CN220171226U - Test platform of energy storage battery monitoring unit - Google Patents

Abstract

The utility model relates to a test platform of an energy storage battery monitoring unit, which comprises a movable bracket, a placing table, a supporting platform and a storage box, wherein a motor is started to drive a screw rod to rotate, so that a left end extension frame and a right end extension frame of a test support frame are in threaded fit and displace along a guide rail, the whole test support frame is enabled to move back and forth, the position of an irradiation detection lamp irradiated on a circuit board is adjusted, when the test support frame penetrates through an auxiliary positioning block to displace, the outer end face of the test support frame is contacted with a contact block, and under flexible elastic fit of a telescopic plate, the contact block and the outer peripheral faces of the left end extension frame and the right end extension frame of the test support frame generate equivalent contact pressure, so that friction damage caused by displacement of the test support frame after multiple use is reduced.

Description

Test platform of energy storage battery monitoring unit

Technical Field

The utility model relates to the technical field of battery testing, in particular to a testing platform of an energy storage battery monitoring unit.

Background

The battery management system, namely the BMS, is a system for controlling the functions of electric energy collection, temperature monitoring, data acquisition, transmission and the like in the energy storage battery, and the battery monitoring unit is detected by using a test platform of the energy storage battery monitoring unit, and usually, the circuit board inside the battery monitoring unit is tested to obtain data.

When a plurality of circuit boards are detected at one time, the circuit boards are placed on the detection table surface, the irradiation detection and the like need to continuously change positions to carry out irradiation detection on important positions of the circuit boards, usually, a person manually moves the test support frame, and the positions of the detection lamps are changed, so that more manual labor is needed in the detection.

Disclosure of Invention

(one) solving the technical problems

In order to solve the technical problems, the utility model provides a test platform of an energy storage battery monitoring unit.

(II) technical scheme

Based on the above, the utility model provides the following technical scheme: the testing platform of the energy storage battery monitoring unit comprises a movable support, a placing table, a supporting platform and a storage box, wherein the bottom end of the movable support is arranged above the supporting platform, the movable support is movably matched with the placing table, and the storage box is fixedly arranged below the supporting platform;

the movable support comprises a positioning device, a test support frame, an irradiation detection lamp, a display screen and a detection signal lamp, wherein the left end and the right end of the test support frame are in sliding clamping connection with the positioning device, the irradiation detection lamp is installed at the middle front end position of the test support frame, the display screen is located at the side position of the middle end of the test support frame, and the detection signal lamp is fixedly installed at the middle top end position of the test support frame.

Preferably, the positioning device comprises a positioning frame, a positioning block and an auxiliary positioning block, wherein the positioning block is fixedly arranged at the top of the positioning frame, and the auxiliary positioning block is fixedly connected to the side face of the positioning frame in a embedding way.

Preferably, the locating rack includes fixing base, flat board, guide rail, motor and screw rod, the flat board is inlayed fixedly and is connected between the fixing base, the guide rail is integrated with the flat board and establish on its one side terminal surface, the motor is fixed on the outside terminal surface of flat board and is passed the flat board, the screw rod is connected with the output of motor, the screw rod is passed the inside of flat board.

Preferably, the auxiliary positioning block comprises a solid block, a movable groove, a telescopic plate and a contact block, wherein the movable groove and the solid block are of an integrated structure, the telescopic plate is movable in the movable groove, and the front end of the telescopic plate is connected with the contact block and is in movable fit.

Preferably, the bottom of positioner is installed at supporting platform's up end, shine and detect the lamp activity in the top of placing the platform, positioner is equipped with two places, and is the symmetry setting, every positioner is matchd respectively to the left and right sides end support of test support frame, and the whole back and forth displacement activity of doing of test support frame of being convenient for.

Preferably, the retention block is made of soft silica gel, has certain flexibility and has good anti-skid effect.

Preferably, the screw is in threaded connection below the brackets at the left end and the right end of the test support frame, and the screw is driven by a motor to rotate so as to conveniently provide power for the displacement of the test support frame.

Preferably, the expansion plate has elasticity, the touch block is soft resin material, has hardness and has certain deformability simultaneously, and has better contact effect with the outer peripheral surface of the test support frame.

Three beneficial effects

Compared with the prior art, the utility model provides a test platform of an energy storage battery monitoring unit, which has the following beneficial effects:

1. this test platform of energy storage battery monitor cell, place the energy storage battery of waiting to detect the test and to the circuit board that electric energy service condition monitored on placing the platform, open the switch of whole equipment, make and shine detection lamp and display screen all be in the state of circular telegram, adjust the test support frame, let it carry out the displacement along positioner, and then control and shine the displacement that detection lamp was placing the platform, make and shine the detection lamp and can produce the gathering light on the circuit board, and shine the circuit position that needs key detection on the circuit board, then real-time response carries out the measurement of relevant data on the display screen.

