CN216996463U - Ageing material feeding unit - Google Patents

Abstract

The utility model discloses an aging feeding device, which comprises: a moving assembly movable between a sensing position and a feeding position; the tray is suitable for placing a piece to be tested; the detection line is suitable for being connected with the piece to be detected; the tray is arranged at the interval of the conveying device and is arranged on the moving assembly when the moving assembly is located at the detection position, the detection line is connected with the piece to be detected, the moving assembly moves from the detection position to the feeding position, the detection line is separated from the piece to be detected, the tray is gradually close to the conveying device until the tray is contacted with the conveying device, and the conveying device drives the tray to move towards the direction away from the moving assembly. The aging feeding device provided by the embodiment of the utility model can automatically separate the detection line and the piece to be detected, and has the advantages of convenience in operation, high working efficiency and the like.

Description

Ageing material feeding unit

Technical Field

The utility model relates to the technical field of electronic equipment detection, in particular to an aging feeding device.

Background

The aging feeding device in the related technology can be used for predicting the service life of a product and evaluating or predicting the durability of the produced product for a manufacturer, but the existing aging feeding device needs to set aging time for a piece to be tested, manually removes a detection line of the piece to be tested after the aging time is finished, and then carries out subsequent detection on the piece to be tested after the aging, so that not only is the time for finishing the aging required to be continuously paid attention to by a worker during the aging period, but also the situation of rear-end material waiting is possibly caused, and unnecessary waiting working time is generated, and the working efficiency is reduced.

SUMMERY OF THE UTILITY MODEL

The present invention is directed to solving at least one of the problems of the prior art. Therefore, one object of the present invention is to provide an aging feeding device, which can automatically separate a detection line from a workpiece to be detected, and has the advantages of convenience in operation, high work efficiency, and the like.

In order to achieve the above object, an embodiment of the present invention provides an aging feeding device, including: a moving assembly movable between a sensing position and a feeding position; the tray is suitable for placing a piece to be tested; the detection line is suitable for being connected with the piece to be detected; the tray is arranged at the interval of the moving assembly when the moving assembly is located at the detection position, the moving assembly is arranged at the interval of the tray and the conveying assembly, the detection line is connected with the piece to be detected, the moving assembly moves from the detection position to the feeding position, the detection line is separated from the piece to be detected, the tray is gradually close to the conveying assembly until the tray is contacted with the conveying assembly, and the conveying assembly drives the tray to move in the direction away from the moving assembly.

The aging feeding device provided by the embodiment of the utility model can automatically separate the detection line and the piece to be detected, and has the advantages of convenience in operation, high working efficiency and the like.

According to some embodiments of the utility model, a side of the moving assembly facing the conveying device is provided with a row of support columns, the row of support columns is provided with a plurality of support columns, the conveying device comprises a positioning plate and a plurality of rollers arranged on the side of the positioning plate facing the moving assembly, each roller is rotatable relative to the positioning plate, and the plurality of rollers and the plurality of support columns are alternately and alternately arranged in the extending direction of the positioning plate; when the moving assembly is located at the detection position, the tray is arranged on the support column row; and in the process that the moving assembly moves from the detection position to the feeding position, the tray gradually approaches the plurality of rollers until the tray is contacted with the plurality of rollers, and the plurality of rollers drive the tray to move in the direction far away from the moving assembly through rotation.

According to some embodiments of the utility model, the side of the row of support posts facing the tray does not extend beyond the side of each roller facing the tray when the moving assembly is in the feeding position.

According to some embodiments of the present invention, the number of the trays is plural, the number of the supporting columns is plural, the supporting columns are arranged at intervals along the moving direction of the moving assembly, and when the moving assembly is at the detection position, the plural trays are arranged in the plural supporting columns in a one-to-one correspondence manner.

According to some embodiments of the utility model, the aging feed device further comprises: the mobile assembly is provided with an accommodating space which penetrates through the mobile assembly along the moving direction of the mobile assembly, the wire pulling plate is arranged in the accommodating space, and the mobile assembly moves from the detection position to the feeding position, and the detection line is abutted to the wire pulling plate to be separated from the piece to be detected.

According to some embodiments of the utility model, the accommodating space has a first side wall, a second side wall, a third side wall and a fourth side wall which are connected end to end in sequence, the first side wall is far away from the conveying device, the inner side of the first side wall is provided with the detection line, the third side wall is close to the conveying device and is provided with a line passing hole, and two opposite sides of the line pulling plate are slidably connected with the second side wall and the fourth side wall respectively; when the movable assembly is located at the detection position, the tray is arranged on the outer side of the third side wall, the detection line penetrates through the line passing hole to be connected with the piece to be detected, and at least part of the wire pulling plate is located between the detection line and the conveying device in the moving direction of the movable assembly.

