when the main material belt 312 and the sub-material belt 412 in the main carrier assembly 3 and the sub-carrier assemblies 4 are fully filled with the hardware, the movable member 201 can be continuously pushed towards the storage cavity 102, in the process of moving the main carrier assembly 3 toward the side of the transmission mechanism 5, the main roller 301 at one end of the main carrier assembly 3 is pressed against the transmission mechanism 5, in this process, because the main roller 301 at the other end is fixedly mounted on the movable element 201 through the fixed arm 204, under the squeezing action, the middle frame 303 and the side frame 304 between the main roller 301 and the middle roller 302 can slide on the guide rod 305, so that the distance between the main roller 301 and the middle roller 302 is shortened, because the main rotating arm 307 and the main connecting arm 311 are rotatably connected, and both ends are movably connected with the main roller 301 and the middle roller 302 respectively, the included angle between the main rotating arm 307 and the main connecting arm 311 is continuously reduced, so that the main shaft barrel 308 mounted at the connection position of the main rotating arm 307 and the main connecting arm 311 is continuously rotated toward the side away from the side frame 304, and the main material belt 312 at the bottom of the main carrier assembly 3 is moved toward the side away from the main carrier assembly 3, the auxiliary carrier assembly 4 is the same, and because the main carrier assembly 3 and the auxiliary carrier assembly 4 are arranged in a stacked manner, when the main material belt 312 or the auxiliary material belt 412 at the bottom of the main carrier assembly 3 or the auxiliary carrier assembly 4 at one side moves towards the main carrier assembly 3 or the auxiliary carrier assembly 4 at the bottom of the main carrier assembly 3 or the auxiliary carrier assembly 4, the main material belt 312 or the auxiliary material belt 412 can be pressed on hardware goods carried by the main carrier assembly 3 or the auxiliary carrier assembly 4 at the bottom of the main carrier assembly 3 or the auxiliary carrier assembly 4, so that the hardware is clamped by the main material belt 312 and the auxiliary material belt 412, compared with the conventional mechanical clamping, the clamping is performed by the main material belt 312 and the auxiliary material belt 412, and the clamping has elasticity, can reduce vibration in the transportation process, adopts a non-rigid contact clamping mode, has more excellent impact resistance, compared with the conventional spring and airbag damping structure, not only has a good protection effect, but also saves space, and improves the utilization rate of the space.

When the device is used for hardware taking, the movable member 201 is taken out from the storage cavity 102 in a sliding manner, the main carrier component 3 is firstly away from the transmission mechanism 5 side, so that the main rotating arm 307 and the auxiliary rotating arm 407 inside the main carrier component 3 and the auxiliary carrier component 4 are both reset in a rotating manner, and the movable arm 205 is slidably assembled in the runner component 6, and the movable rod 104 is slidably assembled in the channel 203, so that the movable arm 205 and the movable rod 104 move vertically and downwards simultaneously in the vertical direction during the movement of the movable member 201 towards the side away from the storage cavity 102, so that a plurality of main carrier components 3 assembled between the fixed arm 204 and the movable arm 205 and a plurality of auxiliary carrier components 4 assembled between the fixed rod 103 and the movable rod 104 are inclined synchronously, and the inclination directions of the main carrier component 3 and the auxiliary carrier components 4 are opposite, so that a stacked inclined staggered structure is formed between the main carrier component 3 and the auxiliary carrier components 4, the main carrier component 3 and the auxiliary carrier components 4 can be driven to move independently in groups by the motor, so that the main carrier components 3 and the auxiliary carrier components 4 can be moved in a stacked inclined staggered structure, so that the main carrier components and auxiliary carrier components can be taken out sequentially and the device can be taken out sequentially without the use of the hardware, thereby improving the efficiency of the continuous taking and the continuous taking of the mechanical goods can be carried out of the primary components 312, and auxiliary carrier components, and the device, and the disposable goods without the disposable goods.

In one aspect of the present embodiment, the plurality of loading openings 207 of the external plate 206 can be closed by a movable door plate or a mechanical door lock, so as to prevent accidental falling during transportation, and is not limited herein.

In one aspect of the present embodiment, the plurality of main carrier assemblies 3 and the plurality of sub-carrier assemblies 4 may be driven by an external motor assembly chain, so that the plurality of main carrier assemblies 3 and the plurality of sub-carrier assemblies 4 rotate independently in groups, where a specific assembly structure of the motor is not limited.

