CN117284805A - A upper plate device and material loading conveying system for ageing test - Google Patents

Abstract

The application relates to a loading plate device and a loading and transporting system for aging test, which comprises a frame, a transfer mechanism and a loading mechanism, wherein the frame is provided with a discharging hole and a loading hole; the transfer mechanism is arranged in the frame to receive the tooling plate; the feeding mechanism comprises a driving assembly, a transverse push plate rod and a push plate, wherein the push plate is rotatably arranged on the transverse push plate rod, the opposite transverse push plate rod is in a vertical state when the push plate is not blocked, the push plate is in a folded state when being subjected to resistance, and the push plate is pushed against the tooling plate after being in the folded state, so that the tooling plate is pushed onto the material receiving device. The utility model provides a trigger and its material feeding unit of material loading conveying system send the frock board to transfer on the mechanism, elevating gear will transfer the mechanism and carry corresponding feed opening, transfer the mechanism and carry the feed opening with the frock board, before automatic carrier trolley carried the feed opening with goods shelves, unlocking device pushed down locking device and made the frock board to transport, and feed mechanism pushes up the frock board to goods shelves from transfer mechanism, accomplishes the material loading transportation of frock board.

Description

A upper plate device and material loading conveying system for ageing test

Technical Field

The application relates to the field of unloading transportation, in particular to an upper plate device for aging test and a loading transportation system.

Background

Many cargoes in the mill need to be loaded, installed and transported, and traditional loading, installation and transportation methods mainly adopt manual operation, however, the manual operation method has the problems of low efficiency, high fatigue strength, high labor cost and the like.

Disclosure of Invention

The application provides a loading board device and material loading conveying system for ageing test to solve among the background art artifical material loading installation transportation goods lead to inefficiency, fatigue strength height and the high problem of cost of labor.

In order to solve the technical problems, one technical scheme adopted by the application is as follows: the utility model provides a upper plate device and material loading conveying system for burn-in test, an upper plate device for burn-in test includes:

the rack is provided with a feeding hole and a discharging hole;

the transferring mechanism is arranged in the frame and positioned between the feeding opening and the discharging opening and is used for receiving the tooling plate and sending the tooling plate out through the feeding opening;

the feeding mechanism comprises a driving assembly, a transverse push plate rod, a push supporting plate and a rotation restraining piece, wherein the transverse push plate rod is flush with or lower than the carrying surface of the transferring mechanism, the transverse push plate rod is provided with a first end and a second end, the driving assembly is used for driving the first end, the rotation restraining piece is arranged at the second end, the push supporting plate is rotationally arranged at the second end of the transverse push plate rod and is restrained by the rotation restraining piece when rotating, the push supporting plate is in a vertical state relative to the transverse push plate rod and protrudes from the carrying surface of the transferring mechanism when not being subjected to resistance towards the second end, the push supporting plate is in a folding state relative to the transverse push plate rod when being subjected to resistance towards the second end and is flush with or recessed in the carrying surface of the transferring mechanism, and the driving assembly is used for driving the transverse push plate rod to move transversely to extend or retract the feeding port, and the push supporting plate is used for pushing the tool plate to be pushed out of the transferring mechanism in the folding state through the bottom surface of the tool.

In a specific embodiment of the present application, the transverse push plate rod extends to form a clamping plate, the clamping plate is provided with a hinge hole for rotatably setting the push plate, the rotation constraint member is arranged between the clamping plates, the top of the rotation constraint member is lower than the hinge hole, the push plate is arranged on the side edge of the rotation constraint member, which is close to the first end, and the push plate is rotated towards the top of the rotation constraint member to be close to when the transverse push plate rod is subjected to resistance towards the second end.

In a specific embodiment of the present application, the pushing plate maintains the upright state relative to the transverse pushing plate rod through a torsion spring; or the pushing plates are asymmetrically arranged at one end of the pushing plates and the other end of the pushing plates are light, and the vertical state is kept relative to the transverse pushing plate rod based on natural gravity distribution.

In a specific embodiment of the present application, the upper plate device for burn-in testing includes a lifting device, the lifting device includes a lifting frame and a gear lifting mechanism, the lifting frame is used for bearing the transfer mechanism and the feeding mechanism, and the gear lifting mechanism is used for carrying the lifting frame up and down to a required corresponding position.

