CN116643185A - Power-on detection device for storage battery and detection method thereof - Google Patents

Abstract

The application belongs to the technical field of storage battery production, and particularly relates to an electrified detection device for a storage battery and a detection method thereof. Still include locating plate and detection mechanism, the inside fixture that is equipped with of locating plate, first braced frame and the inboard equal fixed mounting of second braced frame have belt conveyor. The other side of second backup pad be provided with control panel, translation mechanism, fixture and detection mechanism all with control panel electric connection, the device divide twice to the circular telegram of battery normal and whether electric leakage detects, screens out qualified battery to classify to the quality problem that it exists, the detection method that uses the device reduces staff's work load, has improved work efficiency greatly.

Description

Power-on detection device for storage battery and detection method thereof

Technical Field

The application belongs to the technical field of storage battery production, and particularly relates to a power-on detection device for a storage battery and a detection method thereof.

Background

The device for converting chemical energy into electric energy is called a chemical battery, generally called a battery for short, after discharging, an internal active substance can be regenerated in a charging mode, electric energy is stored as chemical energy, the chemical energy is converted into electric energy again when discharging is needed, the battery is called a storage battery, also called a secondary battery or a lead-acid storage battery jar, the storage battery is an electrochemical device for storing the chemical energy and discharging the electric energy when necessary, in order to ensure the production quality of the storage battery, after the storage battery is manufactured, the storage battery is electrified for detection, and the electrification detection also comprises discharge detection and electric leakage detection.

The battery shell outside has two structures of positive pole and negative pole, and during the test, the battery removes along the conveyer belt direction on the conveyer belt, when waiting to remove to detect the position, needs press from both sides the electric splint clamp and establishes respectively at two junctions of positive pole and negative pole of battery in order to detect. For small batch tests, and for small manufacturers, the number of production is small, and for cost saving, the power-on clamping plate is usually clamped to the storage battery manually. For some large-scale manufacturers, particularly for large-scale delivery detection, a conveying belt is generally adopted to convey the storage battery, and an automatic robot is utilized to operate the clamping electrode of the electrified clamping plate when the storage battery is conveyed to a detection position. However, the automated robot in the prior art has higher manual operation efficiency, but has a complicated control system and higher equipment cost, and thus has a heavy burden on small manufacturers. And because the equipment structure is complicated, the maintenance difficulty is higher, and the equipment is not suitable for large-scale popularization and use. In addition, most production is carried out one by one through the cooperation of the worker through the electric connection ring and the indicator lamp, and after the detection of the storage batteries is finished, the storage batteries are also classified and placed according to normal electrification, abnormal electrification, leakage and the like, and the storage batteries are all required to be finished manually, so that the working efficiency is low.

The application patent with the publication number of 114895138A discloses power-on detection equipment for a storage battery, and belongs to the field of storage battery production. The device comprises: the support plate is provided with two sliding grooves, guide grooves are formed in the sliding grooves, and the guide grooves are obliquely arranged; the sliding rod is slidably arranged in the sliding groove, a guide rod is arranged on the sliding rod, the guide rod is slidably arranged in the guide groove, and a conductive plate for connecting electrodes of the storage battery is arranged on the sliding rod; and the driving device is arranged on the supporting plate and used for driving the sliding rod to reciprocate along the extending direction of the sliding groove. According to the application, the sliding rod drives the wire guide plate to move along the horizontal direction and synchronously moves along the vertical direction through the driving device, so that the sliding rod does not influence the movement of the storage battery in the horizontal direction when the storage battery is not detected.

Disclosure of Invention

The application aims to provide a power-on detection device for a storage battery and a detection method thereof, aiming at the problems in the prior art, the device detects whether the power-on of the storage battery is normal or not and whether the electric leakage is caused or not in two times, screens out qualified storage batteries, classifies the quality problems of the storage batteries, reduces the workload of staff by using the detection method of the device, and greatly improves the working efficiency.

