CN219696542U - Colloid electrolyte cooling mechanism - Google Patents

Abstract

The utility model discloses a colloid electrolyte cooling mechanism, which comprises a transmission cooling assembly, a water storage tank arranged at the bottom of the transmission cooling assembly, a heat dissipation frame fixedly arranged at one side of the water storage tank, and a water pump fixedly arranged at the other side of the water storage tank, wherein the water storage tank is provided with a water inlet and a water outlet; the transmission cooling assembly comprises a transmission barrel, the transmission barrel is provided with a cooling water circulation interlayer, the cooling water circulation interlayer is provided with a water inlet and a water outlet, and the heat dissipation frame is connected with the water outlet of the cooling water circulation interlayer; according to the utility model, the colloid electrolyte is poured into the conveying cylinder, cooling water in the cooling water circulation interlayer continuously absorbs heat to the colloid electrolyte in the conveying process, the cooling water enters the heat dissipation frame for heat dissipation after absorbing the heat, and then the cooling water flows back into the water storage tank, so that the ensured cooling water absorbs heat and dissipates, and the heat dissipation time of the colloid electrolyte cooling mechanism is prolonged.

Description

Colloid electrolyte cooling mechanism

Technical Field

The utility model relates to the technical field of colloid cooling devices, in particular to a colloid electrolyte cooling mechanism.

Background

The colloid lead-acid accumulator is an improvement on the common lead-acid accumulator with liquid electrolyte, and the colloid electrolyte is used for replacing sulfuric acid electrolyte, so that the safety, the storage capacity, the discharge performance, the service life and the like of the colloid lead-acid accumulator are improved compared with those of the common accumulator. The gel lead-acid storage battery adopts gel electrolyte, free liquid exists in the gel lead-acid storage battery, and the gel lead-acid storage battery has large electrolyte capacity, large heat capacity and strong heat dissipation capability under the same volume, so that the phenomenon that the common storage battery is easy to generate thermal runaway can be avoided; the electrolyte concentration is low, and the corrosion effect on the polar plate is weak; the concentration is uniform, and the electrolyte layering phenomenon does not exist.

When the conventional colloid electrolyte cooling mechanism cools the colloid electrolyte, the temperature of cooling water is increased continuously due to the heat absorption effect, so that heat cannot be dissipated for a long time; the heat dissipation effect on the colloidal electrolyte is affected.

Disclosure of Invention

In view of this, the present utility model aims to provide a colloid electrolyte cooling mechanism.

In order to solve the technical problems, the technical scheme of the utility model is as follows: the colloid electrolyte cooling mechanism comprises a transmission cooling assembly, a water storage tank arranged at the bottom of the transmission cooling assembly, a heat dissipation frame fixedly arranged at one side of the water storage tank and a water pump fixedly arranged at the other side of the water storage tank; the transmission cooling assembly comprises a transmission barrel, the transmission barrel is provided with a cooling water circulation interlayer, the cooling water circulation interlayer is provided with a water inlet and a water outlet, and the heat dissipation frame is connected with the water outlet of the cooling water circulation interlayer.

Preferably, the transmission cooling assembly further comprises a screw rod arranged in the transmission cylinder, and a rotating motor arranged on one side of the transmission cylinder.

Preferably, the top of the conveying cylinder is provided with a hopper opening, and the bottom of the conveying cylinder is provided with a discharge opening.

Preferably, the water storage tank comprises a water storage tank body, a water inlet arranged above the water storage tank body, and a water guide slope arranged at the bottom of the water storage tank body.

Preferably, one side of the water storage tank body is communicated with the water pump, and the other side of the water storage tank body is communicated with the heat dissipation frame.

Preferably, the water pump is connected with a water inlet of the cooling water circulation interlayer.

Preferably, the heat dissipation frame comprises a heat dissipation water pipe, a plurality of heat dissipation fins fixedly arranged on the periphery of the heat dissipation water pipe, and fixing plates arranged at the upper end and the lower end of the plurality of heat dissipation fins.

The utility model has the technical effects that: according to the utility model, the colloid electrolyte is poured into the conveying cylinder, cooling water in the cooling water circulation interlayer continuously absorbs heat to the colloid electrolyte in the conveying process, the cooling water enters the heat dissipation frame for heat dissipation after absorbing the heat, and then the cooling water flows back into the water storage tank, so that the ensured cooling water absorbs heat and dissipates, and the heat dissipation time of the colloid electrolyte cooling mechanism is prolonged.

Drawings

FIG. 1 is a block diagram of a gel electrolyte cooling mechanism according to the present utility model;

fig. 2 is a structural view of the heat sink in fig. 1.

Detailed Description

The following detailed description of the utility model is provided in connection with the accompanying drawings to facilitate understanding and grasping of the technical scheme of the utility model.

In this embodiment, it should be understood that the directions or positional relationships indicated by the terms "middle", "upper", "lower", "top", "right", "left", "upper", "back", "middle", etc. are based on the directions or positional relationships shown in the drawings, are merely for convenience of description of the present utility model, and do not indicate or imply that the apparatus or elements referred to must have a specific direction, be configured and operated in a specific direction, and thus should not be construed as limiting the present utility model.