In a specific embodiment of the present application, the lifting frame is a rectangular frame, the lifting frame is disposed in the frame and located between the feeding port and the discharging port, the transverse length of the lifting frame is matched with that of the transfer mechanism, a buffer is disposed in the frame corresponding to the lifting frame, and the buffer is used for stable shock absorption when the lifting frame lifts.

In a specific embodiment of the present application, the gear lifting mechanism includes a rotating rod, a rotating gear, a toothed belt and a connecting block, the rotating rod is connected and fixed with the frame through a fixed pulley, the rotating gear is arranged on the rotating rod, the rotating gear rotates along with the rotation of the rotating rod, the toothed belt is arranged on the rotating gear and ascends and descends along with the rotation of the rotating gear, and the toothed belt is connected with the lifting frame through the connecting block.

In a specific embodiment of the present application, the driving component of the feeding mechanism may adopt a sliding structure or a gear transmission structure.

In a specific embodiment of the present application, the transferring mechanism includes a conveyor belt structure and a transferring motor, the transferring motor is disposed below the lifting frame, and the transferring motor controls the conveyor belt structure to transport the tooling plate.

In a specific embodiment of the present application, the feeding mechanism is disposed in the middle of the transferring mechanism.

The feeding transportation system comprises:

upper plate device for burn-in test;

the material receiving device comprises an automatic carrying trolley, a goods shelf and a locking device, wherein the automatic carrying trolley is used for carrying the goods shelf to the front of the material loading opening of the upper plate device for aging test, the goods shelf is used for carrying the tooling plate, the locking device is elastically connected with the goods shelf, and the locking device is used for locking the tooling plate so as to prevent the tooling plate from falling;

the unlocking device is arranged on the outer part of the rack of the upper plate device for burn-in test, and the unlocking device presses down the locking device to unlock and enable the tooling plate to be moved in;

and the feeding device corresponds to the discharging hole of the upper plate device for aging test and is used for conveying the tooling plate to the transfer mechanism.

The beneficial effects of this application are: the application provides a loading attachment and material loading conveying system for ageing test is because its material feeding unit will frock the board send to transfer the mechanism on, and elevating gear will transfer the mechanism to send to corresponding feed inlet department, and unlocking device unlocking is receiving locking device on the material loading device, and loading attachment will frock the board from transfer the mechanism to support to push up to accomplish the material loading transport function to frock the board on the goods shelves, its novel structure, degree of automation is high, and has greatly improved work efficiency, has reduced the cost of labor.

Drawings

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

fig. 1 is a schematic structural diagram of a feeding transportation system provided in an embodiment of the present application;

fig. 2 is a schematic structural diagram of a board mounting device for burn-in testing according to an embodiment of the present application;

fig. 3 is a schematic diagram of a rack structure of an upper board device for burn-in testing according to an embodiment of the present application;

fig. 4 is a schematic structural view of a transfer mechanism of an upper plate device for burn-in testing according to an embodiment of the present application;

fig. 5 is a schematic structural diagram of a feeding mechanism of an upper plate device for burn-in testing according to an embodiment of the present application;

fig. 6 is a schematic enlarged partial view of a loading mechanism of an upper plate device for burn-in testing according to an embodiment of the present application;

fig. 7 is an enlarged schematic view of a lifting device of an upper plate device for burn-in testing according to an embodiment of the present application;

fig. 8 is a schematic structural diagram of a receiving device of a feeding and transporting system according to an embodiment of the present application;

fig. 9 is a schematic structural view of a locking device according to an embodiment of the present application.

Reference numerals illustrate: 10. upper plate device for burn-in test; 20. a receiving device; 21. automatic carrying trolley; 22. a goods shelf; 23. a locking device; 24. a vertical rod; 25. a cross bar; 26. a through groove; 30. unlocking means; 40. a feeding device; 50. a tooling plate; 100. a frame; 110. a feeding port; 120. a discharge port; 130. a buffer; 200. a transfer mechanism; 210. a conveyor belt structure; 220. a transfer motor; 300. a feeding mechanism; 310. a drive assembly; 312. a sliding rail; 314. a sliding plate; 316. a connecting plate; 318. rotating the belt; 320. a transverse push plate rod; 322. a clamping plate; 324. a rotation restraint; 330. a pushing plate; 400. a lifting device; 410. a lifting frame; 420. a gear lifting mechanism; 422. a rotating lever; 424. rotating the gear; 426. toothed belt; 428. and (5) connecting a block.