The technical scheme of the application is as follows:

the utility model provides a circular telegram detection device for battery, includes parallel arrangement 'U' type first braced frame and 'U' type second braced frame, the tip fixedly connected with of the same end of first braced frame and second braced frame rather than the second backup pad that sets up perpendicularly, one side fixedly connected with that the second backup pad is close to first braced frame and second braced frame rather than the second roof that sets up perpendicularly, the second roof is located first braced frame and second braced frame top, second roof bottom sliding connection has the translation board, the inside translation mechanism that uses with the translation board cooperation and the power piece that is connected with the translation mechanism that is equipped with of second roof.

The positioning plate is arranged below the second top plate, two symmetrical cylinders are fixedly arranged on the lower surface of the translation plate, and the output ends of the two cylinders are fixedly connected with the positioning plate.

The locating plate lower surface sliding connection has two mounting panels that the symmetry set up, the locating plate is inside to be equipped with the fixture that uses with two mounting panels cooperation, mounting panel bottom fixedly connected with grip block.

The belt conveying mechanism is fixedly mounted on the inner sides of the first supporting frame and the second supporting frame, the detection mechanism supporting pieces for fixedly supporting the detection mechanism are respectively arranged on the first supporting frame and the second supporting frame, and the detection mechanism for detecting the electrification of the storage battery is arranged below the detection mechanism supporting pieces.

The other side of the second supporting plate is provided with a control panel, and the translation mechanism, the clamping mechanism and the detection mechanism are electrically connected with the control panel.

Specifically, the power piece includes the second motor, second motor fixed mounting is in second roof outside surface, translation mechanism include with second motor output fixed connection's threaded rod, threaded rod and second roof inner wall rotate to be connected, the threaded rod outer loop is equipped with interior thread plate, interior thread plate lower surface passes through connecting plate and translation board fixed connection, second motor and control panel electric connection.

Specifically, fixture includes the third motor, third motor fixed mounting is inside the locating plate, third motor output fixedly connected with second bidirectional screw, second bidirectional screw rotates with the locating plate inner wall to be connected, the ring is equipped with two second internal thread sleeves on the second bidirectional screw, two second internal thread sleeves respectively through connecting block and corresponding mounting panel fixed connection, third motor and control panel electric connection.

Specifically, detection mechanism support piece include two first backup pads that are located same horizontal line with first braced frame and second braced frame respectively, first backup pad fixed set up in first braced frame and second braced frame outside one side top, two first backup pad top fixedly connected with respectively rather than vertically horizontal first roof, two first roof below be equipped with the pick-up plate respectively, two respectively fixed mounting have two electric telescopic handle that the symmetry set up on the first roof, two electric telescopic handle output all fixed mounting is in the pick-up plate top, every install two tact switches that the symmetry set up on the pick-up plate lower surface, fixed mounting has the pilot lamp on the first roof, the inside symmetry of pick-up plate be equipped with the detection mechanism that uses with tact switch and pilot lamp cooperation, electric telescopic handle, tact switch, pilot lamp respectively with control panel electric connection.

Specifically, every detection mechanism all includes two first motors and four conducting rings, two first motor fixed mounting is in the inside both ends of pick-up plate, every the equal fixedly connected with of first motor output is first two-way lead screw, every first two-way lead screw rotates with the pick-up plate inner wall respectively and is connected, every annular respectively is equipped with two first internal thread sleeves on the first two-way lead screw, two first internal thread sleeves correspond and fixed connection with a conducting ring respectively, two the conducting ring is located one that corresponds and dabs the switch both sides and be symmetrical setting, two conducting ring all with pick-up plate bottom sliding connection, conducting ring and pilot lamp electric connection.

Specifically, stations are fixedly arranged at two ends of the first supporting frame and two ends of the second supporting frame.

