CN220164769U - High-capacity electrolyte heat-preserving container - Google Patents

Abstract

The utility model relates to the technical field of heat preservation containers, and provides a high-capacity electrolyte heat preservation barrel which comprises an inner shell and an outer shell which are similar in shape and are sleeved with each other; the inner shell comprises a cylindrical inner shell body which is vertically arranged; the top port of the inner cylinder body is connected with an end socket with an ellipsoidal shape, and the bottom port of the inner cylinder body is connected with a disk-shaped bottom plate; the bottom surface of the bottom plate is fixedly provided with a reinforcing component. The present utility model thus ensures compressive strength by employing a bottom plate structure with reinforcing components. Compared with the existing barrel body structure, when the barrel heights are the same, the capacity is effectively increased, and the electrolyte transportation quantity of a bicycle is improved; when the capacities are the same, the barrel height is effectively reduced, and the multi-layer stacking is convenient.

Description

High-capacity electrolyte heat-preserving container

Technical Field

The utility model belongs to the technical field of heat preservation containers, and particularly relates to a high-capacity electrolyte heat preservation barrel.

Background

The storage and transportation of the electrolyte requires special containers. Referring to fig. 1, the structure of the existing electrolyte storage barrel is basically a cylindrical section 10 with two open ends, and two ports of the cylindrical section 10 are respectively connected with a seal head 11 with a spherical structure, based on the consideration that the inside of the barrel needs to bear larger pressure. The seal head 11 is designed into a spherical structure, and meets the strength requirement on the premise of not increasing the wall thickness.

Although the existing storage barrel can meet the strength requirement of bearing, compared with a cylindrical structure, the storage barrel has more dead space of a spherical structure, and the capacity is reduced.

In summary, it is clear that the prior art has inconvenience and defects in practical use, so that improvement is needed.

Disclosure of Invention

In view of the above drawbacks, the present utility model ensures compressive strength by employing a bottom plate structure with reinforcing members. Compared with the existing barrel body structure, when the barrel heights are the same, the capacity is effectively increased, and the electrolyte transportation quantity of a bicycle is improved; when the capacities are the same, the barrel height is effectively reduced, and the multi-layer stacking is convenient.

In order to solve the problems, the utility model provides a high-capacity electrolyte heat-preserving barrel, which comprises an inner shell and an outer shell which are similar in shape and are sleeved with each other; the inner shell comprises a cylindrical inner shell body which is vertically arranged; the top port of the inner cylinder body is connected with an end socket with an ellipsoidal shape, and the bottom port of the inner cylinder body is connected with a disk-shaped bottom plate; the bottom surface of the bottom plate is fixedly provided with a reinforcing component.

According to the high-capacity electrolyte heat-insulating barrel, the reinforcing component comprises a plurality of reinforcing plates which are fixedly arranged on the bottom plate in parallel; the two ends of the reinforcing plate do not exceed the boundary of the bottom plate.

According to the high-capacity electrolyte heat-insulating barrel, the reinforcing component comprises a transverse pipe group and a longitudinal pipe group which are mutually arranged in a 90-degree crossed mode; the transverse tube group comprises at least two transverse reinforcing tubes which are arranged in parallel; the longitudinal tube group comprises at least two longitudinal reinforced tubes which are arranged in parallel.

According to the high-capacity electrolyte heat-insulating barrel, the top of the seal head is provided with a main pipeline; the pipe body of the main pipe penetrates through the outer shell, and the pipe outlet is fixedly connected with the main flange plate; two sides of the main pipeline are respectively provided with an auxiliary pipeline; the pipe body of the auxiliary pipe penetrates through the outer shell, and the pipe outlet is fixedly connected with an auxiliary flange plate; the bottom plate is provided with a liquid discharge pipe; the pipe body of the liquid discharge pipe penetrates through the outer shell, and a liquid discharge valve is arranged at the pipe orifice.

According to the high-capacity electrolyte heat-insulating barrel, the base plate and the horizontal plane form an inclination angle of 1-3 degrees; the drain pipe is arranged at one end of the bottom plate which is inclined downwards.

According to the high-capacity electrolyte heat-insulating barrel, the liquid inlet component extending into the inner shell is inserted into the main flange plate; the liquid inlet component comprises a straight pipe penetrating through the main flange plate and inserted into the inner shell, and the straight pipe is also connected with a U-shaped pipe; two pipe orifices of the U-shaped pipe are respectively connected with a liquid inlet valve and a liquid outlet valve.

In summary, the present utility model ensures compressive strength by employing a bottom plate structure with reinforcing components. Compared with the existing barrel body structure, when the barrel heights are the same, the capacity is effectively increased, and the electrolyte transportation quantity of a bicycle is improved; when the capacities are the same, the barrel height is effectively reduced, and the multi-layer stacking is convenient.

