CN220034696U - Electrolytic zinc cathode conductive beam capable of reducing deformation - Google Patents

Abstract

The utility model relates to the technical field of electrolysis, in particular to an electrolytic zinc cathode conductive beam capable of reducing deformation. When the electrolyte impacts the conductive plate, the buffer component plays a role in buffering, and deformation between the conductive plate and the conductive beam main body caused by the impact of the electrolyte is reduced. The utility model has the effect of reducing the influence of electrolyte impact on the conductive beam, so that the conductive beam keeps good conductive performance.

Description

Electrolytic zinc cathode conductive beam capable of reducing deformation

Technical Field

The utility model relates to the technical field of electrolysis, in particular to an electrolytic zinc cathode conductive beam capable of reducing deformation.

Background

In the production process of electrolytic zinc, the cathode plate is necessary equipment and materials for a production system of an electrolysis workshop, so that the loss is large, and the service life of the cathode plate also greatly influences the production economic and technical indexes. The service life of the cathode plate is not only dependent on the external conditions such as the temperature, acidity and zinc stripping mode of the electrolyte, but also has a huge relationship with the main structure design of the conductive beam.

Currently, a die casting process for manufacturing a cathode plate for electrolytic zinc, disclosed in publication number CN1066089a, includes directly casting an aluminum plate into a preheated and inclined die cavity while casting a conductive beam body, and simultaneously casting a lifting lug onto the conductive beam body at one time.

For the related art, the conductive beam body needs to insert the aluminum plate into the electrolyte during use. The electrolysis trough produces vibrations easily in the course of the work, and electrolysis trough vibrations drive electrolyte and produce undulant to electrolyte will strike on aluminum plate at undulant in-process, and aluminum plate just produces deformation easily with the junction of conductive beam main part, thereby leads to the area of contact between aluminum plate and the conductive beam main part to reduce, and conductive efficiency reduces, thereby makes the reaction efficiency in the electrolyte reduce.

Disclosure of Invention

In order to reduce the influence of electrolyte impact on the conductive beam and enable the conductive beam to maintain good conductive performance, the utility model provides an electrolytic zinc cathode conductive beam with reduced deformation.

The utility model provides an electrolytic zinc cathode conductive beam capable of reducing deformation, which adopts the following technical scheme:

an electrolytic zinc cathode conductive beam with reduced deformation comprising:

the conductive beam comprises a conductive beam main body, wherein one side of the conductive beam main body is provided with a lifting lug, the other side of the conductive beam main body is provided with a mounting groove, and a conductive plate is mounted in the mounting groove;

and the buffer component is installed in the installation groove and is used for reducing the impact between the conductive plate and the conductive beam main body.

Through adopting above-mentioned technical scheme, when electrolyte impacted on the current conducting plate at electrolytic in-process, buffer assembly was buffered the impact that the current conducting plate received to reduce the impact force between current conducting plate to the conductive beam main part, make the junction between current conducting plate and the conductive beam main part be difficult for taking place to warp. The impact of the electrolyte on the conductive plate is reduced by utilizing the buffer component, so that good conductivity is kept between the aluminum plate and the conductive beam main body.

Optionally, the buffer assembly includes buffer spring, butt piece, buffer spring's one end fixed connection is in on the inner wall of mounting groove, the other end fixed connection is on the butt piece, the butt piece is used for right the conducting plate carries out the butt.

Through adopting above-mentioned technical scheme, utilize the butt piece to realize the fixed to the conducting plate to the butt of conducting plate, when electrolyte produced the impact to the conducting plate, buffer spring played the cushioning effect to the butt piece, the butt piece continues to butt on the conducting plate after the reset afterwards for keep comparatively great area of contact between conducting plate and the conductive beam main part, thereby keep good conductive properties.

Optionally, two abutting blocks are provided, and the buffer spring is located on one side, away from each other, of the abutting blocks.

Through adopting above-mentioned technical scheme, utilize two butt pieces to carry out the centre gripping with the conducting plate, can effectually alleviate the impact of electrolyte to the conducting plate in two different directions.