2. The test platform of the energy storage battery monitoring unit is characterized in that a motor is started to drive a screw rod to rotate, a left end extension frame and a right end extension frame of a test support frame are in threaded fit and move along a guide rail, the whole test support frame is enabled to move back and forth, the position of an irradiation detection lamp irradiated on a circuit board is adjusted, when the test support frame penetrates through an auxiliary positioning block to move, the outer end face of the test support frame is contacted with a contact block, and under flexible elastic fit of a telescopic plate, the contact block and the outer peripheral face of the left end extension frame and the right end extension frame of the test support frame generate equal contact pressure, so that friction damage caused by the displacement of the test support frame after the test support frame is used for multiple times is reduced.

Drawings

FIG. 1 is a schematic structural diagram of a test platform of an integral energy storage battery monitoring unit of the present utility model;

FIG. 2 is a schematic perspective view of a movable bracket according to the present utility model;

FIG. 3 is a schematic perspective view of a positioning device according to the present utility model;

FIG. 4 is a schematic top view of the positioning frame of the present utility model;

fig. 5 is a schematic side view of the auxiliary positioning block of the present utility model.

In the figure: the device comprises a movable bracket-1, a placing table-2, a supporting platform-3, a storage box-4, a positioning device-11, a test supporting frame-12, an irradiation detection lamp-13, a display screen-14, a detection signal lamp-15, a positioning frame-111, a fixing block-112, an auxiliary positioning block-113, a fixed seat-a 1, a plane plate-a 2, a guide rail-a 3, a motor-a 4, a screw-a 5, a solid block-z 1, a movable groove-z 2, a telescopic plate-z 3 and a contact block-z 4.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. 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. 1-2, a test platform of an energy storage battery monitoring unit comprises a movable support 1, a placement table 2, a support platform 3 and a storage box 4, wherein the bottom end of the movable support 1 is installed above the support platform 3, the movable support 1 is movably matched with the placement table 2, the storage box 4 is fixedly installed below the support platform 3, the movable support 1 comprises a positioning device 11, a test support frame 12, an irradiation detection lamp 13, a display screen 14 and a detection signal lamp 15, the left end and the right end of the test support frame 12 are in sliding clamping connection with the positioning device 11, the irradiation detection lamp 13 is installed at the middle front end position of the test support frame 12, the display screen 14 is located at the side position of the middle end of the test support frame 12, and the detection signal lamp 15 is fixedly installed at the middle top end position of the test support frame 12.

In addition, the retention block 112 is made of soft silica gel, has certain flexibility, and has good anti-skid effect.

In addition, the auxiliary positioning block 113 comprises a solid block z1, a movable groove z2, a telescopic plate z3 and a contact block z4, wherein the movable groove z2 and the solid block z1 are of an integrated structure, the telescopic plate z3 is movable in the movable groove z2, and the front end of the telescopic plate z3 is connected with the contact block z4 and is in movable fit.

Referring to fig. 3-4, the positioning device 11 includes a positioning frame 111, a positioning block 112, and an auxiliary positioning block 113, wherein the positioning block 112 is fixedly mounted on the top of the positioning frame 111, and the auxiliary positioning block 113 is fixedly connected to a side surface of the positioning frame 111.

In addition, the positioning frame 111 comprises a fixing seat a1, a plane plate a2, a guide rail a3, a motor a4 and a screw rod a5, wherein the plane plate a2 is fixedly connected between the fixing seats a1, the guide rail a3 and the plane plate a2 are of an integrated structure and are arranged on one side end face of the guide rail a3, the motor a4 is fixed on the outer side end face of the plane plate a2 and penetrates through the plane plate a2, the screw rod a5 is connected with the output end of the motor a4, and the screw rod a5 penetrates through the inside of the plane plate a 2.

In addition, the screw rod a5 is in threaded connection below the brackets at the left end and the right end of the test supporting frame 12, and the screw rod a5 is driven by the motor a4 to rotate so as to conveniently provide power for the displacement of the test supporting frame 12.

Referring to fig. 5, the bottom end of the positioning device 11 is mounted on the upper end surface of the supporting platform 3, the irradiation detection lamp 13 is movably disposed above the placement table 2, the positioning devices 11 are symmetrically disposed, and the left and right side end brackets of the test support frame 12 are respectively matched with each positioning device 11, so that the whole test support frame 12 can conveniently move back and forth.

In addition, the expansion plate z3 has elasticity, the contact block z4 is made of soft resin, has hardness and certain deformation, and has a good contact effect with the outer peripheral surface of the test support frame 12.