A detection method using the above-described power-on detection device for a storage battery, comprising the steps of:

s1: a worker stands on a station at the first supporting frame, places a storage battery above a corresponding belt conveyor from the front end of the first supporting frame, and adjusts the storage battery to be detected to a discharging state until the storage battery moves to the position below a detection plate below the first supporting frame along with the belt conveyor, and then closes the belt conveyor at the top of the first supporting frame;

s2: starting an electric telescopic rod at the first supporting frame until the storage battery touches a tact switch below a detection plate below the first supporting frame, closing the electric telescopic rod, starting two first motors of the detection plate below one supporting frame until two conducting rings are respectively contacted with the positive electrode and the negative electrode of the storage battery, and observing whether the indicator lamp works normally;

s3: the worker above the station at the tail end of the first supporting frame takes down the storage battery which indicates that the lamp does not work normally in the step S2, namely the storage battery with power-on fault;

s4: for the storage battery with the lamp indicated to work normally in the step S2, firstly starting an air cylinder until two clamping plates are arranged on two sides of the storage battery, then starting a third motor until the two clamping plates clamp the storage battery, then starting the two clamping plates to drive the storage battery to move upwards, finally starting a second motor and matching with the two clamping plates, and placing the storage battery on a belt conveyor on the inner side of a second supporting frame;

s5: the staff on the side surface of the second supporting frame adjusts the storage battery from a discharging state to a closing state, and after the storage battery moves to the position below the detection plate at the second supporting frame along with the belt conveyor, the belt conveyor at the top of the second supporting frame is closed and the storage battery to be detected is detected;

s6: starting an electric telescopic rod at the second supporting frame until the storage battery touches a tact switch below a detection plate below the second supporting frame, closing the electric telescopic rod, starting two first motors of the detection plate below the second supporting frame until two conducting rings are respectively contacted with the positive electrode and the negative electrode of the storage battery, and observing whether the side indicator lamp works normally or not;

s7, a worker observes the working state of the indicator lamp corresponding to the second detection plate to divide the storage battery into two types of electricity leakage and qualification.

The beneficial effects achieved by the application are as follows: the automatic conveying device is compact in structure, automatic conveying of the storage battery is realized through the two belt conveyors, two independent production lines are formed, the detection mechanism is arranged at the terminal of the automatic conveying device, normal power on and electric leakage of the storage battery are detected twice, qualified storage batteries are screened out, quality problems of the storage batteries are classified, the translation mechanism and the clamping mechanism are added, automatic transfer from the first support frame to the second support frame is realized, workload of workers is reduced, and working efficiency is greatly improved.

Drawings

FIG. 1 is a schematic top view of the present application;

FIG. 2 is a schematic elevational view of the present application;

FIG. 3 is a schematic diagram of the detection mechanism of the present application;

FIG. 4 is a schematic view of a translation mechanism of the present application;

fig. 5 is a schematic view of the clamping mechanism of the present application.

1. A first support frame; 2. a second support frame; 3. a detection mechanism; 31. a first motor; 32. a first bidirectional screw rod; 33. a first female threaded sleeve; 34. a conductive ring; 4. a translation mechanism; 41. a second motor; 42. a threaded rod; 43. an inner thread plate; 44. a connecting plate; 5. a clamping mechanism; 51. a third motor; 52. a second bidirectional screw rod; 53. a second female threaded sleeve; 54. a connecting block; 6. a belt conveying mechanism; 7. a first support plate; 8. a first top plate; 9. a detection plate; 10. an electric telescopic rod; 11. a second support plate; 12. a second top plate; 13. a translation plate; 14. a cylinder; 15. a positioning plate; 16. a mounting plate; 17. a clamping plate; 18. a control panel; 19. touching the switch; 20. an indicator light; 21. and (5) a station.

Detailed Description

The technical scheme of the application is described in detail below with reference to the accompanying drawings and the specific embodiments.

Example 1

Fig. 1 is a schematic top view structure diagram of an energizing detection device for a storage battery provided in this embodiment, fig. 2 is a schematic front view structure diagram of fig. 1, including a first "U" type supporting frame 1 and a second "U" type supporting frame 2 that are arranged in parallel, the end portion of the same end of the first supporting frame 1 and the second supporting frame 2 is fixedly connected with a second supporting plate 11 that is arranged perpendicular to the first supporting frame 1 and the second supporting frame 2, one side of the second supporting plate 11, which is close to the first supporting frame 1 and the second supporting frame 2, is fixedly connected with a second top plate 12 that is arranged perpendicular to the second supporting plate, the second top plate 12 is located above the first supporting frame 1 and the second supporting frame 2, a translation plate 13 is slidingly connected to the bottom of the second top plate 12, and a translation mechanism 4 that is used in cooperation with the translation plate 13 and a power piece that is connected with the translation mechanism are arranged inside the second top plate 12. The power piece comprises a second motor 41, the second motor 41 is fixedly arranged on the outer side surface of the second top plate 12, and stations 21 are fixedly arranged at two ends of the first supporting frame 1 and two ends of the second supporting frame 2.