Optionally, a clamping block is fixedly connected to the conductive plate, two sides, close to each other, of the two abutting blocks are respectively provided with a clamping groove, and the clamping blocks are inserted into the clamping grooves.

Through adopting above-mentioned technical scheme, utilize the cooperation of joint piece and joint groove for the current-conducting plate is when adsorbing more zinc, also can keep the stable connection between current-conducting plate and the conductive beam main part, makes the current-conducting plate be difficult for dropping.

Optionally, a stopper is fixedly connected with the opening of the mounting groove, and the abutting block abuts against the stopper.

Through adopting above-mentioned technical scheme, utilize the support force that the stopper provided to the butt piece, reduced the support force that the vertical direction of buffer spring provided to the butt piece.

Optionally, the top of butt piece with the inner wall laminating of mounting groove.

Through adopting above-mentioned technical scheme, with the top butt of butt piece top and mounting groove, the bottom and the stopper butt of butt piece simultaneously for have great area of contact between butt piece and the conductive beam main part, make to keep good guide performance between butt piece and the conductive beam main part.

Optionally, the abutment block is provided with a guiding inclined plane in the length direction, and the distance between the two abutment blocks gradually decreases as the guiding inclined plane approaches the middle part of the abutment block.

Through adopting above-mentioned technical scheme, the setting of guide inclined plane is convenient for insert the conducting plate and establish to the mounting groove for the butt piece is convenient for carry out the butt to the conducting plate more, thereby has reached the installation conducting plate more convenient.

Optionally, the lug includes lifting hook, hanging seat, the lifting hook with install the shock attenuation piece between the hanging seat, the shock attenuation piece is used for reducing the vibrations that the conductive beam main part received.

Through adopting above-mentioned technical scheme, at electrolytic in-process, the connection of the lug that utilizes is electrically conductive to the conductive beam main part, because equipment is easy to oscillate, consequently lug department not only takes place the fracture easily, also causes the deformation of conductive beam main part simultaneously easily. Therefore, vibration between the lifting lug and the conductive beam main body is reduced by the damping piece, so that the service life of the lifting lug is longer, and the conductive beam main body is less prone to deformation.

Optionally, the damping member includes damping spring, damping spring one end with lifting hook fixed connection, the other end with hanging seat fixed connection.

Through adopting above-mentioned technical scheme, utilize damping spring to carry out the shock attenuation between lifting hook and hanging seat for bear less vibrations between hanging seat and the conductive beam main part, thereby make difficult emergence damage between hoist and mount and the conductive beam main part.

Optionally, a guide rod is fixedly connected to the lifting hook, a guide groove is formed in the lifting seat, the guide rod is inserted into the guide groove, and the damping spring is wound on the guide rod.

Through adopting above-mentioned technical scheme, the setting of guide bar has not only led damping spring's flexible direction, has still strengthened the area of contact between lifting hook and the hanger bracket for electrically conductive effect is better between lifting hook and the hanger bracket.

In summary, the present utility model includes at least one of the following beneficial technical effects:

1. through the cooperation of the conductive beam main body, the lifting lug, the mounting groove, the conductive plate and the buffer component, when the conductive plate bears the impact of electrolyte, the buffer component can buffer the conductive plate, so that the effect of reducing the impact of the electrolyte on the conductive beam is achieved, and the conductive beam keeps good conductive performance;

2. the clamping and fixing of the conductive plate are realized through the matching of the buffer spring and the two abutting blocks, so that a good buffer effect is realized between the conductive plate and the conductive beam main body;

3. through the cooperation of lifting hook, hanging seat and damping spring to the influence of equipment vibrations to the conductive beam main part has been reached to reduce.

Drawings

Fig. 1 is a schematic structural view of an electrolytic zinc cathode conductive beam with reduced deformation in an embodiment of the utility model.

Fig. 2 is a side view of an electrolytic zinc cathode conductive beam with reduced deformation in accordance with an embodiment of the present utility model.

Fig. 3 is a cross-sectional view of A-A in fig. 2.

