CN219417686U - Aging equipment for battery detection - Google Patents

Abstract

The utility model discloses battery detection aging equipment, which comprises a bottom plate and a U-shaped hood, wherein a hollow frame is arranged on the surface of the U-shaped hood in a sliding manner, a telescopic driving unit for driving the hollow frame to lift is arranged on the back surface of the U-shaped hood, a positive electrode plug and a negative electrode plug are arranged on the surface of the hollow frame in a sliding manner through a sliding supporting structure, a rack bidirectional transfer structure for driving the positive electrode plug and the negative electrode plug to move in opposite directions is arranged on the surface of the hollow frame, and a DD motor is arranged on the inner wall of one side of the hollow frame. According to the utility model, the telescopic driving unit controls the positive electrode plug and the negative electrode plug to move downwards to contact with the positive electrode and the negative electrode of the storage battery, so that the measured voltage is displayed by the storage battery detector, the state of the battery is good or bad and the aging degree is reflected, batch and continuous measurement of the voltage of the storage battery is realized, the pin position of the detector is not required to be adjusted by a worker, and the detection efficiency of the aging degree of the battery is improved.

Description

Aging equipment for battery detection

Technical Field

The utility model relates to the technical field of battery detection, in particular to battery detection aging equipment.

Background

The detection of the capacity of the battery is also indispensable because the lead-acid storage battery is recovered, the detection is one of main items of battery aging detection, the anode and the cathode of the lead-acid storage battery are connected to a detector in the detection process, then the battery is placed on the ground or a working frame near equipment, and the detector is used for detecting various performances of the battery; the method is suitable for detecting a small amount of lead-acid storage batteries, is troublesome to operate for batch recovery of the obtained lead-acid storage battery workpieces of the same specification, requires workers to continuously put the workpieces, adjust the positions of positive and negative plugs and has relatively low detection efficiency.

Disclosure of Invention

The utility model aims to provide battery detection aging equipment which can quickly adjust the positions of positive and negative plugs according to the specification of a storage battery and complete detection work so as to solve the problems in the prior art.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the utility model provides a battery detects ageing equipment, includes bottom plate and U type aircraft bonnet, the surface sliding mounting of U type aircraft bonnet has the cavity frame, the back side-mounting of U type aircraft bonnet has the flexible drive unit that drives cavity frame and go up and down, the surface of cavity frame has anodal bayonet joint, negative pole bayonet joint through sliding support structure slidable mounting, the surface mounting of cavity frame has the rack two-way transfer structure that drives anodal bayonet joint, negative pole bayonet joint opposite movement, install DD motor on the inner wall of cavity frame one side, DD motor is used for driving rack two-way transfer structure work, battery detector is installed to the bottom of cavity frame, anodal bayonet joint, negative pole bayonet joint carry out electric connection through wiring and battery detector, install PLC control panel on the outer wall of U type aircraft bonnet one side, PLC control panel's output and DD motor, flexible drive unit's input electric connection.

Preferably, the telescopic driving unit is an electric push rod arranged on the back surface of the U-shaped hood, the top end of a piston rod of the electric push rod is fixedly connected with the back surface of the hollow frame, and a prefabricated groove for the hollow frame to slide is formed in the surface of the U-shaped hood.

Preferably, a rectangular hollowed-out part is arranged on the surface of the U-shaped hood below the prefabricated groove.

Preferably, the rack bidirectional transfer structure comprises a main shaft arranged at the output end of the DD motor, and a first rack and a second rack which are slidably arranged at two sides of the surface of the hollow frame through a sliding support structure, wherein the top end of the main shaft extends to the outside of the hollow frame and is provided with a gear, and the gear is meshed with the first rack and the second rack.

Preferably, the sliding support structure comprises guide rails arranged at two ends of the surface of the hollow frame, and sliding tables fixed on the back surfaces of the first rack and the second rack, and the sliding tables are in sliding connection with the guide rails.

Preferably, the hollow frame is made of a member made of stainless steel.

Compared with the prior art, the utility model has the beneficial effects that: this battery detects ageing equipment is through being provided with the structure of mutual cooperation such as anodal bayonet joint and cavity frame, battery work piece is placed on the bottom plate, by the position of DD motor, rack two-way transfer structure adjustment anodal bayonet joint, negative pole bayonet joint, and by flexible drive unit control anodal bayonet joint, negative pole bayonet joint descends and then contacts with the positive negative pole of battery, the battery detector shows the voltage that surveys, with this state that reflects the battery is good bad and ageing degree, realize batch, continuous measurement work that carries out battery voltage, need not the stitch position of staff constantly adjustment detector, promote battery ageing degree detection efficiency.

