CN220350369U - Electrolyte barrel for reducing electrolyte residual liquid - Google Patents

Abstract

The utility model relates to the technical field of electrolyte storage, in particular to an electrolyte barrel for reducing electrolyte residual liquid, which comprises the following components: the device comprises a barrel body with a hollow liquid storage cavity, a liquid discharge hopper arranged at the bottom of the barrel body, a liquid scraping assembly arranged in the hollow liquid storage cavity, and a driving assembly arranged at the top of the barrel body and used for driving the liquid scraping assembly to rotate in the hollow liquid storage cavity to scrape the cavity wall of the hollow liquid storage cavity; wherein the hollow liquid storage cavity is a cylindrical cavity; the liquid scraping assembly comprises a transverse connecting rod and a pair of longitudinal scraping rods, the transverse connecting rod is arranged along the inner diameter direction of the hollow liquid storage cavity, and the pair of longitudinal scraping rods are respectively connected with two ends of the transverse connecting rod; the pair of longitudinal scraping rods extend along the axial direction of the hollow liquid storage cavity so that the pair of longitudinal scraping rods scrape the cavity wall of the hollow liquid storage cavity. The utility model can improve the cleaning efficiency of residual electrolyte in the barrel body.

Description

Electrolyte barrel for reducing electrolyte residual liquid

Technical Field

The utility model relates to the technical field of electrolyte storage, in particular to an electrolyte barrel for reducing electrolyte residual liquid.

Background

The electrolyte is a medium used by chemical batteries, electrolytic capacitors and the like, provides ions for the normal operation of the electrolyte, and ensures that chemical reactions occurring in the operation are reversible. The electrolyte barrel is used as a packaging container of the electrolyte, and is protected by inert gas, so that the water and the acidity can be kept stable for a long time. However, when the electrolyte in the re-electrolyte tank is stored and cannot be completely poured out from the electrolyte tank, the electrolyte is wasted, and the environment is not protected, so that the subsequent electrolyte waste liquid is difficult to treat.

For this, for example, patent publication No. CN 218229820U discloses an electrolyte barrel for reducing electrolyte residual liquid, which comprises an electrolyte outer barrel and an electrolyte inner barrel which are nested with each other, when the electrolyte in the electrolyte inner barrel is emptied, in order to empty the residual liquid in the electrolyte inner barrel, the electrolyte inner barrel at the bottom of the liquid injection pipe is inserted into a driving shaft through a rotating tool and rotated at a high speed, and the transmission chain is utilized to drive the electrolyte inner barrel at the bottom of the liquid injection pipe to rotate and swing at a high speed in the electrolyte outer barrel, so that the residual liquid on the wall of the electrolyte inner barrel is centrifugally thrown into a clear liquid bucket, and in the rotation process of the electrolyte inner barrel, a scraping sheet rotates along with inertia on the inner wall of the electrolyte inner barrel, so that the residual liquid which is sunk into the wall of the clear liquid bucket is scraped and discharged along with the scraping sheet after being led into a liquid discharge pipe, thereby effectively reducing the existence of the residual liquid in the electrolyte inner barrel.

However, for the electrolyte tank in the practical use process, the general electrolyte tank has a certain weight and the overall height is larger, so that the overall electrolyte tank can be said to be a tank body with a relatively larger volume, and the electrolyte tank adopting the above disclosed technology needs to drive the inner electrolyte tank to rotate by rotating a tool, so that on one hand, the problem of larger energy consumption exists; on the other hand, there is a problem of how to ensure the stability of the rotation process of the inner barrel of the electrolyte with a large volume. Based on the problems of the two aspects, the electrolyte tank of the disclosed technology can accelerate the discharge of residual liquid through the rotation of the electrolyte inner tank relative to the electrolyte outer tank theoretically, but a series of problems still exist in practical use to be solved.