Fig. 4 is an exploded view of a shackle in an embodiment of the present utility model.

Reference numerals illustrate:

1. a conductive beam body; 11. a mounting groove; 2. lifting lugs; 21. a lifting hook; 22. a hanging seat; 23. a guide groove; 3. a conductive plate; 31. a clamping block; 4. a buffer assembly; 41. a buffer spring; 42. an abutment block; 43. a clamping groove; 44. a guide slope; 5. a limiting block; 6. a shock absorbing member; 61. a damping spring; 7. a guide rod.

Detailed Description

The utility model is described in further detail below with reference to fig. 1-4.

The embodiment of the utility model discloses an electrolytic zinc cathode conductive beam capable of reducing deformation.

Referring to fig. 1, an electrolytic zinc cathode conductive beam for reducing deformation comprises a conductive beam main body 1, wherein one side of the conductive beam main body 1 is provided with a lifting lug 2, the other side is provided with a mounting groove 11, a conductive plate 3 and a buffer component 4 are mounted in the mounting groove 11, and the buffer component 4 is used for abutting the conductive plate 3 in the mounting groove 11. When the electrolyte impacts the conductive plate 3, the buffer component 4 plays a role in buffering, deformation between the conductive plate 3 and the conductive beam main body 1 caused by the impact of the electrolyte is reduced, and the conductive beam main body 1 keeps good conductive performance.

In the process of electrolysis, when electrolyte is impacted on the conductive plate 3, the impact on the conductive plate 3 is buffered by the buffer component 4, so that the impact force between the conductive plate 3 and the conductive beam main body 1 is reduced, the joint between the conductive plate 3 and the conductive beam main body 1 is not easy to deform, and good conductivity is kept between the aluminum plate and the conductive beam main body 1.

Referring to fig. 2, the buffer assembly 4 includes a buffer spring 41 and an abutment block 42 in the present embodiment, and in other embodiments the buffer assembly 4 may be further provided with a shock absorbing and buffering material having elasticity, such as rubber, foam, etc., filled between the abutment block 42 and the conductive beam body 1. The impact between the conductive plate 3 and the conductive beam is buffered by the buffer spring 41 or the shock absorbing, buffering material having elasticity, thereby reducing the deformation of the conductive beam due to the impact caused by the electrolyte.

In this embodiment, one end of the buffer spring 41 is fixedly connected to the inner wall of the mounting groove 11, and the other end is fixedly connected to the abutting block 42, and the abutting block 42 is used for abutting against the conductive plate 3. The conductive plate 3 is fixed by abutting the conductive plate 3 by the abutting block 42, when the electrolyte impacts the conductive plate 3, the buffer spring 41 plays a role of buffering the abutting block 42, and then the abutting block 42 continuously abuts against the conductive plate 3 after reset, so that a relatively large contact area is maintained between the conductive plate 3 and the conductive beam main body 1, and good conductive performance is maintained.

In the present embodiment, two abutment blocks 42 are provided, the buffer springs 41 are located on the sides where the abutment blocks 42 are away from each other, and the two abutment blocks 42 are driven to approach each other by the buffer springs 41, so that the conductive plate 3 is clamped. In other embodiments, the single-side abutting block 42 can be arranged to abut, so that deformation of the conductive beam can be reduced, and in the embodiment, both sides are abutted by the abutting block 42, so that impact of electrolyte on both sides of the conductive plate 3 can be effectively buffered, and the buffer spring 41 has a better buffer effect.

The clamping blocks 31 are fixedly connected to the two sides of the top of the conducting plate 3 respectively, the clamping grooves 43 are formed in the sides, close to each other, of the two abutting blocks 42 respectively, and the clamping blocks 31 are matched and inserted into the clamping grooves 43. By utilizing the matching of the clamping blocks 31 and the clamping grooves 43, the conductive plate 3 can also keep stable connection between the conductive plate 3 and the conductive beam main body 1 when absorbing more zinc, so that the conductive plate 3 is not easy to fall.