According to some embodiments of the utility model, the power strip comprises: a first sliding section and a second sliding section, the first sliding section slidably connected with the second sidewall, the second sliding section slidably connected with the fourth sidewall; the first connecting section and the second connecting section are arranged at intervals along the moving direction of the moving assembly, two ends of the first connecting section are respectively connected with one end of the first sliding section and one end of the second sliding section, and two ends of the second connecting section are respectively connected with the other end of the first sliding section and the other end of the second sliding section; the abutting section is located between the first connecting section and the second connecting section in the moving direction of the moving assembly, and two ends of the abutting section are connected with the first sliding section and the second sliding section respectively; wherein when the moving assembly is in the detecting position, the abutting section is located between the detecting line and the conveying device in the moving direction of the moving assembly; and in the process that the moving assembly moves from the detection position to the feeding position, the detection line is abutted against the abutting section to be separated from the piece to be detected.

According to some embodiments of the utility model, the moving assembly comprises: the first moving plate is arranged on one side, facing the conveying device, of the wire drawing plate, first edges, facing the bent wire drawing plate, are arranged on two opposite sides of the first moving plate, each first edge forms a side wall of the accommodating space and is provided with a first sliding groove extending along the moving direction of the moving assembly, and a first sliding block matched with the first sliding groove is arranged on one side, facing the first moving plate, of the wire drawing plate; the second movable plate is arranged on the back of the wire drawing plate, one side of the conveying device is limited by the first movable plate, the accommodating space is defined by the second movable plate, the two opposite sides of the second movable plate are provided with second edges bent towards the wire drawing plate, each second edge is formed on the side wall of the accommodating space, the side wall of the accommodating space is provided with a second sliding groove extending along the moving direction of the moving assembly, and one side of the second movable plate is provided with a second sliding block matched with the second sliding groove.

According to some embodiments of the utility model, the aging feeding device further comprises: a fixed block is arranged on one side of the moving assembly, which is back to the conveying device, a threaded hole penetrating through the fixed block along the moving direction of the moving assembly is formed in the fixed block, and the screw penetrates through the threaded hole and is in threaded fit with the threaded hole; the first stop block and the second stop block are respectively arranged on two opposite sides of the fixed block along the moving direction of the moving assembly, the fixed block abuts against the first stop block when the moving assembly is at the detection position, and the fixed block abuts against the second stop block when the moving assembly is at the feeding position; the motor is provided with a motor shaft, and the motor shaft is in transmission connection with the screw rod.

According to some embodiments of the utility model, the moving component drives the tray to move along the vertical direction, and the conveying device drives the tray to move along the horizontal direction.

Additional aspects and advantages of the utility model will be set forth in part in the description which follows and, in part, will be obvious from the description, or may be learned by practice of the utility model.

Drawings

The above and/or additional aspects and advantages of the present invention will become apparent and readily appreciated from the following description of the embodiments, taken in conjunction with the accompanying drawings of which:

fig. 1 is a schematic structural diagram of an aging feeding device according to an embodiment of the present invention.

Fig. 2 is a schematic structural diagram of another view angle of the aging feeding device according to the embodiment of the utility model.

Fig. 3 is an exploded view of an aging feeder, according to an embodiment of the present invention.

Fig. 4 is a schematic view of the assembly of the moving assembly and the rows of support posts of the burn-in feed apparatus according to an embodiment of the present invention.

Fig. 5 is a schematic structural diagram of a wire pulling plate of the aging feeding device according to an embodiment of the utility model.

Fig. 6 is a schematic structural view of a tray of the aging feeder according to an embodiment of the present invention.

Reference numerals are as follows:

an aging feeding device 1,

The movable assembly 100, the accommodating space 110, the wire passing hole 111, the first sidewall 112, the second sidewall 113, the third sidewall 114, the fourth sidewall 115, the sliding groove 120, the first moving plate 130, the first sliding groove 131, the first edge 132, the second moving plate 140, the second sliding groove 141, the second edge 142, the first connecting member 150, the second connecting member 151, the fixing block 160, the first connecting member 115, the second connecting member 140, the second connecting member 151, the fixing block 160, the second connecting member 115, and the third connecting member,

Support column row 200, support columns 210,

A tray 300, a mounting groove 310,

A transmission device 400, a positioning plate 410, a roller 420,

The wire drawing board 500, the sliding protrusion 510, the first sliding section 520, the second sliding section 530, the first connecting section 540, the second connecting section 550, the stop section 560, the first sliding block 570, the second sliding block 580, the wire drawing board,

The screw 600, the first stop block 700, the second stop block 800, the motor 900 and the motor shaft 910.

Detailed Description

Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the accompanying drawings are illustrative only for the purpose of explaining the present invention, and are not to be construed as limiting the present invention.