Detailed Description

The following description of the embodiments of the present application will be made clearly and fully with reference to the accompanying drawings, in which it is evident that the embodiments described are only some, but not all, of the embodiments of the present application. All other embodiments, which can be made by one of ordinary skill in the art without undue burden from the present disclosure, are within the scope of the present disclosure.

It should be noted that, in the embodiment of the present application, directional indications (such as up, down, left, right, front, and rear … …) are referred to, and the directional indications are merely used to explain the relative positional relationship, movement conditions, and the like between the components in a specific posture (as shown in the drawings), and if the specific posture is changed, the directional indications are correspondingly changed.

In addition, if there is a description of "first", "second", etc. in the embodiments of the present application, the description of "first", "second", etc. is for descriptive purposes only and is not to be construed as indicating or implying a relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "a first" or "a second" may explicitly or implicitly include at least one such feature. In addition, the technical solutions of the embodiments may be combined with each other, but it is necessary to base that the technical solutions can be realized by those skilled in the art, and when the technical solutions are contradictory or cannot be realized, the combination of the technical solutions should be regarded as not exist and not within the protection scope of the present application.

As shown in fig. 2 to 7, the present application provides a top plate device 10 for burn-in testing, where the top plate device 10 for burn-in testing includes a frame 100, a transfer mechanism 200, and a loading mechanism 300.

The frame 100 is provided with a feeding hole 110 and a discharging hole 120, the feeding hole 110 and the discharging hole 120 are arranged at the front end and the rear end of the frame 100 at intervals, the feeding hole 110 and the discharging hole 120 are not on the same horizontal plane, and the opening sizes are different.

The transfer mechanism 200 is disposed in the frame 100 and between the loading opening 110 and the unloading opening 120, and is used for receiving the tooling plate 50 and delivering the tooling plate 50 out through the loading opening 110, and the carrying surface of the transfer mechanism 200 is flush with or lower than the bottom surface of the tooling plate 50.

The feeding mechanism 300 comprises a driving component 310, a transverse pushing plate rod 320, a pushing plate 330 and a rotation restraining piece 324, wherein the transverse pushing plate rod 320 is flush with or lower than the carrying surface of the transferring mechanism 200, the transverse pushing plate rod 320 is provided with a first end and a second end, the driving component 310 is used for driving the first end, the rotation restraining piece 324 is arranged at the second end, the pushing plate 330 is rotatably arranged at the second end of the transverse pushing plate rod 320 and restrained by the rotation restraining piece 324 when rotating, the pushing plate 330 is in a vertical state relative to the transverse pushing plate rod 320 and protrudes out of the carrying surface of the transferring mechanism 200 when not receiving resistance towards the second end, the pushing plate 330 is in a reverse folded state relative to the transverse pushing plate rod 320 and is flush with or sunken in the carrying surface of the transferring mechanism 200 when receiving resistance towards the second end, the driving component 310 is used for driving the transverse pushing plate rod 320 to move transversely to extend or retract the feeding port 110, and the pushing plate 330 is used for passing through the bottom surface of the tooling plate 50 in the reverse folded state and pushing the end surface of the tooling plate 50 in the vertical state so as to push the tooling plate 50 out of the transferring mechanism 200.

As shown in fig. 5 and 6, the transverse pushing rod 320 is extended with a clamping plate 322, in this embodiment, an extension portion is connected with the transverse pushing rod 320, or an extension arm is integrally disposed on the transverse pushing rod 320, the clamping plate 322 is provided with a hinge hole for rotatably disposing the pushing plate 330, the rotation restraint member 324 is disposed between the clamping plates 322, the pushing plate 330 is disposed on a side edge of the rotation restraint member 324 near the first end, the rotation restraint member 324 is used for making the pushing plate 330 in a vertical state after pushing against the tooling plate 50, and the top of the rotation restraint member 324 is lower than the hinge hole, so that the pushing plate 330 is rotated towards the top of the rotation restraint member 324 when being subjected to resistance towards the first end, and is close to a folded state and flush with or recessed in a carrying surface of the transfer mechanism 200.