Drawings

FIG. 1 is a schematic diagram of a front view of the present utility model;

FIG. 2 is a schematic side view of the present utility model;

FIG. 3 is a schematic side view of a hollow frame of the present utility model;

FIG. 4 is an enlarged schematic view of the structure of FIG. 1A according to the present utility model;

in the figure: 1. a bottom plate; 2. a U-shaped hood; 201. rectangular hollowed-out parts; 202. prefabricating a groove; 3. a hollow frame; 301. a sliding support structure; 302. DD motor; 303. a main shaft; 304. a gear; 4. a battery detector; 5. a first rack; 6. a second rack; 7. a positive electrode plug; 8. a negative electrode plug; 9. wiring; 10. a PLC control panel; 11. an electric push rod.

Detailed Description

The technical solutions in the embodiments of the present utility model will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present utility model. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Referring to fig. 1-4, an embodiment of the present utility model is provided: the battery detection aging equipment comprises a bottom plate 1 and a U-shaped hood 2, wherein a hollow frame 3 is slidably arranged on the surface of the U-shaped hood 2, the hollow frame 3 is made of a stainless steel member, and a prefabricated groove 202 for sliding the hollow frame 3 is formed in the surface of the U-shaped hood 2;

the back of the U-shaped hood 2 is provided with a telescopic driving unit for driving the hollow frame 3 to lift, the surface of the hollow frame 3 is provided with a positive electrode plug-in connector 7 and a negative electrode plug-in connector 8 in a sliding manner through a sliding supporting structure 301, the sliding supporting structure 301 improves the moving stability of the positive electrode plug-in connector 7 and the negative electrode plug-in connector 8, the surface of the hollow frame 3 is provided with a rack bidirectional transfer structure for driving the positive electrode plug-in connector 7 and the negative electrode plug-in connector 8 to move in opposite directions, a recovered storage battery workpiece is placed on the bottom plate 1, and the positive electrode and the negative electrode of the storage battery are positioned below the positive electrode plug-in connector 7 and the negative electrode plug-in connector 8, and the rack bidirectional transfer structure adjusts the distance between the positive electrode plug-in connector 7 and the negative electrode plug-in connector 8;

the horizontal positions of the positive electrode plug-in connector 7 and the negative electrode plug-in connector 8 are adjusted according to the specification of the group of storage batteries, so that the positive electrode plug-in connector 7 and the negative electrode plug-in connector 8 can be contacted with the positive electrode and the negative electrode of the storage batteries when going down;

a DD motor 302 is arranged on the inner wall of one side of the hollow frame 3, the DD motor 302 is used for driving a rack bidirectional transfer structure to work, a storage battery detector 4 is arranged at the bottom end of the hollow frame 3, a positive electrode plug-in connector 7 and a negative electrode plug-in connector 8 are electrically connected with the storage battery detector 4 through a wiring 9, a PLC control panel 10 is arranged on the outer wall of one side of the U-shaped hood 2, the output end of the PLC control panel 10 is electrically connected with the DD motor 302 and the input end of a telescopic driving unit, the DD motor 302 is started to work through the PLC control panel 10, and then the DD motor 302 drives the positive electrode plug-in connector 7 and the negative electrode plug-in connector 8 to move in opposite directions through the rack bidirectional transfer structure until the positive electrode plug-in connector 7 and the negative electrode plug-in connector 8 are positioned on the same vertical line with the positive electrode and the negative electrode of the storage battery, so that a plurality of storage batteries with different batches and the same specification are used for ageing degree detection;

the telescopic driving unit is an electric push rod 11 arranged on the back surface of the U-shaped hood 2, the input end of the electric push rod 11 is electrically connected with the output end of the PLC control panel 10, and the top end of a piston rod of the electric push rod 11 is fixedly connected with the back surface of the hollow frame 3;

after the positions of the positive electrode plug-in connector 7 and the negative electrode plug-in connector 8 are adjusted, a worker controls the electric push rod 11 to work through the PLC control panel 10, the electric push rod 11 pulls the hollow frame 3, the storage battery detector 4, the positive electrode plug-in connector 7, the negative electrode plug-in connector 8 and other parts to move downwards together until the positive electrode plug-in connector 7 and the negative electrode plug-in connector 8 are contacted with the positive electrode and the negative electrode of the storage battery, and at the moment, the state of the battery is good or bad and the aging degree is reflected by observing the voltage on the storage battery detector 4;

a rectangular hollowed-out part 201 is arranged on the surface of the U-shaped hood 2 below the prefabricated groove 202;

the rack bidirectional transfer structure comprises a main shaft 303 arranged at the output end of a DD motor 302, a first rack 5 and a second rack 6 which are slidably arranged at two sides of the surface of a hollow frame 3 through a sliding support structure 301, wherein the top end of the main shaft 303 extends to the outside of the hollow frame 3 and is provided with a gear 304, the gear 304 is meshed with the first rack 5 and the second rack 6, and a positive electrode plug-in connector 7 and a negative electrode plug-in connector 8 are respectively arranged on the second rack 6 and the first rack 5;

the DD motor 302 drives the gear 304 and the main shaft 303 to rotate, so that the main shaft 303 drives the first rack 5 and the second rack 6 to be far away from or close to each other, and the spacing between the positive electrode plug-in connector 7 and the negative electrode plug-in connector 8 is adjusted, and therefore the storage batteries with different specifications and sizes are met for detection and use;

the sliding support structure 301 comprises guide rails arranged at two ends of the surface of the hollow frame 3, and sliding tables fixed on the back surfaces of the first rack 5 and the second rack 6, the sliding tables are in sliding connection with the guide rails, and the moving stability of the first rack 5 and the second rack 6 is improved through the guide rails and the sliding tables.