In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "axial", "radial", "circumferential", and the like, indicate orientations and positional relationships based on the orientations and positional relationships shown in the drawings, and are used merely for convenience in describing the present invention and for simplicity in description, and do not indicate or imply that the device or element so referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore, should not be construed as limiting the present invention.

In the description of the present invention, "the first feature" and "the second feature" may include one or more of the features.

In the description of the present invention, "a plurality" means two or more, and "several" means one or more.

An aging feeding apparatus 1 according to an embodiment of the present invention is described below with reference to the drawings.

As shown in fig. 1 to 6, the burn-in feeding apparatus 1 according to the embodiment of the present invention includes a moving assembly 100, a tray 300, a sensing line (not shown), and a conveying apparatus 400.

The movable assembly 100 is movable between a detection position and a feeding position, the tray 300 is suitable for placing a piece to be detected (not shown in the figure), the detection line is suitable for being inserted into a detection hole of the piece to be detected, when the movable assembly 100 is located at the detection position, the tray 300 and the conveying device 400 are arranged at intervals and are arranged on the movable assembly 100, the detection line is connected with the piece to be detected, the movable assembly 100 moves from the detection position to the feeding position, the detection line is separated from the piece to be detected, the tray 300 is gradually close to the conveying device until contacting with the conveying device 400, and the conveying device 400 drives the tray 300 to move towards the direction far away from the movable assembly 100.

For example, the device under test may be an electronic device such as a mobile phone, a tablet computer, or a notebook computer.

In the figure, the direction indicated by the arrow a is the moving direction of the moving assembly 100, and the direction indicated by the arrow B is the conveying direction of the conveying device 400.

According to the aging feeding device 1 provided by the embodiment of the utility model, the moving assembly 100 is movably arranged between the detection position and the feeding position, the tray 300 is suitable for placing the piece to be detected, the tray 300 can support and fix the piece to be detected and can drive the piece to be detected to move when the tray 300 moves, wherein the detection position is the position where the moving assembly 100 is located when the piece to be detected is in the detection process, and after the piece to be detected is detected, the moving assembly 100 can drive the piece to be detected to move to the feeding position, so that the piece to be detected can move from the feeding position to the next station to be separated from the aging feeding device 1.

In addition, the detection line is connected with the movable assembly 100 and is suitable for being inserted into the detection hole of the piece to be detected, and the detection line can acquire the data condition of the piece to be detected in real time, so that the aging condition of the piece to be detected can be observed conveniently. When the movable assembly 100 is located at the detection position, the tray 300 and the conveying device 400 are arranged at intervals and are arranged on the movable assembly 100, and the detection line is connected with the piece to be detected, so that when the movable assembly 100 is located at the detection position, the tray 300 cannot interfere with the conveying device 400 in position, and the detection line can detect the aging condition of the piece to be detected when the movable assembly 100 is located at the detection position.

In addition, in the process that the moving assembly 100 moves from the detection position to the feeding position, the detection line is separated from the piece to be detected, the tray 300 gradually approaches the conveying device until the tray contacts the conveying device 400, and the conveying device 400 drives the tray 300 to move in the direction away from the moving assembly 100. That is, when the moving member 100 is located at the detecting position, the tray 300 and the conveying device 400 are not moved, and when the tray 300 contacts the conveying device 400 during the moving member 100 moves from the detecting position to the feeding position, the tray 300 moves along with the conveying device 400.

Wherein, can set for ageing material feeding unit 1 ageing time, it can move the subassembly 100 and can drive the piece that awaits measuring automatically and move to the pay-off position by the detection position after arriving ageing time to convey the piece that awaits measuring to conveyer 400, and, in the in-process that the subassembly 100 moved to the pay-off position by the detection position, the position of the piece that awaits measuring changes, and the detection line of connecting the piece that awaits measuring can receive the dragging, makes the piece that awaits measuring automatic and detection line separation, conveyer 400 drives the piece that awaits measuring again and moves to next station and breaks away from ageing material feeding unit 1.

It should be noted that the moving direction of the moving assembly 100 is not parallel to the conveying direction of the conveying device 400, so that the conveying device 400 can carry the tray 300 and drive the tray 300 to move, and the structural arrangement is more reasonable.

Therefore, the aging feeding device 1 in the embodiment of the utility model does not need a worker to manually pull out the detection line and separate the piece to be detected from the aging feeding device 1, so that the worker can operate more conveniently, the situation of rear-end material waiting can not occur, the piece to be detected is immediately sent to the next detection procedure after aging is finished, unnecessary waiting time is avoided, and the work efficiency of the aging feeding device 1 is improved.

Therefore, the aging feeding device 1 provided by the embodiment of the utility model can automatically separate the detection line and the piece to be detected, and has the advantages of convenience in operation, high working efficiency and the like.