As shown in fig. 6, the push plate 330 is maintained in a vertically placed state with respect to the lateral push plate lever 320 by a torsion spring; or the pushing plate 330 is asymmetrically arranged with one heavy end and the other light end, and the vertical state is kept relative to the horizontal pushing plate 330 rod based on natural gravity distribution, and in the embodiment, the pushing plate 330 is asymmetrically arranged with one heavy end and the other light end, compared with the other mode, the mode has the advantages of strong durability, material saving and the like.

As shown in fig. 1, 2 and 7, the upper plate device 10 for burn-in test includes a lifting device 400, the lifting device 400 includes a lifting frame 410 and a gear lifting mechanism 420, the lifting frame 410 is used for carrying the transferring mechanism 200 and the feeding mechanism 300, the gear lifting mechanism 420 is used for carrying the lifting frame 410 up and down to the required corresponding positions, in this embodiment, the number of layers on the shelf 22 can be different, the gear lifting mechanism 420 can sequentially lift the lifting frame 410 to the corresponding number of layers, and the tooling plate 50 is carried onto the shelf 22.

As shown in fig. 3 and 7, the lifting frame 410 is a rectangular frame, the lifting frame 410 is disposed in the frame 100 and is located between the feeding port 110 and the discharging port 120, the transverse length of the lifting frame 410 is matched with that of the transferring mechanism 200, in this embodiment, two parallel transferring mechanisms 200 are disposed in the lifting frame 410, three four transferring mechanisms 200 may be disposed in the lifting frame 410 if the frame 100 is large enough, the buffer 130 is disposed in the frame 100 corresponding to the lifting frame 410, the buffer 130 is used for stable shock absorption when the lifting frame 410 is lifted, and in this embodiment, four buffers 130 are disposed above and below the lifting frame 410 of the frame 100, and five or six different transferring mechanisms may be disposed.

As shown in fig. 7, the gear lifting mechanism 420 includes a rotating rod 422, a rotating gear 424, a toothed belt 426 and a connecting block 428, the rotating rod 422 is connected and fixed with the frame 100 through a fixed pulley, the rotating rod 422 is rotated by a gear pair, the rotating gear 424 is arranged on the rotating rod 422, the rotating gear 424 rotates along with the rotation of the rotating rod 422, the toothed belt 426 is arranged on the rotating gear 424 and rotates along with the rotating gear 424, the connecting block 428 is arranged on the outer surface of the lifting frame 410, the connecting block 428 is connected with the toothed belt 426, the toothed belt 426 is connected with the lifting frame 410 through the connecting block 428, the connecting block 428 lifts along with the rotation of the toothed belt 426, and then drives the lifting frame 410 to lift, a sliding wheel is arranged on the gear lifting mechanism 420, and the sliding wheel lifts smoothly along with a V-shaped sliding rail arranged beside the auxiliary lifting frame.

As shown in fig. 5, the driving component 310 of the feeding mechanism 300 may adopt a sliding structure or a gear transmission structure, in this embodiment, a sliding structure is adopted, the driving component 310 includes a sliding rail 312, a sliding plate 314, a connecting plate 316 and a rotating belt 318, the sliding rail 312 is disposed beside the rotating belt 318, the sliding plate 314 is mounted on the sliding rail 312 for sliding back and forth, a transverse pushing plate rod 320 is disposed on the sliding plate 314, the connecting plate 316 is mounted on the rotating belt 318 in a clamping manner, the connecting plate 316 is engaged with the sliding plate 314 in a clamping manner, the feeding motor controls the rotating belt 318 to rotate, the connecting plate 316 on the rotating belt 318 moves back and forth along with the rotation of the rotating belt 318, and then drives the sliding plate 314 to slide back and forth on the sliding rail 312, so as to extend or retract the transverse pushing plate rod 320 into the feeding opening 110.

