CN218282713U - Lithium battery batch test assembly line - Google Patents

Abstract

The utility model discloses a lithium cell tests assembly line in batches, including feeding track, ejection of compact track and detection track, feeding track and ejection of compact track parallel arrangement, a set of detection track of fixedly connected with between feeding track and the ejection of compact track detects track upper end fixedly connected with test rack, test rack outside fixedly connected with battery internal resistance detector, sliding connection has a lifter plate in the test rack, a pair of test probe of lifter plate lower extreme fixedly connected with, test probe pass through the connection of electric lines with battery internal resistance detector, the beneficial effects of the utility model are that: divide into ejection of compact track and the orbital combination of feeding with the test assembly line to connect through a plurality of detection tracks, the water conservancy diversion pole water conservancy diversion through water conservancy diversion mechanism can make the lithium cell get into different detection tracks in proper order, thereby need not to wait for the material loading that just can carry out next lithium cell after the previous lithium cell detects and detect, the effectual efficiency that improves the battery and test in batches.

Description

Lithium battery batch test assembly line

Technical Field

The utility model relates to a lithium cell test technical field specifically is a lithium cell tests assembly line in batches.

Background

The lithium battery detection assembly line is used for placing the lithium battery on a special production track for transmission, after the battery flows to a specified position, the lithium battery can be located in a detection box or a detection frame through a positioning sensor, battery quality detection is carried out through a battery internal resistance detector and various battery detectors, during detection, a metal end of the lithium battery is abutted against a detection probe, and detection of the battery internal resistance or other detection standard vertebrae is achieved.

The existing test assembly line is characterized in that lithium batteries are placed on a special guide rail to be conveyed, and the lithium batteries sequentially enter a detection box or a detection frame to be detected, and the detection efficiency is reduced due to the fact that no shunting structure exists, so that the lithium batteries are not suitable for batch detection.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a lithium cell tests assembly line in batches to solve the problem that proposes in the above-mentioned background art.

In order to achieve the above object, the utility model provides a following technical scheme: the utility model provides a lithium cell tests assembly line in batches, includes feeding track, ejection of compact track and detection track, feeding track and ejection of compact track parallel arrangement, a set of detection track of fixedly connected with between feeding track and the ejection of compact track, detect track upper end fixedly connected with test stand, test stand outside fixedly connected with battery internal resistance detector, sliding connection has a lifter plate in the test stand, a pair of detection probe of lifter plate lower extreme fixedly connected with, detection probe passes through electric wire connection with battery internal resistance detector, ejection of compact track upper end just is located and is provided with water conservancy diversion mechanism between feeding track and the test stand.

Preferably, the water conservancy diversion mechanism includes the guide rod, guide rod sliding connection is close to feeding track one side in ejection of compact track upper end, the guide rod is close to feeding track one end and is located the feeding track, the guide rod is kept away from between feeding track one end and the lifter plate and is rotated and be connected with the connection bull stick.

Preferably, the middle position of the lower end of the guide rod is fixedly connected with a limiting sliding block, a limiting sliding groove is formed in the upper end of the detection track and corresponds to the limiting sliding block, and the limiting sliding block is connected in the limiting sliding groove in a sliding mode, so that the sliding stability of the guide rod on the upper end of the detection track is guaranteed.

Preferably, the upper end of the connecting rotating rod is rotatably connected with one side, close to the feeding track, of the lower end of the lifting plate, the straight line distance between the upper end of the connecting rotating rod and the feeding track is smaller than the straight line distance between the lower end of the connecting rotating rod and the feeding track, and the lifting plate is guaranteed to move downwards so that the guide rod can be pushed to be drawn out of the feeding track.

Preferably, the detection track is located between the feeding track and the discharging track, so that the lithium battery can better enter the detection track from the feeding track.

Preferably, the upper end of the lifting plate is fixedly connected with an electric telescopic cylinder, the upper end of the electric telescopic cylinder is fixedly connected to the upper end of the detection frame, and output power can be provided for lifting of the lifting plate.

Compared with the prior art, the beneficial effects of the utility model are that: divide into ejection of compact track and the orbital combination of feeding with the test assembly line to connect through a plurality of detection tracks, the water conservancy diversion pole water conservancy diversion through water conservancy diversion mechanism can make the lithium cell get into different detection tracks in proper order, thereby need not to wait for the material loading that just can carry out next lithium cell after the previous lithium cell detected and detect, the effectual efficiency that improves the battery and test in batches.

Drawings

Fig. 1 is a schematic view of the top-view appearance structure of the present invention;

FIG. 2 is a schematic view of the internal side structure of the inspection frame of the present invention;

FIG. 3 is a schematic view of the connection structure of the diversion pole and the connection rotating pole of the present invention;

fig. 4 is a schematic view of the internal front structure of the inspection rack of the present invention.

In the figure: 1. a feed rail; 2. a discharge rail; 3. detecting a track; 4. a detection frame; 5. a battery internal resistance detector; 6. a lifting plate; 7. an electric telescopic cylinder; 8. detecting the probe; 9. a flow guide mechanism; 91. a guide rod; 92. connecting the rotating rod; 93. a limiting slide block; 94. and a limiting sliding groove.

Detailed Description

The technical solution in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention.