The following description will be given by taking the moving assembly 100 moving in the vertical direction and the conveying direction of the conveying device 400 moving in the horizontal direction as an example, that is, the moving assembly 100 driving the tray 300 can move in the vertical direction and the conveying device 400 driving the tray 300 can move in the horizontal direction. Of course, it is understood that in other embodiments of the present invention, the moving direction of the moving assembly 100 is not limited to the vertical direction, and the conveying direction of the conveyor 400 is not limited to the horizontal direction.

In some embodiments of the present invention, as shown in fig. 1-3, the side of the moving assembly 100 facing the conveyor 400 is provided with a row of support columns 200, and the conveyor 400 includes a positioning plate 410 and a plurality of rollers 420 provided on the side of the positioning plate 410 facing the moving assembly 100.

Support column row 200 is equipped with a plurality of support columns 210, a plurality of support columns 210 can be followed the length direction interval setting of support column row 200, the one end that is close to removal subassembly 100 that removal subassembly 100 can fix support column 210 makes support column row 200 can stable support tray 300 and the piece that awaits measuring, and support column row 200 can link into an integrated entity with removal subassembly 100 moreover, can drive support column row 200 when removal subassembly 100 removes to drive the piece that awaits measuring and remove.

Specifically, the rollers 420 can rotate relative to the positioning plate 410, and the rotation axes of the rollers 420 are parallel, the moving assembly 100 drives the to-be-tested object to move downward, when the upper surface of the supporting column row 200 of the moving assembly 100 is lower than or equal to the upper surface of the rollers 420, the to-be-tested object is supported by the supporting column row 200 and becomes supported by the rollers 420, at this time, friction force may exist between the to-be-tested object and the rotating rollers 420, and the rollers 420 drive the to-be-tested object to move along the horizontal direction.

And, a plurality of rollers 420 and a plurality of support columns 210 are alternately and alternately arranged in the extending direction of the positioning plate 410, the plurality of rollers 420 are connected with one side of the positioning plate 410 facing the moving assembly 100 and are arranged at intervals along the length direction of the positioning plate 410, each roller 420 and the moving assembly 100 are arranged at intervals in the horizontal direction, and when the moving assembly 100 drives the object to be tested to vertically move downwards, each support column 210 passes through between two adjacent rollers 420.

In other words, the gap between adjacent supporting columns 210 is not smaller than the diameter of the rollers 420, the gap between adjacent rollers 420 is not smaller than the diameter of the supporting columns 210, and the side of the positioning plate 410 facing the moving assembly 100 and the side of the supporting column row 200 facing the conveying device 400 are spaced, so that each supporting column 210 can pass through between two adjacent rollers 420, and the conveying device 400 and the moving assembly 100 are prevented from interfering.

Wherein, the upper surface of support column row 200 is the horizontal plane, and tray 300 is placed in the upper surface of support column row 200, is more convenient for place tray 300 and cell-phone steadily, and when removal subassembly 100 drove support column row 200 vertical migration, support column row 200 still can keep the cell-phone stable not landing.

Further, when the moving assembly 100 is in the feeding position, the side of the row of support posts 200 facing the tray 300 does not extend beyond the side of each roller 420 facing the tray 300.

Thus, when the moving assembly 100 moves to the feeding position, one side of the tray 300 facing away from the piece to be tested can be stopped by one side of the roller 420 facing the tray 300, so that the tray 300 is separated from the support column row 200, the tray 300 does not move along with the moving assembly 100 any more, and the tray 300 can drive the piece to be tested to move along with the roller 420, so that the piece to be tested is separated from the aging feeding device 1.

In some embodiments of the present invention, as shown in fig. 1-4, the supporting column rows 200 are disposed at intervals along the moving direction of the moving assembly 100, the trays 300 are disposed in plural, the trays 300 are disposed between two adjacent supporting column rows 200, and when the moving assembly 100 is at the detecting position, the trays 300 are disposed in the supporting column rows 200 in a one-to-one correspondence manner.

It should be noted that the interval between adjacent support column rows 200 is larger than the sum of the thickness of the tray 300 and the thickness of the object to be tested, so that the tray 300 and the object to be tested can be easily placed on the upper surface of the support column row 200.

Therefore, the tray 300 can be placed on the upper surface of each support column row 200, so that the aging feeding device 1 can accommodate more workpieces to be tested at the same time, and the working efficiency of the aging feeding device 1 is further improved.