As shown in fig. 4, the transferring mechanism 200 includes a conveyor belt structure 210 and a transferring motor 220, the transferring motor 220 is disposed below the lifting frame 410, the transferring motor 220 controls the conveyor belt structure 210 to transport the tooling plate 50, and the feeding mechanism 300 is disposed in the middle of the transferring mechanism 200 to push the tooling plate 50 out of the feeding opening 110 onto the shelf 22.

As shown in fig. 1 to 9, the present application provides a loading and transporting system, which includes an upper plate device 10 for burn-in test, a receiving device 20, an unlocking device 30, and a feeding device 40.

The upper plate device 10 for burn-in testing comprises a frame 100, a transfer mechanism 200 and a feeding mechanism 300. The frame 100 is provided with a feeding hole 110 and a discharging hole 120, the feeding hole 110 and the discharging hole 120 are arranged at the front end and the rear end of the frame 100 at intervals, the feeding hole 110 and the discharging hole 120 are not on the same horizontal plane, and the opening sizes are different. The transfer mechanism 200 is disposed in the frame 100 and between the loading opening 110 and the unloading opening 120, and is used for receiving the tooling plate 50 and delivering the tooling plate 50 out through the loading opening 110, and the carrying surface of the transfer mechanism 200 is flush with or lower than the bottom surface of the tooling plate 50. The feeding mechanism 300 comprises a driving component 310, a transverse push plate rod 320, a push plate 330 and a rotation constraint piece 324, the transverse push plate rod 320 is flush with or lower than the carrying surface of the transferring mechanism 200, the transverse push plate rod 320 is provided with a first end and a second end, the driving component 310 is used for driving the first end, the push plate 330 is rotatably arranged at the second end of the transverse push plate rod 320, the push plate 330 is in a vertical state relative to the transverse push plate rod 320 and protrudes out of the carrying surface of the transferring mechanism 200 when not receiving resistance force towards the second end, the push plate 330 is in a folding state relative to the transverse push plate rod 320 and is flush with or recessed in the carrying surface of the transferring mechanism 200 when receiving resistance force towards the second end, the driving component 310 is used for driving the transverse push plate rod 320 to move transversely to extend or retract the feeding port 110, and the push plate 330 is used for passing through the bottom surface of the tooling plate 50 in the folding state and pushing the end surface of the tooling plate 50 in the vertical state so as to push the tooling plate 50 out of the transferring mechanism 200.

The receiving device 20 includes an automatic carrying trolley 21, a shelf 22 and a locking device 23, in this embodiment, the automatic carrying trolley 21 is used for carrying the shelf 22 to the front of the loading opening 110 of the upper plate device 10 for burn-in test, the shelf 22 is used for carrying the tooling plate 50, in this embodiment, the shelf 22 is divided into three layers, each layer is provided with two tooling plates 50, the loading opening 110 corresponds to the three layers of tooling plates 50 on the shelf 22, the locking device 23 is elastically connected with the shelf 22, and in a natural state, the locking device 23 is in a diastole state relative to the shelf 22, the locking device 23 blocks the end face of the tooling plate 50 to lock the tooling plate 50 so as to prevent the tooling plate 50 from falling. The locking device 23 comprises a vertical rod 24 and a cross rod 25, a buffer sleeve 27 is sleeved outside the cross rod 25, a through groove 26 is formed in the goods shelf 22, the vertical rod 24 is vertically connected with the cross rod 25, the cross rod 25 is inserted into the through groove 26, the locking device 23 is elastically connected with the goods shelf 22, in a natural state, the cross rod 25 is positioned at the uppermost part of the through groove 26 and is flush with the tooling plate 50 to lock the tooling plate 50 due to elastic force, when the vertical rod 24 is pressed down, the cross rod 25 moves to the lower end of the through groove 26 below the tooling plate 50 to unlock so that the tooling plate 50 can be conveyed into the goods shelf 22, and then the goods shelf 22 with the tooling plate 50 can be conveyed away by the automatic carrying trolley 21.