Referring to fig. 1-4, the present invention provides a technical solution: the utility model provides a lithium cell batch test assembly line, including feeding track 1, ejection of compact track 2 and detection track 3, feeding track 1 and ejection of compact track 2 parallel arrangement, a set of detection track 3 of fixedly connected with between feeding track 1 and the ejection of compact track 2, detect 3 upper ends fixedly connected with detection frame 4 of track, detection frame 4 outside fixedly connected with battery internal resistance detector 5, sliding connection has a lifter plate 6 in detection frame 4, a pair of detection probe 8 of 6 lower extreme fixedly connected with of lifter plate, detection probe 8 passes through the connection of electric lines with battery internal resistance detector 5, ejection of compact track 2 upper end just is located and is provided with water conservancy diversion mechanism 9 between feeding track 1 and the detection frame 4, detection track 3 is located between feeding track 1 and the ejection of compact track 2, 6 upper end fixedly connected with electronic telescoping cylinder 7 of lifter plate, 7 upper ends fixed connection of electronic telescoping cylinder is in detection frame 4 upper ends.

Diversion mechanism 9 includes water conservancy diversion pole 91, water conservancy diversion pole 91 sliding connection is close to feeding track 1 one side in ejection of compact track 2 upper end, water conservancy diversion pole 91 is close to feeding track 1 one end and is located feeding track 1, water conservancy diversion pole 91 is kept away from between feeding track 1 one end and the lifter plate 6 and is rotated and be connected with and connect bull stick 92, water conservancy diversion pole 91 lower extreme intermediate position fixedly connected with limit slide 93, detect track 3 upper end and the position corresponding to limit slide 93 has been seted up, limit slide 93 sliding connection is in limit slide 94, connect bull stick 92 upper end and lifter plate 6 lower extreme and be close to feeding track 1 one side and rotate and be connected, the sharp distance between connecting bull stick 92 upper end and feeding track 1 is far less than the linear distance between connecting bull stick 92 lower extreme and feeding track 1, when lifter plate 6 moves down and carries out lithium cell detection, connect bull stick 92 and rotate with the extrusion, thereby make connecting bull stick 92 lower extreme promote water conservancy diversion pole 91 and keep away from feeding track 1 one side to slide mutually, finally make water conservancy diversion pole 91 be located feeding track 1 one end and take out from feeding track 1 interior lithium cell detection of detection, thereby lose to the lithium cell in feeding track 1.

Specifically, use the utility model discloses the time, at first put into feeding track 1 with the lithium cell in proper order, when the detection track 3 through the front end, through the hindrance of guiding rod 91 to lithium cell direction of advance, can make the lithium cell automatic enter into in the detection track 3, finally enter into in the test stand 4, drive lifter plate 6 downstream through 7 outputs of electric telescopic cylinder, make the metal end of detecting probe 8 and lithium cell offset, begin to detect the battery, here in-process, lifter plate 6 downstream, will extrude to connect the bull stick 92 and rotate, thereby make and connect the lower extreme of bull stick 92 to promote the guiding rod 91 and keep away from feeding track 1 one side mutually and slide, finally make the bull stick 91 be located feeding track 1 one end and take out from feeding track 1, thereby lose the blockking to the lithium cell in feeding track 1, make the lithium cell can flow into next detection track 3 and detect, need not to wait for the detection of previous lithium cell and just can carry out the detection of next lithium cell after, lithium cell detection efficiency in batches has been improved.

Claims (6)

1. The utility model provides a lithium cell batch test assembly line, its characterized in that, includes feeding track (1), ejection of compact track (2) and detection track (3), feeding track (1) and ejection of compact track (2) parallel arrangement, a set of detection track (3) of fixedly connected with between feeding track (1) and ejection of compact track (2), detection track (3) upper end fixedly connected with detection frame (4), detection frame (4) outside fixedly connected with battery internal resistance detector (5), sliding connection has a lifter plate (6) in detection frame (4), a pair of test probe (8) of lifter plate (6) lower extreme fixedly connected with, test probe (8) pass through the connection of electric lines with battery internal resistance detector (5), ejection of compact track (2) upper end just is located and is provided with water conservancy diversion mechanism (9) between feeding track (1) and detection frame (4).

2. The batch test production line for lithium batteries according to claim 1, characterized in that: the water conservancy diversion mechanism (9) includes water conservancy diversion pole (91), water conservancy diversion pole (91) sliding connection is close to feeding track (1) one side in ejection of compact track (2) upper end, water conservancy diversion pole (91) are close to feeding track (1) one end and are located feeding track (1), water conservancy diversion pole (91) are kept away from and are rotated between feeding track (1) one end and lifter plate (6) and be connected with and connect bull stick (92).

3. The batch test production line for lithium batteries according to claim 2, characterized in that: the guide rod (91) lower extreme intermediate position fixedly connected with spacing slider (93), detection track (3) upper end and with spacing slider (93) corresponding position seted up spacing spout (94), spacing slider (93) sliding connection is in spacing spout (94).

4. The batch test production line for lithium batteries according to claim 2, characterized in that: the upper end of the connecting rotating rod (92) is rotatably connected with one side, close to the feeding track (1), of the lower end of the lifting plate (6), and the straight line distance between the upper end of the connecting rotating rod (92) and the feeding track (1) is smaller than the straight line distance between the lower end of the connecting rotating rod (92) and the feeding track (1).

5. The batch test production line for lithium batteries according to claim 1, characterized in that: the detection track (3) is positioned between the feeding track (1) and the discharging track (2).

6. The batch test production line for lithium batteries according to claim 1, characterized in that: the upper end of the lifting plate (6) is fixedly connected with an electric telescopic cylinder (7), and the upper end of the electric telescopic cylinder (7) is fixedly connected to the upper end of the detection frame (4).

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