Drawings

FIG. 1 is a schematic diagram of a prior art structure;

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

FIG. 3 is a schematic view of the structure of one embodiment in the direction A in FIG. 2;

FIG. 4 is a schematic view of another embodiment of the direction A in FIG. 2;

FIG. 5 is a schematic view of the structure of the insulating bucket of the present utility model;

FIG. 6 is a schematic view of the structure in the direction A in FIG. 5;

FIG. 7 is a schematic view of the structure of the fluid inlet and outlet assembly of the present utility model;

FIG. 8 is a schematic view of the structure of the wash tube and sampling tube of the present utility model;

FIG. 9 is a schematic view of a stacked configuration of the frame of the present utility model;

in the figure: 1-an inner shell, 10-a cylindrical section, 11-a sealing head, 12-a main flange, 13-an auxiliary flange, 14-a bottom plate, 15-a liquid discharge pipe, 16-a reinforcing plate, 17-a transverse reinforcing pipe and 18-a longitudinal reinforcing pipe; 2-a shell cylinder, 21-a reinforcing plate, 22-a supporting leg, 23-a vent pipe, 24-a liquid level meter, 25-a cleaning pipe and 251-a spray head; 26-sampling tube, 27-safety valve, 28-U-shaped tube and 281-straight tube; 3-frame body, 31-lug.

Detailed Description

Referring to fig. 5, the utility model provides a high-capacity electrolyte heat-insulating barrel, which comprises an inner shell 1 and an outer shell 2 which are similar in shape and are sleeved with each other; referring to fig. 2 again, the inner shell 1 includes a cylindrical inner shell body disposed vertically; the top port of the inner cylinder body is connected with a seal head 11 with an ellipsoidal shape, and the bottom port is connected with a disk-shaped bottom plate 14; a reinforcing component is fixedly arranged on the bottom surface of the bottom plate 14;

referring to fig. 3, as an example, the reinforcement assembly of the present utility model includes a plurality of reinforcement plates 16 secured in parallel to a base plate 14; the two ends of the reinforcing plate 16 do not exceed the boundary of the bottom plate 14; the thickness and height of the reinforcing plate 16 can be adaptively selected by those skilled in the art according to the diameter specification of the cylinder, thereby securing the deformation resistance of the bottom plate 14.

Referring to fig. 4, as an example, the reinforcement assembly of the present utility model includes a transverse tube group and a longitudinal tube group disposed at 90 ° intersections with each other; the transverse tube group comprises at least two transverse reinforced tubes 17 which are arranged in parallel; the longitudinal tube group comprises at least two longitudinal reinforcing tubes 18 arranged in parallel; the cross tube sets and the longitudinal tube sets are arranged in a crossing manner to divide the bottom plate 14 into a plurality of small areas, so that the deformation resistance of the bottom plate 14 is improved.

The top of the seal head 11 is provided with a main pipeline; the pipe body of the main pipe penetrates through the outer shell tube 2, and the outlet of the main pipe is fixedly connected with the main flange plate 12; two sides of the main pipeline are respectively provided with an auxiliary pipeline; the pipe body of the auxiliary pipe penetrates through the outer shell tube 2, and the pipe outlet is fixedly connected with an auxiliary flange plate 13; a liquid discharge pipe 15 is arranged on the bottom plate 14; the pipe body of the liquid discharge pipe 15 passes through the outer shell barrel 2, and a liquid discharge valve is arranged at the pipe orifice;

the waste liquid or cleaning liquid in the cartridge can be discharged through the liquid discharge pipe 15. Preferably, the bottom plate 14 of the present utility model is inclined at an angle of 1-3 ° to the horizontal; the liquid discharge pipe 15 is arranged at one end of the bottom plate 14 obliquely downward; so that the waste liquid can be completely discharged.

The joint parts of the main pipeline, the auxiliary pipeline and the drain pipe body and the outer shell barrel 2 are in sealing connection.

Referring to fig. 6, the main flange 12 is inserted with a liquid inlet component extending into the inner shell 1; referring to fig. 7, the liquid inlet assembly includes a straight tube 281 penetrating the main flange 12 and inserted into the inner shell 1, and the straight tube 281 is further connected to a U-shaped tube 28; the two pipe orifices of the U-shaped pipe 28 are respectively connected with a liquid inlet valve and a liquid outlet valve;

the utility model adopts the design of a U-shaped pipe 28, and a liquid inlet valve and a liquid outlet valve of two pipe orifices are respectively connected with a liquid inlet pipeline and a liquid outlet pipeline. The liquid inlet process and the liquid outlet process are separately and independently carried out, so that the pipeline is prevented from being detached and replaced during liquid inlet and liquid outlet.

Preferably, the main flange 12 is also provided with a level gauge 24; for monitoring the liquid level in the tub.