The unlocking device 30 is arranged on the outside of the frame 100 of the upper plate device 10 for aging test and correspondingly arranged above the locking device 23, the unlocking device 30 presses down the locking device 23 to unlock and enable the tooling plate 50 to be carried in, in the embodiment, the unlocking device 30 is a telescopic cylinder, when the goods shelf 22 is carried to the feeding opening 110 by the automatic carrying trolley 21, the locking device 23 and the telescopic cylinder are positioned on the same vertical line, at the moment, the telescopic cylinder presses down the locking device 23 to enable the locking device 23 to be in a compressed state relative to the goods shelf 22, at the moment, the locking device 23 unlocks the end face of the tooling plate 50, and the tooling plate 50 can be smoothly carried onto the goods shelf 22 by the upper plate device 10 for aging test.

The feeding device 40 corresponds to the discharge port 120 of the upper plate device 10 for burn-in testing, the feeding device 40 is used for feeding the tooling plate 50 to the transfer mechanism 200 through the discharge port 120, the feeding device 40 adopts a double-speed chain in the embodiment, and the transfer mechanism 200 transports the tooling plate 50 to the feed port 110 after the feeding device 40 conveys the tooling plate 50 to the transfer mechanism 200.

In summary, as will be readily understood by those skilled in the art, in the upper plate device 10 for burn-in testing and the loading and transporting system provided by the present application, before the automatic carrying trolley 21 transports the pallet 22 to the loading port 110 of the upper plate device 10 for burn-in testing, the three layers of tooling plates 50 on the pallet 22 are matched and corresponding to the positions of the loading port 110, at this time, the unlocking device 30 and the locking device 23 are located on the same vertical line, the unlocking device 30 presses the locking device 23 to unlock the tooling plates 50, at this time, the feeding device 40 transports the tooling plates 50 to the transferring mechanism 200, the lifting device 400 transports the tooling plates 50 to the position corresponding to the discharge port 120, at this time, the loading mechanism 300 pushes the tooling plates 50 from the transferring mechanism to the pallet, the locking device 23 locks the tooling plates 50, and the automatic carrying trolley transports the pallet 22 with the tooling plates 50, namely, because the transverse push plate rods 320 in the loading mechanism 300 or the carrying surfaces lower than the transferring mechanism 200 are located on the same vertical line, the push plate 330 is used for pushing the tooling plates 50 to the bottom surface of the tooling plates in a folded state and pushing the tooling plates 50 to the high efficiency, and the tooling plate loading and the tooling plate 50 is pushed up by the high level.

The above examples of the present application are only examples for clarity of illustration of the present application and are not limiting of the embodiments of the present application. Other variations or modifications of the above teachings will be apparent to those of ordinary skill in the art. It is not necessary here nor is it exhaustive of all embodiments. Any modifications, equivalent substitutions, improvements, etc. that fall within the spirit and principles of the present application are intended to be included within the scope of the present application.

Claims (10)

1. A top plate apparatus (10) for burn-in testing, the top plate apparatus (10) for burn-in testing comprising:

the machine frame (100) is provided with a feeding port (110) and a discharging port (120);

the transferring mechanism (200) is arranged in the frame (100) and positioned between the feeding opening (110) and the discharging opening (120) and is used for receiving the tooling plate (50) and sending the tooling plate (50) out through the feeding opening (110);

the feeding mechanism (300) comprises a driving assembly (310), a transverse pushing plate rod (320), a pushing plate (330) and a rotation restraint member (324), wherein the transverse pushing plate rod (320) is flush with or lower than the carrying surface of the transferring mechanism (200), the transverse pushing plate rod (320) is provided with a first end and a second end, the driving assembly (310) is used for driving the first end, the rotation restraint member (324) is arranged at the second end, the pushing plate (330) is rotatably arranged at the second end of the transverse pushing plate rod (320) and is restrained by the rotation restraint member (324) when rotating, the pushing plate (330) is in a vertical state relative to the transverse pushing plate rod (320) when not being subjected to resistance towards the second end and protrudes out of the carrying surface of the transferring mechanism (200), the pushing plate (330) is in a folding state relative to the transverse pushing plate rod (320) when being subjected to resistance towards the second end and is flush with or recessed in the carrying surface of the transferring mechanism (200), the pushing plate (330) is used for driving the pushing plate (320) to extend out of the transverse feeding mechanism (110), the pushing plate (330) is used for pushing the end face of the tooling plate (50) in the vertical state through the bottom surface of the tooling plate (50) in the folded state so as to push the tooling plate (50) out of the transfer mechanism (200).