The opening part of the mounting groove 11 is fixedly connected with a limiting block 5, the limiting block 5 abuts against part of the bottom of the abutting block 42, and the limiting block 5 is supported by the limiting block 42 due to the limitation of the moving distance of the limiting block 5 by the buffer spring 41. With the supporting force provided by the stopper 5 to the abutting block 42, the supporting force provided by the buffer spring 41 to the abutting block 42 in the vertical direction is reduced. Simultaneously, the top of the abutting block 42 is attached to the inner wall of the top of the mounting groove 11 by the supporting of the abutting block 42 by the limiting block 5,

by abutting the top of the abutting block 42 against the top of the mounting groove 11, and simultaneously abutting the bottom of the abutting block 42 against the stopper 5, a large contact area is provided between the abutting block 42 and the conductive beam body 1, so that good guiding performance is maintained between the abutting block 42 and the conductive beam body 1.

Referring to fig. 3, in the present embodiment, guide slopes 44 are respectively provided at both ends of the two abutment blocks 42 in the longitudinal direction, and the distance between the two abutment blocks 42 gradually decreases as the guide slopes 44 approach the middle portion of the abutment blocks 42. In other embodiments, the guide inclined surfaces 44 may be formed at the same end of the two abutment blocks 42, and the guide inclined surfaces 44 may be formed at one or both ends of the same abutment block 42.

The setting of guide slope 44 in this embodiment is convenient for insert the current conducting plate 3 to the mounting groove 11 in not only to guide slope 44 has all been seted up at the both ends of two butt pieces 42 so that current conducting plate 3 can insert from current conducting beam main part 1 both sides and establish to the mounting groove 11 in, is convenient for utilize butt piece 42 to carry out the butt to current conducting plate 3 more, thereby has reached that installation current conducting plate 3 is more convenient.

Referring to fig. 4, in an alternative embodiment, the lifting lug 2 includes a lifting hook 21 and a lifting seat 22, and a shock absorbing member 6 is installed between the lifting hook 21 and the lifting seat 22, and the shock absorbing member 6 is used to reduce shock to which the conductive beam body 1 is subjected. The damping member 6 is a damping spring 61 in this embodiment, and the damping member 6 may be an elastic rubber pad in other embodiments.

In the electrolytic process, the connection of the lifting lug 2 is used for conducting electricity to the conductive beam main body 1, and as equipment is easy to vibrate, the connection part of the lifting lug 2 and the conductive beam main body 1 is easy to break, and meanwhile, the conductive beam main body 1 is easy to deform. Therefore, vibration between the lifting lug 2 and the conductive beam main body 1 (refer to fig. 1) is reduced by the damping piece 6, so that the service life of the lifting lug 2 is longer, and the conductive beam main body 1 is less prone to deformation.

One end of the damping spring 61 is fixedly connected with the lifting hook 21, and the other end is fixedly connected with the lifting seat 22. The damping spring 61 is utilized to damp vibration between the lifting hook 21 and the lifting seat 22, so that the lifting seat 22 and the conductive beam main body 1 (refer to fig. 1) bear smaller vibration, and the lifting and the conductive beam main body 1 (refer to fig. 1) are not easy to damage.

The lifting hook 21 is fixedly connected with a guide rod 7, the lifting seat 22 is provided with a guide groove 23, the guide rod 7 is coaxially inserted into the guide groove 23, and the outer wall of the guide rod 7 is attached to the inner wall of the guide groove 23. The conduction effect between the lifting hook 21 and the lifting seat 22 is better by utilizing the fit between the guide rod 7 and the inner wall of the guide groove 23.

Meanwhile, the damping spring 61 is wound on the guide rod 7, and the guide rod 7 is used for guiding the elastic deformation of the damping spring 61, so that the telescopic direction of the damping spring 61 is guided by the guide rod 7.