In one case of this embodiment, when the distance between the main roller 301 and the middle roller 302 is shortened, the main arm 307 rotates continuously, so that the main belt 312 is always tensioned on the surfaces of the main roller 301, the middle roller 302 and the main roller 308, the circumference of the main belt is always kept unchanged, and the hardware goods on the top are ensured not to fall off, and the subcarrier assembly 4 is the same.

Referring to fig. 2, in a preferred embodiment of the invention, the inclined angle of the channel 203 is matched with the flow channel assembly 6.

In practical application, the channel 203 and the runner assembly 6 have the same inclination angle and opposite inclination angles, so that the main carrier assembly 3 and the sub-carrier assembly 4 are synchronously and reversely tilted under the driving of the movable rod 104 and the movable arm 205, so that they form a staggered tilting and stacking structure, thereby forming a runner for continuous discharging.

In one case of this embodiment, the channel 203 and the runner assembly 6 have an inclination angle between 5 ° and 15 °, which is not too large, and thus the hardware is likely to naturally slide against friction under the action of gravity, thereby causing the hardware to be jammed in the runner for continuous discharge.

Referring to fig. 2, in a preferred embodiment of the invention, a plurality of the main carrier assemblies 3 and the sub-carrier assemblies 4 are arranged in the storage cavity 102 in a staggered manner, and the distance between the main carrier assemblies 3 and the sub-carrier assemblies 4 is matched with the thickness of the computer hardware to be transported.

In practical application of the embodiment, when the main carrier assembly 3 and the sub-carrier assembly 4 are arranged in the storage cavity 102 in a staggered manner, and the hardware is clamped by the main material belt 312 and the sub-material belt 412, the rotation angles of the main rotating arm 307 and the sub-rotating arm 407 can ensure that the main material belt 312 and the sub-material belt 412 can be stably pressed on the surface of the hardware with a fixed thickness, so as to ensure the fixation of the hardware.

In one case of this embodiment, the number of the main carrier assemblies 3 and the sub-carrier assemblies 4 are matched, and the bottom layer is always the sub-carrier assembly 4, so that the hardware is finally output through the sub-carrier assembly 4 toward the opening side of the storage cavity 102.

Referring to fig. 3, in a preferred embodiment of the present invention, the transmission mechanism 5 includes a transmission frame 501, a plurality of abutting arms 502 and L-shaped members 503, the transmission frame 501 is elastically and slidably assembled in the storage cavity 102, and a plurality of abutting arms 502 are disposed at one end of the transmission frame 501, the abutting arms 502 are disposed toward one side of the main carrier assembly 3, a plurality of L-shaped members 503 are further disposed at the other end of the transmission frame 501 in an array manner, the L-shaped members 503 are rotatably assembled in the main housing 101, one end of each L-shaped member is movably abutted to the transmission frame 501, and the other end of each L-shaped member is assembled to a plurality of sub carrier assemblies 4.

In practical application of the present embodiment, when the main roller 301 is pressed toward one side of the transmission frame 501, in the process that the main roller 301 is abutted against the abutting arm 502, the transmission frame 501 slides toward the wall surface end of the main casing 101 against the elastic acting force, and the transmission frame 501 is movably abutted against the L-shaped part 503 on the other side, and the L-shaped part 503 drives the auxiliary rotating arm 407 to rotate through the transmission arm 413 in the rotating process, so that the auxiliary rotating arm 407 synchronously drives the auxiliary shaft cylinder 408 to rotate, so that the auxiliary shaft cylinder 408 is pressed onto the auxiliary material belt 412, and the auxiliary material belt 412 is pressed toward the hardware end on the main material belt 312 at the bottom, so that the hardware is stably clamped between the main material belt 312 and the auxiliary material belt 412.

In one aspect of this embodiment, the primary material belt 312 and the secondary material belt 412 are preferably made of a polymeric polyurethane belt, which has the characteristics of skid resistance and wear resistance, and also has the toughness of high resilience, so that the hardware is not easy to slide and damage when being clamped.

Referring to fig. 2, in a preferred embodiment of the present invention, the runner assembly 6 includes a straight runner 601 and an inclined runner 602, the straight runner 601 is disposed at an inner wall end of the storage chamber 102, and an inclined runner 602 is connected to one side of the straight runner 601, and the inclined runner 602 is slidably connected to the movable arm 205, so as to define a sliding direction of the movable arm 205.