A positioning plate 15 is arranged below the second top plate 12, two symmetrical cylinders 14 are fixedly arranged on the lower surface of the translation plate 13, and the output ends of the two cylinders 14 are fixedly connected with the positioning plate 15.

The lower surface sliding connection of locating plate 15 has two mounting panels 16 that the symmetry set up, the inside fixture 5 that is equipped with and uses with two mounting panels 16 of locating plate 15, mounting panel 16 bottom fixedly connected with grip block 17.

The belt conveyor comprises a first supporting frame 1 and a second supporting frame 2, wherein belt conveyor 6 is fixedly arranged on the inner sides of the first supporting frame 1 and the second supporting frame 2, detection mechanism supporting pieces for fixedly supporting detection mechanisms are respectively arranged on the first supporting frame 1 and the second supporting frame 2, and detection mechanisms 3 for carrying out power-on detection on storage batteries are arranged below the detection mechanism supporting pieces.

The other side of the second supporting plate 11 is provided with a control panel 18, the translation mechanism 4, the clamping mechanism 5 and the detection mechanism 3 are electrically connected with the control panel 18, and integrated control of the device is realized through the control panel 18, so that the operation of staff is facilitated.

When the application is used, a worker loads the storage battery from the front end of the first supporting frame 1, and when the storage battery passes through the first detection plate 9, the detection mechanism 3 is matched with the indicator lamp 20 to detect the electrifying of the storage battery, and meanwhile, the worker at the tail end carries out targeted discharging on the storage battery to finish the detection of the electrifying state and the electric leakage state of the storage battery.

Example 2

The difference from the embodiment is that the specific structure of the translation mechanism 4 provided by the application is shown in fig. 4, the translation mechanism 4 comprises a threaded rod 42 fixedly connected with the output end of the second motor 41, the threaded rod 42 is rotatably connected with the inner wall of the second top plate 12, an inner thread plate 43 is arranged on the outer ring of the threaded rod 42, the lower surface of the inner thread plate 43 is fixedly connected with the translation plate 13 through a connecting plate 44, and the second motor 41 is electrically connected with the control panel 18. When the storage battery transfer device works, the second motor 41 is started to drive the threaded rod 42 to rotate, the threaded rod 42 drives the inner threaded plate 43 to move, the inner threaded plate 43 drives the translation plate 13 to move through the connecting plate 44, and then the translation plate is matched with the air cylinder 14 to finish the storage battery transfer from the first support frame 1 to the second support frame 2.

Example 3

The difference from the embodiment is that, as shown in fig. 5, the structure of the clamping mechanism provided by the application is that the clamping mechanism 5 comprises a third motor 51, the third motor 51 is fixedly installed inside the positioning plate 15, the output end of the third motor 51 is fixedly connected with a second bidirectional screw rod 52, the second bidirectional screw rod 52 is rotatably connected with the inner wall of the positioning plate 15, two second internal thread sleeves 53 are annularly arranged on the second bidirectional screw rod 52, the two second internal thread sleeves 53 are respectively fixedly connected with the corresponding mounting plate 16 through connecting blocks 54, and the third motor 51 is electrically connected with the control panel 18. When the electric accumulator is in operation, the third motor 51 is started to drive the second bidirectional screw rod 52 to rotate, the second bidirectional screw rod 52 drives the second internal thread sleeve 53 to move, the second internal thread sleeve 53 drives the mounting plate 16 to move through the connecting block 54, the mounting plate 16 drives the corresponding clamping plate 17 to move, the accumulator is clamped, and the accumulator is convenient to move.