When the embodiment of the application is used, firstly, a worker places the recovered storage battery workpiece on the bottom plate 1, and the positive and negative poles of the storage battery are positioned below the positive electrode plug-in connector 7 and the negative electrode plug-in connector 8, then the staff adjusts the horizontal positions of the positive electrode plug-in connector 7 and the negative electrode plug-in connector 8 according to the specification of the storage battery, so that the positive electrode plug-in connector 7 and the negative electrode plug-in connector 8 can be contacted with the positive electrode and the negative electrode of the storage battery when going downwards, in the process, a worker starts the DD motor 302 to work through the PLC control panel 10, the DD motor 302 drives the positive electrode plug-in connector 7 and the negative electrode plug-in connector 8 to move in opposite directions through a rack bidirectional transfer structure until the positive electrode plug-in connector 7 and the negative electrode plug-in connector 8 are on the same vertical line with the positive electrode and the negative electrode of the storage battery, so that the ageing degree detection of a plurality of storage batteries with different batches and the same specification is realized, after the positions of the positive electrode plug-in connector 7 and the negative electrode plug-in connector 8 are adjusted, a worker controls the electric push rod 11 to work through the PLC control panel 10, the electric push rod 11 pulls the hollow frame 3, the storage battery detector 4, the positive electrode plug-in connector 7, the negative electrode plug-in connector 8 and other parts to move downwards together until the positive electrode plug-in connector 7 and the negative electrode plug-in connector 8 are contacted with the positive electrode and the negative electrode of the storage battery, at the moment, the state of the battery is good or bad and the aging degree is reflected by observing the voltage on the storage battery detector 4, after the detection of the battery is completed, the battery is withdrawn from the rectangular hollowed-out part 201, then the next battery to be detected is placed on the bottom plate 1, and the operation is repeated, and further, batch and continuous measurement of the voltage of the storage batteries is realized, no staff is required to continuously adjust the pin positions of the detector, and the detection efficiency of the aging degree of the batteries is improved.

Claims (6)

1. A battery detection aging device, characterized in that: including bottom plate (1) and U type aircraft bonnet (2), the surface sliding mounting of U type aircraft bonnet (2) has cavity frame (3), the back side-mounting of U type aircraft bonnet (2) has the flexible drive unit that drives cavity frame (3) and go up and down, the surface of cavity frame (3) has anodal bayonet joint (7), negative pole bayonet joint (8) through sliding support structure (301) slidable mounting, the surface mounting of cavity frame (3) has the rack two-way transfer structure that drives anodal bayonet joint (7), negative pole bayonet joint (8) opposite movement, install DD motor (302) on the inner wall of cavity frame (3) one side, DD motor (302) are used for driving rack two-way transfer structure work, battery detector (4) are installed to the bottom of cavity frame (3), anodal bayonet joint (7), negative pole bayonet joint (8) carry out electric connection through wiring (9) and battery detector (4), install PLC control panel (10) on the outer wall of U type aircraft bonnet (2) one side, the output of PLC control panel (10) and the input electric drive unit's of DD motor electric connection.

2. The battery test aging apparatus according to claim 1, wherein: the telescopic driving unit is an electric push rod (11) arranged on the back of the U-shaped hood (2), the top end of a piston rod of the electric push rod (11) is fixedly connected with the back of the hollow frame (3), and a prefabricated groove (202) for the hollow frame (3) to slide is formed in the surface of the U-shaped hood (2).

3. A battery test aging apparatus according to claim 2, wherein: a rectangular hollowed-out part (201) is arranged on the surface of the U-shaped hood (2) below the prefabricated groove (202).

4. The battery test aging apparatus according to claim 1, wherein: the rack bidirectional transfer structure comprises a main shaft (303) arranged at the output end of a DD motor (302), and a first rack (5) and a second rack (6) which are slidably arranged on two sides of the surface of a hollow frame (3) through a sliding support structure (301), wherein the top end of the main shaft (303) extends to the outside of the hollow frame (3) and is provided with a gear (304), and the gear (304) is meshed with the first rack (5) and the second rack (6).

5. The battery test aging apparatus according to claim 4, wherein: the sliding support structure (301) comprises guide rails arranged at two ends of the surface of the hollow frame (3), and sliding tables fixed on the back surfaces of the first rack (5) and the second rack (6), and the sliding tables are in sliding connection with the guide rails.

6. The battery test aging apparatus according to claim 1, wherein: the hollow frame (3) is made of a member made of stainless steel.