Optionally, as shown in fig. 6, the upper surface of the tray 300 is provided with a plurality of mounting grooves 310 along the length direction thereof, each mounting groove 310 is suitable for placing a piece to be tested, specifically, the plurality of mounting grooves 310 are formed by inward depression of the upper surface of the tray 300, so that each tray 300 can position a plurality of pieces to be tested through the plurality of mounting grooves 310, and when the testing line is separated from the piece to be tested, the groove wall of the mounting groove 310 can limit the piece to be tested, the piece to be tested is prevented from being pulled to separate from the tray 300 by the testing line, and the piece to be tested is more easily separated from the testing line.

In addition, the detection line can be equipped with a plurality of plugs, and a plurality of plugs insert the hole of waiting to detect of a plurality of pieces that await measuring one-to-one, and the detection line can be a whole like this, and the volume of detection line is less, is favorable to reducing the space that the detection line occupy, further is convenient for arrange of detection line.

Or, the detection line is a plurality of, and a plurality of detection lines insert the waiting to test hole of a plurality of pieces that await measuring one-to-one, and every detection line connects a piece that awaits measuring respectively like this, and just every detection line arranges for alone, when one of them detection line breaks down, is difficult for influencing other detection lines, and it is also more convenient to maintain.

In some embodiments of the present invention, as shown in fig. 1 to 4, the aging feeding device 1 further includes a pulling plate 500, and the pulling plate 500 may support and fix the moving assembly 100, so that different positions of the moving assembly 100 in the vertical direction can be kept balanced, and thus the to-be-tested piece can be supported and driven to move.

The thickness direction of the power strip 500 is perpendicular to the vertical direction, the moving assembly 100 is provided with an accommodating space 110 penetrating through the moving assembly in the vertical direction, and the power strip 500 is located in the accommodating space 110.

For example, the wire drawing plate 500 may be provided with the sliding protrusion 510 and the side wall of the accommodating space 110 is provided with the sliding groove 120, or the side wall of the accommodating space 110 may be provided with the sliding protrusion 510 and the wire drawing plate 500 is provided with the sliding groove 120. Moreover, the sliding protrusion 510 and the sliding groove 120 both extend in the vertical direction, so that the moving assembly 100 can slide in the vertical direction relative to the power strip 500, and the sliding protrusion 510 and the sliding groove 120 can limit and guide the movement of the moving assembly 100 in a matching manner, thereby facilitating the movement of the moving assembly 100.

In addition, the detection line is arranged on one of the side walls of the accommodating space 110, which is far away from the conveying device 400, when the moving assembly 100 moves from the detection position to the feeding position, the detection line is abutted against the wire pulling plate 500 to be separated from the piece to be detected, and one end of the detection line, which is connected with the piece to be detected, is abutted against the wire pulling plate 500 to prevent one end of the detection line from continuously moving along with the piece to be detected.

It can be understood that, the line pulling plate 500 can be kept stationary when the moving assembly 100 moves, and the moving assembly 100 drives the piece to be detected to move and also drives the detection line to move, when the moving assembly 100 drives the piece to be detected to move, the line pulling plate 500 can stop the detection line so that the detection line is pulled to the limit length, thereby preventing the detection line from continuously moving along with the piece to be detected, the purpose of separating the detection line from the piece to be detected is achieved, and the piece to be detected can be conveyed to the aging feeding device 1 by the conveying device 400 to finish aging.

Further, as shown in fig. 1, the accommodating space 110 has a first side wall 112, a second side wall 113, a third side wall 114 and a fourth side wall 115 connected end to end in sequence, the first side wall 112 is far away from the conveyor 400 and the inner side thereof is provided with a detection line, the third side wall 114 is close to the conveyor 400 and is provided with a wire passing hole 111, and opposite sides of the wire pulling plate 500 are slidably connected with the second side wall 113 and the fourth side wall 115 respectively.

Wherein, the wire passing hole 111 penetrates through the third side wall 114, so that the detection wire can directly penetrate through the wire passing hole 111 to be connected with a piece to be detected, the connection is more convenient, the length of the detection wire is favorably shortened, the wire harness is easier to arrange, and the phenomenon that the wire harness is too long and interferes with other parts can be avoided.

When the moving assembly 100 is located at the detection position, the tray 300 is disposed on the outer side of the third side wall 114, the detection line passes through the line passing hole 111 to be connected with the to-be-detected object, and at least a portion of the line pulling plate 500 is located between the detection line and the conveying device 400 in the moving direction of the moving assembly 100. Like this, when the position of removal subassembly 100 for conveyer 400 changes, removal subassembly 100 can drive the detection line and move, and the line drawing board 500 position is unchangeable to make the line drawing board 500 can block the detection line and move, so that detection line and the piece that awaits measuring break away from.

Optionally, as shown in fig. 5, the wire pulling plate 500 includes a first sliding section 520, a second sliding section 530, a first connecting section 540, a second connecting section 550 and a stop section 560.