Example 4

The application provides a specific structure of a detection mechanism support, which comprises two first support plates 7 which are respectively positioned on the same horizontal line with a first support frame 1 and a second support frame 2, wherein the first support plates 7 are fixedly arranged above one side of the first support frame 1 and one side of the second support frame 2, which are outside, a horizontal first top plate 8 which is vertical to the first support plates 7 is respectively and fixedly connected above the first support plates 7, detection plates 9 are respectively arranged below the first top plates 8, two electric telescopic rods 10 which are symmetrically arranged are respectively and fixedly arranged on the first top plates 8, the output ends of the two electric telescopic rods 10 are fixedly arranged above the detection plates 9, two tact switches 19 which are symmetrically arranged are arranged on the lower surface of each detection plate 9, an indicator lamp 20 is fixedly arranged on the first top plates 8, detection mechanisms 3 which are matched with the tact switches 19 and the indicator lamps 20 are symmetrically arranged inside the first support plates 8, and the electric telescopic rods 10, the tact switches 19 and the control panels 20 are respectively and electrically connected with the control panels 18.

Example 5

The difference from the embodiment is that the application provides a specific structure of the detection mechanism, as shown in fig. 3, each detection mechanism 3 includes two first motors 31 and four conductive rings 34, the two first motors 31 are fixedly installed at two ends inside the detection plate 9, the output end of each first motor 31 is fixedly connected with a first bidirectional screw rod 32, each first bidirectional screw rod 32 is respectively rotatably connected with the inner wall of the detection plate 9, each first bidirectional screw rod 32 is respectively provided with two first internal thread sleeves 33 in a ring mode, the two first internal thread sleeves 33 are respectively corresponding to and fixedly connected with one conductive ring 34, the two conductive rings 34 are symmetrically arranged at two sides of the corresponding one tact switch 19, the two conductive rings 34 are respectively slidably connected with the bottom of the detection plate 9, and the conductive rings 34 are electrically connected with the indicator lamp 20. When the storage battery is in operation, after the storage battery contacts 19, the first motor 31 is started to drive the first bidirectional screw rod 32 to rotate, the first bidirectional screw rod 32 drives the first internal thread sleeve 33 to move, and the first internal thread sleeve 33 drives the corresponding conductive ring 34 to move, so that the positive electrode and the negative electrode of the storage battery are clamped, and an electric path is formed between the storage battery and the indicator lamp 20.

Example 6

The present embodiment provides a detection method using the power-on detection device for a storage battery, including the steps of:

s1: a worker stands on a station 21 at the first supporting frame 1, places a storage battery above a corresponding belt conveyor 6 from the front end of the first supporting frame 1, and adjusts the storage battery to be detected to a discharging state until the storage battery moves to the position below a detection plate 9 below the first supporting frame 1 along with the belt conveyor 6, and then closes the belt conveyor 6 at the top of the first supporting frame 1;

s2: starting the electric telescopic rod 10 at the first supporting frame 1 until the storage battery touches the tact switch 19 below the detection plate 9 below the first supporting frame 1, closing the electric telescopic rod 10, starting the two first motors 31 of the detection plate 9 below one supporting frame 1 until the two conducting rings 34 are respectively contacted with the positive electrode and the negative electrode of the storage battery, and observing whether the indicator lamp 20 works normally;

s3: the worker above the end station 21 of the first support frame 1 takes down the storage battery which does not normally work in the indicator lamp 20 in the step S2, namely the storage battery with the power-on fault;

s4: for the storage battery which indicates the lamp 20 to work normally in the step S2, firstly starting the cylinder 14 until the two clamping plates 17 are arranged on two sides of the storage battery, then starting the third motor 51 until the two clamping plates 17 clamp the storage battery, then starting the two clamping plates 17 to drive the storage battery to move upwards, finally starting the second motor 41 and matching with the two clamping plates 17, and placing the storage battery on the belt conveyor 6 on the inner side of the second supporting frame 2;

s5: the staff on the side surface of the second supporting frame 2 adjusts the storage battery from a discharging state to a closing state, and after the storage battery moves to the position below the detection plate 9 at the second supporting frame 2 along with the belt conveyor 6, the belt conveyor 6 at the top of the second supporting frame 2 is closed and the storage battery to be detected is detected;

s6: starting the electric telescopic rod 10 at the second support frame 2 until the storage battery touches the tact switch 19 below the detection plate 9 below the second support frame 2, closing the electric telescopic rod 10, starting the two first motors 31 of the detection plate 9 below the second support frame 2 until the two conducting rings 34 are respectively contacted with the positive electrode and the negative electrode of the storage battery, and observing whether the side indicator lamp 20 works normally;

s7, a worker classifies the storage battery into two types of electricity leakage and qualification through observing the working state of the indicator lamp 20 corresponding to the second detection plate 9.