In summary, when in use, the circuit board for monitoring the energy storage battery to be tested and the electric energy use condition is placed on the placement table 2, the switch of the whole equipment is turned on, so that the irradiation detection lamp 13 and the display screen 14 are in the electrified state, the test support frame 12 is adjusted, the irradiation detection lamp 13 is displaced along the positioning device 11, further the displacement of the irradiation detection lamp 13 on the placement table 2 is controlled, the irradiation detection lamp 13 can generate concentrated light on the circuit board, the circuit board is irradiated at the circuit position which needs to be detected in a key way, then the measurement of relevant data is performed on the display screen 14 in real time, the motor a4 is started, the screw a5 is driven to rotate, the left and right end extension frames of the test support frame 12 are subjected to threaded fit to displace along the guide rail a3, the whole test support frame 12 is enabled to perform front and back displacement activity, the position of the irradiation detection lamp 13 is adjusted, when the test support frame 12 penetrates through the auxiliary positioning block 113 to displace, the outer end face of the test support frame 12 contacts the contact block z4, the flexible elastic fit of the expansion plate z3 enables the contact block z4 and the outer peripheral face of the test support frame 12 to be damaged due to the fact that the contact with the left and right end extension frames of the test support frame 12 are contacted with each other, and the friction displacement is reduced.

The control mode of the utility model is controlled by manually starting and closing the switch, the wiring diagram of the power element and the supply of the power supply are common knowledge in the field, and the utility model is mainly used for protecting the mechanical device, so the utility model does not explain the control mode and the wiring arrangement in detail.

The control mode of the utility model is automatically controlled by the controller, the control circuit of the controller can be realized by simple programming of a person skilled in the art, the supply of power also belongs to common knowledge in the art, and the utility model is mainly used for protecting a mechanical device, so the utility model does not explain the control mode and circuit connection in detail.

Although embodiments of the present utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (8)

1. Test platform of energy storage battery monitoring unit, its characterized in that: the automatic storage device comprises a movable support (1), a placing table (2), a supporting platform (3) and a storage box (4), wherein the bottom end of the movable support (1) is arranged above the supporting platform (3), the movable support (1) is in movable fit with the placing table (2), and the storage box (4) is fixedly arranged below the supporting platform (3);

the movable support (1) comprises a positioning device (11), a test support frame (12), an irradiation detection lamp (13), a display screen (14) and a detection signal lamp (15), wherein the left end and the right end of the test support frame (12) are in sliding clamping with the positioning device (11), the irradiation detection lamp (13) is installed at the middle front end position of the test support frame (12), the display screen (14) is located at the middle end side position of the test support frame (12), and the detection signal lamp (15) is fixedly installed at the middle top end position of the test support frame (12).

2. The test platform for an energy storage cell monitoring unit of claim 1, wherein: the positioning device (11) comprises a positioning frame (111), a positioning block (112) and an auxiliary positioning block (113), wherein the positioning block (112) is fixedly arranged at the top of the positioning frame (111), and the auxiliary positioning block (113) is fixedly connected to the side face of the positioning frame (111) in a embedding mode.

3. The test platform for an energy storage cell monitoring unit of claim 2, wherein: the locating rack (111) is including fixing base (a 1), plane board (a 2), guide rail (a 3), motor (a 4) and screw rod (a 5), the fixed connection is rule between fixing base (a 1) to plane board (a 2), guide rail (a 3) and plane board (a 2) are integrated structure and establish on its one side terminal surface, motor (a 4) are fixed on the outside terminal surface of plane board (a 2) and are passed plane board (a 2) perpendicularly, screw rod (a 5) are connected with the output of motor (a 4), inside that screw rod (a 5) passed plane board (a 2) perpendicularly.

4. The test platform for an energy storage cell monitoring unit of claim 2, wherein: the auxiliary positioning block (113) comprises a solid block (z 1), a movable groove (z 2), a telescopic plate (z 3) and a contact block (z 4), wherein the movable groove (z 2) and the solid block (z 1) are of an integrated structure, the telescopic plate (z 3) moves in the movable groove (z 2), and the front end of the telescopic plate (z 3) is connected with the contact block (z 4) and is in movable fit.

5. The test platform for an energy storage cell monitoring unit of claim 1, wherein: the bottom of positioner (11) is installed in the up end of supporting platform (3), shine and detect lamp (13) activity in the top of placing platform (2), positioner (11) are equipped with two places, and are the symmetry setting, each positioner (11) are matchd respectively to the left and right sides end support of test support frame (12).

6. The test platform for an energy storage cell monitoring unit of claim 2, wherein: the fixing block (112) is made of soft silica gel, has certain flexibility and has good anti-skid effect.

7. A test platform for an energy storage cell monitoring unit as defined in claim 3, wherein: the screw rod (a 5) is in threaded connection below the brackets at the left end and the right end of the test supporting frame (12), and the screw rod (a 5) is driven by the motor (a 4) to rotate.

8. The test platform for an energy storage cell monitoring unit of claim 4, wherein: the expansion plate (z 3) has elasticity, and the contact block (z 4) is made of soft resin, has hardness and has certain deformation.