Therefore, in order to overcome the defects of the electrolyte barrel used in the prior art in terms of residual liquid discharge, the structure of the electrolyte barrel needs to be further optimized.

Disclosure of Invention

The utility model aims to provide an electrolyte barrel for reducing electrolyte residual liquid, so as to solve the technical problem of optimizing a residual liquid discharge structure of the electrolyte barrel.

The electrolyte barrel for reducing the residual liquid of the electrolyte is realized by the following steps:

an electrolyte cartridge for reducing electrolyte residue, comprising: the device comprises a barrel body with a hollow liquid storage cavity, a liquid discharge hopper arranged at the bottom of the barrel body, a liquid scraping assembly arranged in the hollow liquid storage cavity, and a driving assembly arranged at the top of the barrel body and used for driving the liquid scraping assembly to rotate in the hollow liquid storage cavity to scrape the cavity wall of the hollow liquid storage cavity; wherein the method comprises the steps of

The hollow liquid storage cavity is a cylindrical cavity; and

the liquid scraping assembly comprises a transverse connecting rod which is arranged along the inner diameter direction of the hollow liquid storage cavity, and a pair of longitudinal scraping rods which are respectively connected with two ends of the transverse connecting rod;

the pair of longitudinal scraping rods extend along the axial direction of the hollow liquid storage cavity so that the pair of longitudinal scraping rods scrape the cavity wall of the hollow liquid storage cavity.

In an alternative embodiment of the utility model, the driving assembly comprises a rotating seat penetrating through the top of the barrel body and a power structure for driving the rotating seat to rotate.

In an alternative embodiment of the utility model, the power structure comprises a toothed ring connected with the rotating seat, a gear meshed with the toothed ring, and a motor connected with the gear.

In an alternative embodiment of the utility model, the transverse joint rod and the pair of longitudinal scraper rods are hollow rods; and

a cavity communicated with the transverse connecting rod is formed in the rotating seat;

and a pair of longitudinal scraping rods are provided with exhaust grooves towards the side end surfaces of the cavity walls of the hollow liquid storage cavity.

In an alternative embodiment of the utility model, a sealing bin for covering the rotating seat is further arranged at the top of the barrel body; and

the sealing bin is provided with a one-way air valve which is arranged on the rotating seat and communicated with the cavity, and an air outlet pipe which is connected with the one-way air valve;

the air outlet pipe is connected with an air pump.

In an alternative embodiment of the utility model, the drain hopper is in a cone shape; and

the conical tip of the liquid discharge bucket is also provided with a liquid discharge pipe.

In an alternative embodiment of the utility model, the outer side of the barrel body in the depth direction is also provided with a barrel outer shell;

the top of the barrel outer shell is fixedly connected with the top of the barrel body, and a gap is formed between the barrel outer shell and the outer side wall of the barrel body in the depth direction.

In an alternative embodiment of the utility model, the barrel outer shell is also movably connected with a supporting base;

the support base comprises a chassis and at least two support columns vertically connected with the chassis;

at least two of the support posts are each adapted to be inserted into a gap; and

and the supporting base is also provided with a limiting clamping groove matched with the liquid discharge pipe in a clamping way.

In an alternative embodiment of the utility model, a positioning component is arranged between each support column and the barrel outer shell; the positioning assembly comprises a plurality of hollow limiting grooves and limiting columns, wherein the hollow limiting grooves are distributed along the axial direction of the barrel body at intervals, and the limiting columns are convexly arranged on the supporting columns and are suitable for being clamped into any hollow limiting groove.

In an alternative embodiment of the present utility model, the tub is made of a transparent material; and

the barrel outer shell is provided with a hollowed-out observation window along the axial direction of the hollow liquid storage cavity, and one side of the hollowed-out observation window is provided with scale marks along the axial direction of the hollow liquid storage cavity.