The first sliding section 520 is slidably connected with the second side wall 113, the second sliding section 530 is slidably connected with the fourth side wall 115, the first connecting section 540 and the second connecting section 550 are arranged at intervals along the moving direction of the moving assembly 100, two ends of the first connecting section 540 are respectively connected with one end of the first sliding section 520 and one end of the second sliding section 530, two ends of the second connecting section 550 are respectively connected with the other end of the first sliding section 520 and the other end of the second sliding section 530, the abutting section 560 is located between the first connecting section 540 and the second connecting section 550 in the moving direction of the moving assembly 100, and two ends are respectively connected with the first sliding section 520 and the second sliding section 530.

Specifically, the first sliding section 520 and the second sliding section 530 extend along the vertical direction and are arranged at intervals along the horizontal direction, the first connecting section 540 and the second connecting section 550 extend along the horizontal direction and are arranged at intervals along the vertical direction, the resisting section 560 extends along the horizontal direction and is located between the first connecting section 540 and the second connecting section 550, and two ends of the resisting section 560 are connected with the first sliding section 520 and the second sliding section 530 respectively.

Therefore, the first sliding section 520, the second sliding section 530, the first connecting section 540 and the second connecting section 550 are connected into a closed loop, so that the structure of the wire drawing board 500 is more stable, and the middle of the wire drawing board 500 is of a hollow structure, which is beneficial to reducing the weight of the wire drawing board 500.

When the moving assembly 100 is located at the detecting position, the abutting section 560 is located between the detecting line and the conveying device 400 in the moving direction of the moving assembly 100, and the detecting line abuts against the abutting section 560 to be separated from the workpiece to be detected in the moving process of the moving assembly 100 from the detecting position to the feeding position.

Moreover, the detection line passes through the gap between the first connecting section 540 and the abutting section 560 and the wire passing hole 111 to be connected with the piece to be detected, and when the moving assembly 100 moves towards the conveying device 400, one end of the detection line connected with the piece to be detected abuts against the abutting section 560 to prevent one end of the detection line from continuously moving along with the piece to be detected.

For example, the abutting section 560 may be located at an end of the wire pulling plate 500 close to the conveyor 400, that is, a distance between the abutting section 560 and the second connecting section 550 is smaller than a distance between the abutting section 560 and the first connecting section 540, so that a larger number of detection lines can be accommodated between the first connecting section 540 and the abutting section 560, that is, the aging feeding device 1 can simultaneously detect a larger number of detection pieces.

After the aging time is over, when the moving assembly 100 drives the piece to be detected to approach the conveying device 400, the detection line moves towards the direction approaching the abutting section 560, so that the detection line is blocked by the abutting section 560 and separated from the detection hole, and the separation between the detection line and the piece to be detected is realized. In addition, the height difference between the tray 300 and the conveying device 400 is smaller, and when the detection line is separated from the object to be detected, the tray 300 can be immediately moved to the conveying device 400, so that the moving probability of the object to be detected is reduced.

In some embodiments of the present invention, the line passing holes 111 are disposed between adjacent support column rows 200, for example, the number of the line passing holes 111 is multiple, the number of the detection lines is multiple, the detection lines correspond to the line passing holes 111 one by one, and each detection line is connected to the to-be-tested member supported by the support column row 200 below the corresponding line passing hole 111.

In some embodiments of the present invention, as shown in fig. 1-4, the moving assembly 100 includes a first moving plate 130, a second moving plate 140, and a first link 150 and a second link 151.

The first moving plate 130 is disposed on one side of the wire pulling plate 500 facing the transmission device 400, first edges 132 facing the bent wire pulling plate 500 are disposed on opposite sides of the first moving plate 130, each first edge 132 forms a sidewall of the accommodating space 110 and is provided with a first sliding groove 131 extending along a moving direction of the moving assembly 100, and a first sliding block 570 matched with the first sliding groove 131 is disposed on one side of the wire pulling plate 500 facing the first moving plate 130.

The second moving plate 140 is disposed on a side of the wire drawing plate 500 facing away from the transmission device 400 and defines the accommodating space 110 together with the first moving plate 130, second edges 142 of the wire drawing plate 500 bent towards each other are disposed on opposite sides of the second moving plate 140, each second edge 142 forms a side wall of the accommodating space 500 and is provided with a second sliding groove 141 extending along the moving direction of the moving assembly 100, and a second slider 580 matched with the second sliding groove 141 is disposed on a side of the wire drawing plate 500 facing towards the second moving plate 140.

The first connecting member 150 has two ends respectively connected to the first edge 132 and the second edge 142 of one side of the moving assembly 100, and the second connecting member 151 has two ends respectively connected to the first edge 132 and the second edge 142 of the other side of the moving assembly 100.