Finally, it should be noted that the above-mentioned embodiments are only for illustrating the technical scheme of the present application and are not limiting; while the application has been described in detail with reference to the preferred embodiments, those skilled in the art will appreciate that: modifications may be made to the specific embodiments of the present application or equivalents may be substituted for part of the technical features thereof; without departing from the spirit of the application, it is intended to cover the scope of the application as claimed.

Claims (7)

1. An energizing detection device for a storage battery comprises a U-shaped first supporting frame (1) and a U-shaped second supporting frame (2) which are arranged in parallel, and is characterized in that,

the end parts of the same ends of the first supporting frame (1) and the second supporting frame (2) are fixedly connected with a second supporting plate (11) which is vertically arranged with the second supporting plate, one side of the second supporting plate (11) close to the first supporting frame (1) and the second supporting frame (2) is fixedly connected with a second top plate (12) which is vertically arranged with the second supporting frame, the second top plate (12) is positioned above the first supporting frame (1) and the second supporting frame (2), the bottom of the second top plate (12) is slidably connected with a translation plate (13), a translation mechanism (4) which is matched with the translation plate (13) for use and a power piece which is connected with the translation mechanism are arranged inside the second top plate (12),

a positioning plate (15) is arranged below the second top plate (12), two symmetrical cylinders (14) are fixedly arranged on the lower surface of the translation plate (13), and the output ends of the two cylinders (14) are fixedly connected with the positioning plate (15);

the lower surface of the positioning plate (15) is connected with two symmetrically arranged mounting plates (16) in a sliding manner, a clamping mechanism (5) matched with the two mounting plates (16) is arranged in the positioning plate (15), and a clamping plate (17) is fixedly connected to the bottom of the mounting plate (16);

the belt conveying mechanism (6) is fixedly arranged on the inner sides of the first supporting frame (1) and the second supporting frame (2), detection mechanism supporting pieces for fixedly supporting the detection mechanisms are respectively arranged on the first supporting frame (1) and the second supporting frame (2), and a detection mechanism (3) for detecting the electrification of the storage battery is arranged below the detection mechanism supporting pieces;

the other side of the second supporting plate (11) is provided with a control panel (18), and the translation mechanism (4), the clamping mechanism (5) and the detection mechanism (3) are electrically connected with the control panel (18).

2. The power-on detection device for the storage battery according to claim 1, wherein the power piece comprises a second motor (41), the second motor (41) is fixedly arranged on the outer side surface of a second top plate (12), the translation mechanism (4) comprises a threaded rod (42) fixedly connected with the output end of the second motor (41), the threaded rod (42) is rotatably connected with the inner wall of the second top plate (12), an inner thread plate (43) is arranged on the outer ring of the threaded rod (42), the lower surface of the inner thread plate (43) is fixedly connected with the translation plate (13) through a connecting plate (44), and the second motor (41) is electrically connected with the control panel (18).

3. The power-on detection device for the storage battery according to claim 1, wherein the clamping mechanism (5) comprises a third motor (51), the third motor (51) is fixedly installed inside the positioning plate (15), the output end of the third motor (51) is fixedly connected with a second bidirectional screw rod (52), the second bidirectional screw rod (52) is rotatably connected with the inner wall of the positioning plate (15), two second internal thread sleeves (53) are annularly arranged on the second bidirectional screw rod (52), the two second internal thread sleeves (53) are fixedly connected with corresponding mounting plates (16) through connecting blocks (54) respectively, and the third motor (51) is electrically connected with the control panel (18).