By adopting the technical scheme, the utility model has the following beneficial effects: according to the electrolyte barrel for reducing the electrolyte residual liquid, the liquid scraping component is arranged in the hollow liquid storage cavity of the barrel body, and scraping of the cavity wall of the hollow liquid storage cavity is realized through the rotary motion of the liquid scraping component, so that the electrolyte residual liquid adhered to the cavity wall of the hollow liquid storage cavity is cleaned, and the electrolyte residual liquid flows to the liquid discharge hopper and is discharged out of the barrel body.

Furthermore, the transverse connecting rod and the pair of longitudinal scraping rods are designed into hollow rod bodies, and then the air pump is matched to accelerate the cleaning speed of electrolyte residual liquid adhered to the cavity wall of the hollow liquid storage cavity through air, and the thoroughness of cleaning the electrolyte residual liquid is improved.

Drawings

FIG. 1 is a schematic view of the overall structure of an electrolyte filtering and storing device of the present utility model;

FIG. 2 is a schematic cross-sectional view of the electrolyte filtration storage device of the present utility model in a cylindrical tube;

FIG. 3 is a schematic view of the drive assembly of the electrolyte filtration storage device of the present utility model;

FIG. 4 is a schematic view showing the structure of the filter plate and the filter funnel of the electrolyte filtering and storing device according to the present utility model.

In the figure: the barrel outer shell 1, the communication area 132, the hollowed-out limit groove 131, the handle 12, the support base 21, the liquid discharge pipe 32, the control valve 33, the limit clamping groove 22, the limit column 23, the support column 2, the seal cabin 4, the scale mark 35, the hollowed-out observation window 34, the barrel body 11, the air pump 41, the air inlet pipe 42, the air outlet pipe 43, the motor 5, the rotating seat 52, the transverse connecting rod 54, the longitudinal scraping rod 55, the air discharge groove 56, the gear 51, the one-way air valve 44, the liquid inlet 31 and the toothed ring 53.

Detailed Description

In order that the utility model may be more readily understood, a more particular description of the utility model will be rendered by reference to specific embodiments that are illustrated in the appended drawings.

Example 1: referring to fig. 1 to 4, the present embodiment provides an electrolyte tank 11 for reducing residual liquid of electrolyte, comprising: the device comprises a barrel body 11 with a hollow liquid storage cavity, a liquid discharge hopper arranged at the bottom of the barrel body 11, a liquid scraping component arranged in the hollow liquid storage cavity, and a driving component arranged at the top of the barrel body 11 and used for driving the liquid scraping component to rotate in the hollow liquid storage cavity to scrape the cavity wall of the hollow liquid storage cavity.

Under this structure, realize scraping to the chamber wall of cavity stock solution chamber through the rotary motion who scrapes the liquid subassembly, so make the clearance of adhesion at the chamber wall electrolyte raffinate in cavity stock solution chamber for electrolyte raffinate flow to the flowing back fill, thereby discharge outside staving 11.

On the basis of the above structure, it can be understood that the top of the tub 11 is further provided with a liquid inlet 31 for inputting electrolyte into the hollow liquid storage chamber. In order to improve the efficiency of removing the residual electrolyte from the barrel body 11, the liquid discharge hopper is preferably in a cone shape; and a drain pipe 32 is further provided at the tapered tip of the drain bucket, and a control valve 33 is disposed on the drain pipe 32 for the purpose of facilitating control of the drain state of the drain pipe 32.

On the basis of the above structure, first, the hollow liquid storage cavity adopted in this embodiment is a cylindrical cavity; the shape of the corresponding integral barrel 11 can also be a cylindrical structure.

Next, the scraping assembly includes a lateral joint rod 54 disposed along an inner diameter direction of the hollow liquid storage chamber and a pair of longitudinal scraping rods 55 respectively connected to both ends of the lateral joint rod 54; the pair of longitudinal scraping rods 55 each extend along the axial direction of the hollow liquid storage chamber so that the pair of longitudinal scraping rods 55 scrape the chamber wall of the hollow liquid storage chamber. The transverse connecting rod 54 and the pair of longitudinal scraper rods 55 form a unitary structure for rotational movement within the hollow reservoir. Based on this structure, the wiper assembly adopts a structure in which the transverse connecting rod 54 and the pair of longitudinal wiper rods 55 are matched, so that the power requirement on the output of the driving assembly can be reduced, and the energy consumption of the driving assembly can be reduced.