In practical application of the embodiment, the linear flow channel 601 is arranged on one side of the inclined flow channel 602, and when the main carrier assembly 3 and the sub-carrier assembly 4 start to move horizontally, the linear flow channel 601 slides in the linear flow channel 601 first, so that the main material belt 312 and the sub-material belt 412 inside the main carrier assembly 3 and the sub-carrier assembly 4 are reset and tensioned on the main roller 301 and the middle roller 302, and the sub-roller 401 and the sub-middle roller 402, and in the process, the main carrier assembly 3 and the sub-carrier assembly 4 can be prevented from being inclined, so that hardware is prevented from being pushed off from the main material belt 312 and the sub-material belt 412.

Referring to fig. 2, in a preferred embodiment of the present invention, a spur rack 105 is further disposed in the main housing 101, a sliding rail member 208 is further disposed in the movable member 201, and the sliding rail member 208 is slidably assembled on the spur rack 105 through a locking member 209 for locking the main housing 101 and the movable member 201.

In practical application of the present embodiment, the sliding rail member 208 is slidably assembled on the spur rack 105, and the locking member 209 is further disposed at one end of the sliding rail member 208, so that when the movable member 201 is pushed into the storage chamber 102, the movable member 201 can be limited from sliding reversely by the locking member 209, so that the movable member 201 is locked in the storage chamber 102, and the movable member 201 is prevented from sliding out of the storage chamber 102 during transportation to cause dropping and loss of hardware.

In one case of the present embodiment, a linear sliding locking structure composed of the spur rack 105 and the slide rail member 208 may be employed, and a fixed locking structure may also be employed, but in view of convenience during actual use, a linear sliding locking structure is preferably employed here.

The embodiment of the invention provides computer hardware transportation equipment, and a plurality of main carrier assemblies 3 and auxiliary carrier assemblies 4 which are staggered and stacked can be used for positioning and clamping hardware in the process of storing and transporting the computer hardware, so that the vibration in the transportation process can be reduced, a non-rigid contact clamping mode is adopted, the impact resistance is better, the space occupation is saved compared with the traditional spring and air bag damping structure, and meanwhile, in the unloading process, a continuous unloading flow channel is formed by tilting of the main carrier assemblies 3 and the auxiliary carrier assemblies 4, so that the hardware is quickly and continuously taken out, the complicated steps of manual cleaning and transportation are omitted, the unloading efficiency is improved, and meanwhile, the environment-friendly value of recycling is achieved.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents and improvements made within the spirit and principle of the present invention are intended to be included within the scope of the present invention.

Claims (7)

1. A computer hardware transport apparatus, comprising:

the device comprises a shell component (1), wherein the shell component (1) comprises a main shell (101), a storage cavity (102) and a fixed rod (103), the storage cavity (102) is arranged on one side of the main shell (101), the fixed rod (103) is fixedly assembled in the storage cavity (102), a movable rod (104) is movably arranged in the storage cavity (102), and a flow channel assembly (6) is further arranged in the storage cavity (102);

the movable component (2) comprises a movable piece (201), a channel (203) and a fixed arm (204), the movable piece (201) is slidably assembled in the storage cavity (102), the channel (203) is arranged on the movable piece (201), a movable wheel (202) is assembled at the bottom of the movable piece (201), the channel (203) is connected with the movable rod (104) in a sliding manner, the fixed arm (204) is fixedly assembled on the movable piece (201), a movable arm (205) is movably arranged on one side of the fixed arm (204), one end of the movable arm (205) is slidably assembled in the runner assembly (6), an external plate (206) is further fixedly assembled at one end of the movable piece (201), and a plurality of charging ports (207) are arranged on the external plate (206) in an array manner;

the main carrier assembly (3) comprises main rollers (301) and middle rollers (302), the middle rollers (302) are arranged between the two groups of main rollers (301), main material belts (312) are assembled on the main rollers (301) and the middle rollers (302), one end of each main roller (301) is provided with a side frame (304), two ends of each middle roller (302) are provided with middle frames (303), the middle frames (303) are assembled on the side frames (304) in a sliding mode through guide rods (305), one side of each main roller (301) is also provided with a main rotating arm (307), the tail end of each main rotating arm (307) is provided with a main shaft barrel (308), a plurality of main carrier assemblies (3) are assembled between a fixed arm (204) and a movable arm (205) in an array mode, and the main carrier assemblies (3) are respectively connected with the fixed arm (204) and the movable arm (205) in a rotating mode;