Specifically, the thickness direction of the first moving plate 130 and the thickness direction of the second moving plate 140 are both perpendicular to the vertical direction, the first moving plate 130 and the second moving plate 140 are respectively disposed on two sides of the thickness direction of the wire drawing plate 500 and jointly define the accommodating space 110, the first sliding groove 131 and the second sliding groove 141 extend along the vertical direction, the first connecting piece 150 and the second connecting piece 151 are respectively disposed on two opposite sides of the moving assembly 100 in the horizontal direction, the first sliding block 570 and the second sliding block 580 extend along the vertical direction, the first sliding block 570 is fitted to the first sliding groove 131, and the second sliding block 580 is fitted to the second sliding groove 141.

In this way, both sides of the thickness direction of the wire drawing board 500 are matched with the moving assembly 100 through the sliding protrusions 510 and the sliding grooves 120, the moving assembly 100 moves more easily relative to the wire drawing board 500, and the positioning effect of the wire drawing board 500 on the moving assembly 100 is better.

The first moving plate 130 and the second moving plate 140 are integrally connected by connecting the first connecting unit 150 and the second connecting unit 151 to the first moving plate 130 and the second moving plate 140, respectively, so that the first moving plate 130 and the second moving plate 140 can simultaneously move relative to the wire pulling plate 500.

Preferably, the first sliding grooves 131 are formed on two opposite sides of the first moving plate 130 in the horizontal direction, and the second sliding grooves 141 are formed on two opposite sides of the second moving plate 140 in the horizontal direction, so that the two first sliding grooves 131 are simultaneously matched with the first sliding blocks 570, the two second sliding grooves 141 are simultaneously matched with the second sliding blocks 580, the connection between the first moving plate 130 and the wire pulling plate 500 and the connection between the second moving plate 140 and the wire pulling plate 500 are more stable, and the movement of the first moving plate 130 and the second moving plate 140 is smoother.

In some embodiments of the present invention, as shown in fig. 2, the aging feeding device 1 further includes a screw 600, a first stop block 700, a second stop block 800, and a motor 900.

One side of the moving assembly 100, which faces away from the conveying device 400, is provided with a fixed block 160, the fixed block 160 is provided with a threaded hole which penetrates through the fixed block 160 along the moving direction of the moving assembly 100, the screw 600 penetrates through the threaded hole and is in threaded fit with the threaded hole, the first stop block 700 and the second stop block 800 are respectively arranged on two opposite sides of the fixed block 160 along the moving direction of the moving assembly 100, the fixed block 160 abuts against the first stop block 700 when the moving assembly 100 is at the detection position, the fixed block 160 abuts against the second stop block 800 when the moving assembly 100 is at the feeding position, the motor 900 is provided with a motor shaft 910, and the motor shaft 910 is in transmission connection with the screw 600.

For example, the screw 600 may be arranged in a vertical direction, the fixing block 160 is fixedly connected to the moving assembly 100, the motor 900 may drive the screw 600 to rotate through the motor shaft 910, when the screw 600 rotates relative to the fixing block 160, the fixing block 160 may be changed into a linear motion relative to the rotation of the screw 600 through a screw-thread fit, the fixing block 160 may move in an axial direction of the screw 600, thereby driving the moving assembly 100 to move in the vertical direction, and the first stopper 700 and the second stopper 800 may limit the fixing block 160, thereby preventing the fixing block 160 from being separated from the screw 600.

Preferably, an anti-collision block may be disposed on both a side of the first stopper 700 facing the fixed block 160 and a side of the second stopper 800 facing the fixed block 160, and the anti-collision block may be elastically deformed, and when the first stopper 700 contacts the fixed block 160 or the second stopper 800 contacts the fixed block 160, the anti-collision block may play a certain buffering role, thereby preventing the first stopper 700, the second stopper 800, and the fixed block 160 from being damaged due to collision.

Other constructions and operations of the aging feeder 1 according to embodiments of the present invention are known to those of ordinary skill in the art and will not be described in detail herein.

In the description herein, references to the description of "a particular embodiment," "a particular example," etc., mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the utility model. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. While embodiments of the utility model have been shown and described, it will be understood by those of ordinary skill in the art that: various changes, modifications, substitutions and alterations can be made to the embodiments without departing from the principles and spirit of the utility model, the scope of which is defined by the claims and their equivalents.

Claims (10)

1. An aging feeding device, comprising:

a moving assembly movable between a sensing position and a feeding position;

the tray is suitable for placing a piece to be tested;

the detection line is suitable for being connected with the piece to be detected;

when the moving assembly is located at the detection position, the tray is spaced from the conveying device and arranged on the moving assembly, the detection line is connected with the piece to be detected, the moving assembly moves from the detection position to the feeding position, the detection line is separated from the piece to be detected, the tray gradually approaches the conveying device until the tray is in butt joint with the conveying device, and the conveying device drives the tray to move in the direction away from the moving assembly.