Furthermore, the driving assembly used in this embodiment includes a rotating base 52 penetrating the top of the tub 11 and a power structure for driving the rotating base 52 to rotate. The rotary seat 52 can be selected from bearings or directly in rotary engagement with the top of the tub 11. In an alternative embodiment, illustrated in the accompanying drawings, the power structure comprises a toothed ring 53 connected to a rotary seat 52, a gear 51 meshed with the toothed ring 53, and a motor 5 connected to the gear 51. The gear 51 may be engaged with the outer ring gear of the ring gear 53 or the inner ring gear of the ring gear 53, which is not limited in this embodiment.

On the basis of the above structure, the present embodiment can further make the following modifications:

the transverse joint rod 54 and the pair of longitudinal scraper rods 55 are hollow rods; and a cavity formed in the swivel mount 52 for communication with a transverse docking rod 54; a pair of longitudinal scraping rods 55 are provided with exhaust grooves 56 on the side end faces of the cavity walls facing the hollow liquid storage cavity. It should be noted that the air vent 56 is a strip air vent extending along the axial direction of the hollow liquid storage cavity; or the vent groove 56 is a plurality of hole grooves arranged at intervals along the axial direction of the hollow liquid storage cavity. Both of these cases satisfy the use requirements of the present embodiment.

In this configuration, that is to say through the passage of gas into the cavity of the rotary seat 52, the gas can flow through the transverse connecting rod 54 and then into the longitudinal scraper 55, and finally be sprayed onto the wall of the hollow liquid storage chamber through the air discharge slot 56 on the longitudinal scraper 55.

Based on the above structure, considering that the air is convenient to be introduced into the cavity of the steering seat, this embodiment, in combination with the accompanying drawings, exemplifies an alternative implementation case, and makes the following design:

the top of the barrel body 11 is also provided with a sealing bin 4 for covering the rotating seat 52; and the sealing bin 4 is provided with a one-way air valve 44 which is arranged on the rotating seat 52 and communicated with the cavity, and an air outlet pipe 43 connected with the one-way air valve 44; and the air outlet pipe 43 is connected with an air pump 41. It can be understood that the air pump 41 is connected with the air inlet pipe 42, and the embodiment of whether the air pump 41 is arranged in the sealed cabin 4 or outside the sealed cabin 4 is not absolutely limited, so long as the tightness in the sealed cabin 4 can be ensured, the use requirement of introducing air into the rotating seat 52 can be met.

In summary, the transverse connecting rod 54 and the pair of longitudinal scraping rods 55 are designed as hollow rod bodies, and the air pump 41 is matched to accelerate the cleaning speed of electrolyte residual liquid adhered to the cavity wall of the hollow liquid storage cavity through air, and improve the thoroughness of cleaning the electrolyte residual liquid.

Example 2: on the basis of the electrolyte barrel 11 for reducing electrolyte residual liquid in embodiment 1, this embodiment provides an electrolyte barrel 11 for reducing electrolyte residual liquid, and a barrel outer shell 1 is further disposed on the outer side of the depth direction of the barrel 11, where the barrel outer shell 1 may be a cylinder adapted to the barrel shape. The top of the barrel outer shell 1 is fixedly connected with the top of the barrel 11, and a gap is formed between the barrel outer shell 1 and the outer side wall of the barrel 11 in the depth direction.