4. The power-on detection device for a storage battery according to claim 1, wherein the detection mechanism support piece comprises two first support plates (7) which are respectively located on the same horizontal line with the first support frame (1) and the second support frame (2), the first support plates (7) are fixedly arranged above one side, which is outside, of the first support frames (1) and the second support frame (2), two horizontal first top plates (8) which are respectively fixedly connected with the upper parts of the first support plates (7) and are vertical to the first support plates, two electric telescopic rods (10) which are symmetrically arranged are respectively and fixedly arranged on the first top plates (8), two light touch switches (19) which are symmetrically arranged are respectively and fixedly arranged on the output ends of the electric telescopic rods (10) are respectively arranged above the detection plates (9), an indicator lamp (20) is fixedly arranged on the first top plates (8), and the electric telescopic rods (20) are respectively and symmetrically arranged on the lower surfaces of the detection plates (9), and the electric telescopic rods (20) are respectively matched with the electric telescopic rods (20).

5. The device for detecting the electrification of a storage battery according to claim 4, wherein each detection mechanism (3) comprises two first motors (31) and four conducting rings (34), the two first motors (31) are fixedly arranged at two ends inside the detection plate (9), each first motor (31) output end is fixedly connected with a first bidirectional screw rod (32), each first bidirectional screw rod (32) is respectively and rotatably connected with the inner wall of the detection plate (9), each first bidirectional screw rod (32) is respectively and annularly provided with two first internal thread sleeves (33), the two first internal thread sleeves (33) are respectively and fixedly connected with one conducting ring (34), the two conducting rings (34) are symmetrically arranged at two sides of the corresponding one tact switch (19), the two conducting rings (34) are respectively and slidably connected with the bottom of the detection plate (9), and the conducting rings (34) are electrically connected with the indicator lamp (20).

6. The power-on detection device for a storage battery according to claim 1, wherein stations (21) are fixedly mounted at both end portions of the first support frame (1) and both end portions of the second support frame (2).

7. A detection method using the energization detection apparatus for a secondary battery according to any one of claims 1 to 6, comprising the steps of:

s1: a worker stands on a station (21) at the first supporting frame (1), places a storage battery above a corresponding belt conveyor (6) from the front end of the first supporting frame (1), and adjusts the storage battery to be detected to a discharging state until the storage battery moves to the position below a detection plate (9) below the first supporting frame (1) along with the belt conveyor (6), and then closes the belt conveyor (6) at the top of the first supporting frame (1);

s2: starting an electric telescopic rod (10) at the first supporting frame (1) until the storage battery touches a tact switch (19) below a detection plate (9) below the first supporting frame (1), closing the electric telescopic rod (10), starting two first motors (31) of the detection plate (9) below one supporting frame (1) until two conducting rings (34) are respectively contacted with the positive electrode and the negative electrode of the storage battery, and observing whether an indicator lamp (20) works normally;

s3: the worker above the end station (21) of the first support frame (1) takes down the storage battery which does not normally work in the indicator lamp (20) in the step S2, namely the storage battery with power-on fault;

s4: for the storage battery with the lamp (20) indicated to work normally in the step S2, firstly starting the air cylinder (14) until the two clamping plates (17) are arranged on two sides of the storage battery, then starting the third motor (51) until the two clamping plates (17) clamp the storage battery, then starting the two clamping plates (17) to drive the storage battery to move upwards, finally starting the second motor (41) and matching with the two clamping plates (17), and placing the storage battery on the belt conveyor (6) on the inner side of the second supporting frame (2);

s5: the staff on the side face of the second supporting frame (2) adjusts the storage battery from a discharging state to a closing state, and after the storage battery moves to the position below a detection plate (9) at the second supporting frame (2) along with the belt conveyor (6), the belt conveyor (6) at the top of the second supporting frame (2) is closed and the storage battery to be detected is detected;

s6: starting an electric telescopic rod (10) at the second supporting frame (2) until the storage battery touches a tact switch (19) below a detection plate (9) below the second supporting frame (2), closing the electric telescopic rod (10), starting two first motors (31) of the detection plate (9) below the second supporting frame (2) until two conducting rings (34) are respectively contacted with the positive electrode and the negative electrode of the storage battery, and observing whether the side indicator lamp (20) works normally;

s7: the working state of the indicator lamp (20) corresponding to the second detection plate (9) is observed by a worker, and the storage battery is divided into two types of electricity leakage and qualification.