2. The upper plate device (10) for burn-in testing according to claim 1, wherein the lateral push plate lever (320) extends with a clamping plate (322), the clamping plate (322) being provided with hinge holes for rotatably arranging the push plate (330), the rotation restriction (324) being arranged between the clamping plates (322), the top of the rotation restriction (324) being lower than the hinge holes, the push plate (330) being arranged at a side of the rotation restriction (324) near the first end, the push plate (330) being rotated near towards the top of the rotation restriction (324) when being subjected to a resistance force towards the second end.

3. Upper plate device (10) for burn-in testing according to claim 2, characterized in that:

the pushing plate (330) is kept in the vertical state relative to the transverse pushing plate rod (320) through a torsion spring; or alternatively

The pushing plate (330) is asymmetrically arranged one end of the pushing plate is heavy, the other end of the pushing plate is light, and the vertical state is kept relative to the transverse pushing plate rod (320) based on natural gravity distribution.

4. The upper plate device (10) for burn-in testing according to claim 1, wherein the upper plate device (10) for burn-in testing comprises a lifting device (400), the lifting device (400) comprises a lifting frame (410) and a gear lifting mechanism (420), the lifting frame (410) is used for carrying the transferring mechanism (200) and the feeding mechanism (300), and the gear lifting mechanism (420) is used for carrying the lifting frame (410) up and down to the required corresponding positions.

5. The upper plate device (10) for burn-in testing according to claim 4, wherein the lifting frame (410) is a rectangular frame, the lifting frame (410) is arranged in the frame (100) and is located between the feeding port (110) and the discharging port (120), the transverse length of the lifting frame (410) is matched with the transverse length of the transferring mechanism (200), a buffer (130) is arranged in the frame (100) corresponding to the lifting frame (410), and the buffer (130) is used for stably absorbing shock when the lifting frame (410) is lifted.

6. The upper plate device (10) for burn-in testing according to claim 5, wherein the gear lifting mechanism (420) comprises a rotating rod (422), a rotating gear (424), a toothed belt (426) and a connecting block (428), the rotating rod (422) is connected and fixed with the frame (100) through a fixed pulley, the rotating gear (424) is arranged on the rotating rod (422), the rotating gear (424) rotates along with the rotation of the rotating rod (422), the toothed belt (426) is arranged on the rotating gear (424) and lifts along with the rotation of the rotating gear (424), and the toothed belt (426) is connected with the lifting frame (410) through the connecting block (428).

7. The upper plate device (10) for burn-in testing according to claim 1, wherein the drive assembly (310) of the loading mechanism (300) may employ a sliding structure or a gear transmission structure.

8. The upper plate device (10) for burn-in testing according to claim 4, wherein the transfer mechanism (200) comprises a conveyor belt structure (210) and a transfer motor (220), the transfer motor (220) being disposed below the lifting frame (410), the transfer motor (220) controlling the conveyor belt structure (210) to transport the tooling plate (50).

9. The upper plate device (10) for burn-in testing according to claim 1, wherein the loading mechanism (300) is provided in the middle of the transfer mechanism (200).

10. The utility model provides a material loading conveying system which characterized in that, material loading conveying system includes:

upper plate device (10) for burn-in testing according to any one of claims 1 to 9;

the material receiving device (20) comprises an automatic carrying trolley (21), a goods shelf (22) and a locking device (23), wherein the automatic carrying trolley (21) is used for carrying the goods shelf (22) to the front of the material loading opening (110) of the upper plate device (10) for aging test, the goods shelf (22) is used for carrying the tooling plate (50), the locking device (23) is elastically connected with the goods shelf (22), and the locking device (23) is used for locking the tooling plate (50) so as to prevent the tooling plate (50) from falling;

the unlocking device (30) is arranged on the outside of the rack (100) of the upper plate device (10) for burn-in testing, and the unlocking device (30) presses down the locking device (23) to unlock and enable the tooling plate (50) to be moved in;

and the feeding device (40) corresponds to the discharging hole (120) of the upper plate device (10) for aging test, and the feeding device (40) is used for feeding the tooling plate (50) to the transferring mechanism (200).