2. The aging feeding device as set forth in claim 1, wherein a side of the moving assembly facing the conveyor is provided with a row of support columns provided with a plurality of support columns, the conveyor includes a positioning plate and a plurality of rollers provided on a side of the positioning plate facing the moving assembly, each of the rollers being rotatable relative to the positioning plate, the plurality of rollers being alternately and alternately arranged with the plurality of support columns in an extending direction of the positioning plate;

when the moving assembly is located at the detection position, the tray is arranged on the support column row;

and in the process that the moving assembly moves from the detection position to the feeding position, the tray gradually approaches the plurality of rollers until the tray is contacted with the plurality of rollers, and the plurality of rollers drive the tray to move towards the direction far away from the moving assembly through rotation.

3. The retrogradation feed assembly of claim 2, wherein the side of the row of support posts facing the tray does not extend beyond the side of each roller facing the tray when the moving assembly is in the feed position.

4. The aging feeding device according to claim 2, wherein the number of the trays is plural, the number of the support column rows is plural, the support column rows are arranged at intervals along the moving direction of the moving assembly, and when the moving assembly is at the detection position, the plural trays are arranged in the plural support column rows in a one-to-one correspondence manner.

5. The aging feeder of claim 1, further comprising:

the wire drawing board is provided with an accommodating space which penetrates through the moving assembly along the moving direction of the moving assembly, the wire drawing board is arranged in the accommodating space, the moving assembly moves from the detection position to the feeding position, and the detection line is abutted to the wire drawing board to be separated from the piece to be detected.

6. The aging feeding device as claimed in claim 5, wherein the accommodating space has a first side wall, a second side wall, a third side wall and a fourth side wall which are connected end to end in sequence, the first side wall is far away from the conveying device and is provided with the detection line on the inner side, the third side wall is close to the conveying device and is provided with a line passing hole, and two opposite sides of the line pulling plate are slidably connected with the second side wall and the fourth side wall respectively;

when the movable assembly is located at the detection position, the tray is arranged on the outer side of the third side wall, the detection line penetrates through the line passing hole to be connected with the piece to be detected, and at least part of the line pulling plate is located between the detection line and the conveying device in the moving direction of the movable assembly.

7. The burn-in feeder of claim 6, wherein the pull-out plate comprises:

a first sliding section and a second sliding section, the first sliding section slidably connected with the second sidewall, the second sliding section slidably connected with the fourth sidewall;

the first connecting section and the second connecting section are arranged at intervals along the moving direction of the moving assembly, two ends of the first connecting section are respectively connected with one end of the first sliding section and one end of the second sliding section, and two ends of the second connecting section are respectively connected with the other end of the first sliding section and the other end of the second sliding section;

the abutting section is located between the first connecting section and the second connecting section in the moving direction of the moving assembly, and two ends of the abutting section are connected with the first sliding section and the second sliding section respectively;

wherein when the moving assembly is in the detecting position, the abutting section is located between the detecting line and the conveying device in the moving direction of the moving assembly;

and in the process that the moving assembly moves from the detection position to the feeding position, the detection line is abutted against the abutting section to be separated from the piece to be detected.

8. The retrogradation feed assembly of claim 5, wherein the movement assembly comprises:

the first moving plate is arranged on one side, facing the conveying device, of the wire drawing plate, first edges, facing the bent wire drawing plate, are arranged on two opposite sides of the first moving plate, each first edge forms a side wall of the accommodating space and is provided with a first sliding groove extending along the moving direction of the moving assembly, and a first sliding block matched with the first sliding groove is arranged on one side, facing the first moving plate, of the wire drawing plate;

the second movable plate is arranged on the back of the wire drawing plate, one side of the conveying device is limited by the first movable plate, the accommodating space is defined by the second movable plate, the two opposite sides of the second movable plate are provided with second edges bent towards the wire drawing plate, each second edge is formed on the side wall of the accommodating space, the side wall of the accommodating space is provided with a second sliding groove extending along the moving direction of the moving assembly, and one side of the second movable plate is provided with a second sliding block matched with the second sliding groove.

9. The aging feeder of claim 1, further comprising:

a fixed block is arranged on one side of the moving assembly, which is back to the conveying device, a threaded hole penetrating through the fixed block along the moving direction of the moving assembly is formed in the fixed block, and the screw penetrates through the threaded hole and is in threaded fit with the threaded hole;

the movable assembly is arranged at the detection position, the fixed block is abutted to the first stop block, and the movable assembly is arranged at the feeding position, the fixed block is abutted to the second stop block.

10. The retrogradation feeding device as claimed in any one of claims 1 to 9, wherein the moving assembly moves the tray in a vertical direction and the conveying device moves the tray in a horizontal direction.

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