the auxiliary carrier assembly (4) comprises an auxiliary roller (401), an auxiliary middle roller (402) and auxiliary rotating arms (407), an auxiliary middle roller (402) is arranged between the two groups of auxiliary rollers (401), auxiliary material belts (412) are assembled on the auxiliary roller (401) and the auxiliary roller (402), an auxiliary side frame (404) is assembled at one end of the auxiliary roller (401), auxiliary middle frames (403) are assembled at two ends of the auxiliary middle roller (402), the auxiliary middle frames (403) are assembled on the auxiliary side frame (404) in a sliding mode through auxiliary guide rods (405), an auxiliary elastic piece (406) is sleeved on the auxiliary guide rods (405), auxiliary rotating arms (403) are assembled at two ends of the auxiliary middle roller (402), an auxiliary shaft tube (408) is assembled at the tail end of one side of the auxiliary rotating arm (407), a transmission arm (413) is assembled at the other side in a rotating mode, auxiliary guide grooves (409) are fixedly arranged on the auxiliary middle frames (403), auxiliary sliders (410) are assembled on the auxiliary guide grooves (409), one end of each auxiliary slider (410) is connected with a plurality of fixing rods (411) and a plurality of fixing rods (103) which are connected with the auxiliary rotating arm assemblies (411), and a plurality of the auxiliary slider (103), and a plurality of rotating arm assemblies (411) are assembled between the auxiliary middle carrier assemblies (103), and the auxiliary roller (411) and the auxiliary carrier assemblies (104) respectively connected with the auxiliary rotating arms (411), and the fixing rods (103), and the auxiliary carrier assemblies (103), and the auxiliary roller (411), and the auxiliary roller (103), and the auxiliary carrier assemblies (104), and the auxiliary roller (411), and the auxiliary roller (104), and the auxiliary middle carrier assemblies (103) are assembled between the auxiliary roller (411), and the auxiliary roller (103), and the auxiliary roller (104) respectively ) Rotating and connecting;

and the transmission mechanism (5) is arranged in the storage cavity (102), movably abutted against the plurality of main carrier assemblies (3) and used for driving the main carrier assemblies (3) and the auxiliary carrier assemblies (4) to tilt.

2. A computer hardware transport apparatus according to claim 1, wherein the channel (203) is inclined at an angle matching the flow channel assembly (6).

3. The computer hardware transport apparatus according to claim 1, wherein a plurality of the main carrier assemblies (3) and the sub-carrier assemblies (4) are arranged in the storage chamber (102) in a staggered manner, and the distance between the main carrier assemblies (3) and the sub-carrier assemblies (4) is matched with the thickness of the computer hardware to be transported.

4. The computer hardware transportation device according to claim 1, wherein the main carrier assembly (3) further comprises an elastic member (306), a guide groove (309), a slider (310) and a main link arm (311), the elastic member (306) is sleeved on the guide rod (305), and is disposed between the middle frame (303) and the side frame (304) for driving elastic return between the main roller (301) and the middle roller (302), the guide groove (309) is fixedly disposed on the middle roller (302), the slider (310) is slidably mounted on the guide groove (309), and two ends of the slider (310) are rotatably connected with the main link arm (311), and a distal end of the main link arm (311) is rotatably connected with the main link arm (307) for driving rotation of the main link arm (307).

5. The computer hardware transportation device according to claim 1, wherein the transmission mechanism (5) comprises a transmission frame (501), an abutting arm (502) and L-shaped pieces (503), the transmission frame (501) is elastically and slidably assembled in the storage cavity (102), a plurality of abutting arms (502) are distributed at one end of the transmission frame (501), the abutting arms (502) are arranged towards one side of the main carrier component (3), a plurality of L-shaped pieces (503) are further distributed at the other end of the transmission frame (501) in an array mode, the L-shaped pieces (503) are rotatably assembled in the main housing (101), one end of each L-shaped piece is movably abutted to the transmission frame (501), and the other end of each L-shaped piece is assembled to a plurality of auxiliary carrier components (4).

6. The computer hardware transportation device of claim 1, wherein the runner assembly (6) comprises a straight runner (601) and an inclined runner (602), the straight runner (601) is disposed at an inner wall end of the storage chamber (102), and an inclined runner (602) is connected to one side of the straight runner (601), and the inclined runner (602) is slidably connected to the movable arm (205) for defining a sliding direction of the movable arm (205).

7. The computer hardware transportation device according to claim 1, wherein a spur rack (105) is further disposed in the main housing (101), and a slide rail member (208) is further disposed in the movable member (201), wherein the slide rail member (208) is slidably mounted on the spur rack (105) through a locking member (209) and is used for locking the main housing (101) and the movable member (201).

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