Further, referring to fig. 8, a cleaning tube 25 and a sampling tube 26 extending into the inner shell 1 are inserted into one of the auxiliary flanges 13;

in the empty state, cleaning liquid can be introduced into the inner shell from the cleaning pipe 25 to clean the wall of the inner shell 1. Preferably, the end of the cleaning pipe 25 extending into the inner shell 1 is connected with a spherical sprinkler head 251, and water spraying holes are uniformly distributed on the sprinkler head 251; so that the cleaning liquid can be uniformly sprayed in all directions.

In the loaded state, the liquid in the cartridge can be extracted from the sampling tube 26 for detection, and the quality of the stored electrolyte can be judged.

The other auxiliary flange 13 is provided with a safety valve 27, and when the pressure in the cylinder is too high, the safety valve 27 is opened to release pressure. Preferably, a vent pipe 23 extending into the inner shell 1 is also inserted;

when liquid is fed, the vent pipe 23 is opened to discharge air in the cylinder, so that liquid is smoothly fed;

during liquid discharging, nitrogen is introduced from the vent pipe 23 to increase the pressure in the cylinder, and the electrolyte is extruded from the liquid outlet of the U-shaped pipe 28.

Better, a hollow interlayer is formed between the inner shell 1 and the outer shell 2, and vacuum pumping is performed in the interlayer to improve the heat preservation effect.

Referring to fig. 9, as an embodiment, the utility model further comprises a frame 3, and the outer shell 2 is placed in the frame 3, so that the heat-preserving barrel is convenient to transport and stack in multiple layers. Further, a plurality of lifting lugs 31 are fixedly arranged on the frame body 3; is convenient for integral hoisting, stacking or loading and unloading.

More preferably, a plurality of reinforcing plates 21 are fixedly arranged on the outer wall of the shell barrel 2, and each reinforcing plate 21 is fixedly connected with a supporting leg 22; is convenient for fixing and placing on the frame body 3.

In summary, the present utility model provides a high-capacity electrolyte thermal insulation barrel, which ensures compressive strength by adopting a bottom plate structure with a reinforcing component. Compared with the existing barrel body structure, when the barrel heights are the same, the capacity is effectively increased, and the electrolyte transportation quantity of a bicycle is improved; when the capacities are the same, the barrel height is effectively reduced, and the multi-layer stacking is convenient.

Of course, the present utility model is capable of other various embodiments and its several details are capable of modification and variation in light of the present utility model, as will be apparent to those skilled in the art, without departing from the spirit and scope of the utility model as defined in the appended claims.

Claims (6)

1. The high-capacity electrolyte heat-insulating barrel is characterized by comprising an inner shell and an outer shell which are similar in shape and are sleeved with each other; the inner shell comprises a cylindrical inner shell body which is vertically arranged; the top port of the inner cylinder body is connected with an end socket with an ellipsoidal shape, and the bottom port of the inner cylinder body is connected with a disk-shaped bottom plate; the bottom surface of the bottom plate is fixedly provided with a reinforcing component.

2. The high-capacity electrolyte thermal insulation can as claimed in claim 1, wherein the reinforcement assembly comprises a plurality of reinforcement plates fixed on the bottom plate in parallel; the two ends of the reinforcing plate do not exceed the boundary of the bottom plate.

3. The high-capacity electrolyte thermal insulation can as claimed in claim 1, wherein the reinforcement assembly comprises a transverse tube group and a longitudinal tube group which are disposed to cross each other at 90 °; the transverse tube group comprises at least two transverse reinforcing tubes which are arranged in parallel; the longitudinal tube group comprises at least two longitudinal reinforced tubes which are arranged in parallel.

4. A high capacity electrolyte insulating bucket as claimed in any one of claims 1 to 3, wherein a main pipe is provided at the top of the head; the pipe body of the main pipe penetrates through the outer shell, and the pipe outlet is fixedly connected with the main flange plate; two sides of the main pipeline are respectively provided with an auxiliary pipeline; the pipe body of the auxiliary pipe penetrates through the outer shell, and the pipe outlet is fixedly connected with an auxiliary flange plate; the bottom plate is provided with a liquid discharge pipe; the pipe body of the liquid discharge pipe penetrates through the outer shell, and a liquid discharge valve is arranged at the pipe orifice.

5. The high-capacity electrolyte heat-insulating bucket according to claim 4, wherein the bottom plate forms an inclination angle of 1-3 degrees with the horizontal plane; the drain pipe is arranged at one end of the bottom plate which is inclined downwards.

6. The high-capacity electrolyte heat-insulating barrel as claimed in claim 4, wherein the main flange is inserted with a liquid inlet component extending into the inner shell; the liquid inlet component comprises a straight pipe penetrating through the main flange plate and inserted into the inner shell, and the straight pipe is also connected with a U-shaped pipe; two pipe orifices of the U-shaped pipe are respectively connected with a liquid inlet valve and a liquid outlet valve.