The implementation principle of the electrolytic zinc cathode conductive beam for reducing deformation in the embodiment of the utility model is as follows: when the conductive plate 3 is mounted, the engaging block 31 on the conductive plate 3 is aligned with the engaging groove 43 on the abutting block 42, and then the conductive plate 3 is inserted into the middle portion of the mounting groove 11 along the guide slope 44 from the abutting block 42 side, so that the two abutting blocks 42 completely abut the conductive plate 3.

The conductive plate 3 is inserted into the electrolyte for electrolysis, and vibration in the operation process of equipment can cause fluctuation of the electrolyte, when the fluctuation of the electrolyte is impacted on the conductive plate 3, the buffer spring 41 at the connecting position between the conductive plate 3 and the conductive beam main body 1 deforms for buffering, and after the reset, the two abutting blocks 42 continue to have good abutting effect on the conductive plate 3, so that the connecting part of the conductive beam main body 1 and the conductive plate 3 is not easy to deform, and good conductive performance is achieved between the conductive beam main body 1 and the conductive plate 3.

The above embodiments are not intended to limit the scope of the present utility model, so: all equivalent changes in structure, shape and principle of the utility model should be covered in the scope of protection of the utility model.

Claims (10)

1. An electrolytic zinc cathode conductive beam for reducing distortion, comprising:

the conductive beam comprises a conductive beam body (1), wherein one side of the conductive beam body (1) is provided with a lifting lug (2), the other side of the conductive beam body is provided with a mounting groove (11), and a conductive plate (3) is mounted in the mounting groove (11);

and the buffer component (4) is installed in the installation groove (11), and the buffer component (4) is used for reducing the impact between the conductive plate (3) and the conductive beam main body (1).

2. A deformation reducing electrolytic zinc cathode conductive beam according to claim 1, wherein: the buffer assembly (4) comprises a buffer spring (41) and an abutting block (42), one end of the buffer spring (41) is fixedly connected to the inner wall of the mounting groove (11), the other end of the buffer spring is fixedly connected to the abutting block (42), and the abutting block (42) is used for abutting the conducting plate (3).

3. A deformation reducing electrolytic zinc cathode conductive beam according to claim 2, wherein: the two abutting blocks (42) are arranged, and the buffer springs (41) are positioned on one sides of the abutting blocks (42) which are away from each other.

4. A reduced deformation electrolytic zinc cathode conductive beam according to claim 3, wherein: the conductive plate (3) is fixedly connected with a clamping block (31), one sides, close to each other, of the two abutting blocks (42) are respectively provided with a clamping groove (43), and the clamping block (31) is inserted into the clamping grooves (43).

5. A deformation reducing electrolytic zinc cathode conductive beam according to claim 2, wherein: a limiting block (5) is fixedly connected to the opening of the mounting groove (11), and the abutting block (42) abuts against the limiting block (5).

6. A deformation reducing electrolytic zinc cathode conductive beam according to claim 5, wherein: the top of the abutting block (42) is attached to the inner wall of the mounting groove (11).

7. A deformation reducing electrolytic zinc cathode conductive beam according to claim 2, wherein: the abutting blocks (42) are provided with guide inclined planes (44) in the length direction, and the distance between the two abutting blocks (42) gradually decreases as the guide inclined planes (44) approach the middle part of the abutting blocks (42).

8. A deformation reducing electrolytic zinc cathode conductive beam according to claim 1, wherein: lifting lug (2) are including lifting hook (21), hanging seat (22), lifting hook (21) with install shock attenuation piece (6) between hanging seat (22), shock attenuation piece (6) are used for reducing vibrations that electrically conductive roof beam main part (1) received.

9. The electrolytic zinc cathode conductive beam for reducing distortion according to claim 8, wherein: the damping piece (6) comprises a damping spring (61), one end of the damping spring (61) is fixedly connected with the lifting hook (21), and the other end of the damping spring is fixedly connected with the lifting seat (22).

10. A deformation reducing electrolytic zinc cathode conductive beam according to claim 9, wherein: the lifting hook (21) is fixedly connected with a guide rod (7), a guide groove (23) is formed in the lifting seat (22), the guide rod (7) is inserted into the guide groove (23), and the damping spring (61) is wound on the guide rod (7).