In more detail, the tub outer casing 1 is also movably connected with a support base 21; the support base 21 comprises a chassis and at least two support columns 2 vertically connected with the chassis; four support columns 2 are optionally adopted in the drawing, and the four support columns 2 are enclosed to form a circular structure, so that the four support columns 2 can be simultaneously inserted into a gap formed by the barrel outer shell 1 and the barrel body 11. With this structure, the tub 11 and the tub outer casing 1 can do not only a lifting movement with respect to the support column 2 but also a rotation movement with respect to the support column 2. The chassis here is used not only for supporting the plurality of support columns 2, but also for supporting the bottom of the tub outer casing 1, that is to say just being mounted on the chassis when the tub outer casing 1 is lowered to the lowest point with respect to the support columns 2.

On the basis of the above structure, the support base 21 is further provided with a limit clamping groove 22 which is in clamping fit with the liquid discharge pipe 32. Under this structure, it should be noted that the limiting slot 22 has an arc structure, so that the liquid drain pipe 32 is convenient to be clamped with the limiting slot 22, and meanwhile, the liquid drain pipe 32 is convenient to be separated from the limiting slot 22. Only when the tub 11 and the tub outer case 1 descend to the lowest point with respect to the support column 2, and the tub outer case 1 is mounted on the chassis, the drain pipe 32 is caught in the limit catch groove 22, and when the tub outer case 1 drives the tub 11 to make an upward movement with respect to the support column 2 together, the drain pipe 32 is disengaged from the limit catch groove 22. The limiting clamping groove 22 is used for limiting the liquid discharge pipe 32, so that the liquid discharge pipe 32 can be supported and protected, and damage caused by false touch in the using process is prevented.

Based on the above, it is considered that in order to facilitate positioning of the tub outer casing 1 and the tub 11 at different positions with respect to the support columns 2, a positioning assembly is provided between each support column 2 and the tub outer casing 1; the positioning component comprises a plurality of hollow limiting grooves 131 and limiting columns 23, wherein the hollow limiting grooves 131 are distributed along the axial direction of the barrel body 11 at intervals, and the limiting columns 23 are convexly arranged on the supporting columns 2 and are suitable for being clamped and embedded into any hollow limiting groove 131. Under this structure, it should be noted that the communicating area 132 is formed at the notch of the plurality of hollow limiting grooves 131, so that the limiting post 23 can move in the communicating area 132 to switch the matching states with different hollow limiting grooves 131. Moreover, when the limiting column 23 moves from the hollow limiting groove 131 to the communication area 132, the barrel 11 and the barrel outer shell 1 do rotary motion relative to the support column 2, and in the process that the limiting column 23 moves along the communication area 132 and is switched to the notch of the different hollow limiting groove 131, the barrel 11 and the barrel outer shell 1 do lifting motion relative to the support column 2.

Furthermore, in order to facilitate the lifting movement of the tub 11 and the tub outer case 1 with respect to the support column 2, a handle 12 is further provided at the top of the tub 11.

Finally, regarding the electrolyte tank 11 for reducing the residual electrolyte liquid in the present embodiment, it may be designed as follows: the barrel body 11 is made of transparent materials; and the barrel outer shell 1 is provided with a hollowed-out observation window 34 along the axial direction of the hollow liquid storage cavity, and one side of the hollowed-out observation window 34 is provided with scale marks 35 along the axial direction of the hollow liquid storage cavity. Under this design, be convenient for through fretwork observation window 34 cooperation scale mark 35 come the height of the electrolyte in the cavity stock solution chamber of real-time observation staving 11.

The foregoing embodiments have been provided for the purpose of illustrating the general principles of the present utility model, and are more fully described herein with reference to the accompanying drawings, in which the principles of the present utility model are shown and described, and in which the general principles of the utility model are defined by the appended claims.

In the description of the present utility model, it should be understood that the terms "orientation" or "positional relationship" are based on the orientation or positional relationship shown in the drawings, and are merely for convenience of description and to simplify the description, rather than to indicate or imply that the apparatus or elements referred to must have a particular orientation, be constructed and operate in a particular orientation, and therefore should not be construed as limiting the utility model.

Claims (10)

1. An electrolyte cartridge for reducing electrolyte residue, comprising: the device comprises a barrel body with a hollow liquid storage cavity, a liquid discharge hopper arranged at the bottom of the barrel body, a liquid scraping assembly arranged in the hollow liquid storage cavity, and a driving assembly arranged at the top of the barrel body and used for driving the liquid scraping assembly to rotate in the hollow liquid storage cavity to scrape the cavity wall of the hollow liquid storage cavity; wherein the method comprises the steps of

The hollow liquid storage cavity is a cylindrical cavity; and

the liquid scraping assembly comprises a transverse connecting rod which is arranged along the inner diameter direction of the hollow liquid storage cavity, and a pair of longitudinal scraping rods which are respectively connected with two ends of the transverse connecting rod;

the pair of longitudinal scraping rods extend along the axial direction of the hollow liquid storage cavity so that the pair of longitudinal scraping rods scrape the cavity wall of the hollow liquid storage cavity.

2. The electrolyte cartridge for reducing electrolyte residual according to claim 1, wherein said drive assembly includes a rotatable seat extending through a top of the cartridge body and a power structure for driving the rotatable seat in rotation.

3. The electrolyte cartridge for reducing electrolyte residual according to claim 2, wherein said power structure comprises a toothed ring coupled to said rotary base, a gear engaged with said toothed ring, and a motor coupled to said gear.

4. The electrolyte cartridge for reducing electrolyte residual according to claim 2 or 3, wherein the transverse joint rod and the pair of longitudinal scraper rods are hollow rod bodies; and

a cavity communicated with the transverse connecting rod is formed in the rotating seat;

and a pair of longitudinal scraping rods are provided with exhaust grooves towards the side end surfaces of the cavity walls of the hollow liquid storage cavity.

5. The electrolyte tank for reducing electrolyte residual liquid according to claim 4, wherein a sealing bin for covering the rotating seat is further arranged at the top of the tank body; and

the sealing bin is provided with a one-way air valve which is arranged on the rotating seat and communicated with the cavity, and an air outlet pipe which is connected with the one-way air valve;

the air outlet pipe is connected with an air pump.

6. The electrolyte tank for reducing electrolyte residual liquid according to claim 1, wherein said drain hopper has a tapered shape; and

the conical tip of the liquid discharge bucket is also provided with a liquid discharge pipe.

7. The electrolyte tank for reducing electrolyte residual liquid according to claim 6, wherein a tank outer case is further provided on the outer side in the depth direction of said tank body;

the top of the barrel outer shell is fixedly connected with the top of the barrel body, and a gap is formed between the barrel outer shell and the outer side wall of the barrel body in the depth direction.

8. The electrolyte tank for reducing electrolyte residual liquid according to claim 7, wherein said tank outer housing is further movably connected with a supporting base;

the support base comprises a chassis and at least two support columns vertically connected with the chassis;

at least two of the support posts are each adapted to be inserted into a gap; and

and the supporting base is also provided with a limiting clamping groove matched with the liquid discharge pipe in a clamping way.

9. The electrolyte tank for reducing electrolyte residual liquid according to claim 8, wherein a positioning component is arranged between each support column and the tank outer shell; the positioning assembly comprises a plurality of hollow limiting grooves and limiting columns, wherein the hollow limiting grooves are distributed along the axial direction of the barrel body at intervals, and the limiting columns are convexly arranged on the supporting columns and are suitable for being clamped into any hollow limiting groove.

10. The electrolyte tank for reducing electrolyte residual liquid according to any one of claims 7 to 9, wherein the tank body is made of transparent material; and

the barrel outer shell is provided with a hollowed-out observation window along the axial direction of the hollow liquid storage cavity, and one side of the hollowed-out observation window is provided with scale marks along the axial direction of the hollow liquid storage cavity.