In this embodiment, if not specifically described, the members may be connected or fixed by bolts, pins, or the like, which are commonly used in the prior art, and therefore, the details thereof will not be described in this embodiment.

The utility model provides a colloid electrolyte cooling mechanism, as shown in figure 1, includes transmission cooling module 1, sets up storage water tank 2 of transmission cooling module 1 bottom, storage water tank 2 inside stores the coolant liquid that the cooling colloid electrolyte was used. A heat dissipation frame 3 fixedly arranged at one side of the water storage tank 2, wherein the heat dissipation frame 3 dissipates heat of the cooling liquid after heat absorption; a water pump 4 fixedly arranged on the other side of the water storage tank 2; the water pump 4 pumps the cooling liquid in the water storage tank 2 into the cooling water circulation interlayer 111; the transmission cooling assembly 1 comprises a transmission barrel 11, the transmission barrel 11 is provided with a cooling water circulation interlayer 111, the cooling water circulation interlayer 111 is provided with a water inlet 114 and a water outlet 115, and the heat dissipation frame 3 is connected with the water outlet 115 of the cooling water circulation interlayer 111. The water pump 4 is connected with a water inlet 114 of the cooling water circulation interlayer 111. The cooling water circulation interlayer 111 is connected with the water storage tank 2, the heat dissipation frame 3 and the water pump 4 to form a cooling liquid circulation loop, so that the cooling water can be recycled.

The transmission cooling assembly 1 further comprises a screw rod 13 arranged inside the transmission cylinder 11, and a rotating motor 14 arranged on one side of the transmission cylinder 11. The top of the conveying cylinder 11 is provided with a hopper inlet 112, and the bottom of the conveying cylinder 11 is provided with a discharge outlet 113. The colloidal electrolyte can enter the conveying cylinder 11 from the feeding hopper 112, and the rotating motor 14 rotates the screw rod 13 to slowly convey the colloidal electrolyte to the discharging port 113.

The water storage tank 2 comprises a water storage tank body 21, and a water inlet 22 arranged above the water storage tank body 21, wherein the water inlet 22 is used for adding cooling liquid. A water guiding slope 23 arranged at the bottom of the water storage tank body 21. One side of the water storage tank body 21 is communicated with the water pump 4, and the other side of the water storage tank body 21 is communicated with the heat dissipation frame 3. The water guide slope 23 is used for guiding the cooling liquid to one place, so that the cooling liquid can be conveniently sucked by the water pump 4, and when the cooling liquid is required to be discharged, the cooling liquid can be discharged only by disassembling the water pipe at the joint of the water pump 4 and the water storage tank body 21.

As shown in fig. 2, the heat sink 3 includes a heat dissipation water pipe 31, and the heat dissipation water pipe 31 has a continuously curved shape. A plurality of heat radiation fins 32 fixedly installed at the periphery of the heat radiation water pipe 31, and fixing plates 33 disposed at the upper and lower ends of the plurality of heat radiation fins 32. The heat dissipation fins 32 are used for dissipating heat of the cooling water absorbed by the heat dissipation water pipe 31. The fixing plate 33 fixes the radiator frame 3 to the water storage tank 2.

Working principle: firstly, the colloidal electrolyte enters the conveying cylinder 11 from the feeding hopper 112, and the rotating motor 14 rotates the screw rod 13 to slowly convey the colloidal electrolyte to the discharging port 113.

In this process, the water pump 4 pumps the cooling liquid in the water tank 2 into the cooling water circulation interlayer 111 to absorb heat and cool the colloidal electrolyte, and then the cooling liquid is discharged to the heat dissipation frame 3, the heat dissipation frame 3 dissipates the cooling liquid after absorbing heat, and the heat dissipation frame 3 is returned to the water tank 2.

The utility model has the technical effects that: according to the utility model, the colloid electrolyte is poured into the conveying cylinder, cooling water in the cooling water circulation interlayer continuously absorbs heat to the colloid electrolyte in the conveying process, the cooling water enters the heat dissipation frame for heat dissipation after absorbing the heat, and then the cooling water flows back into the water storage tank, so that the ensured cooling water absorbs heat and dissipates, and the heat dissipation time of the colloid electrolyte cooling mechanism is prolonged.

Of course, the above is only a typical example of the utility model, and other embodiments of the utility model are also possible, and all technical solutions formed by equivalent substitution or equivalent transformation fall within the scope of the utility model claimed.

Claims (7)

1. The colloid electrolyte cooling mechanism comprises a transmission cooling assembly, a water storage tank arranged at the bottom of the transmission cooling assembly, a heat dissipation frame fixedly arranged at one side of the water storage tank and a water pump fixedly arranged at the other side of the water storage tank; the method is characterized in that: the transmission cooling assembly comprises a transmission barrel, the transmission barrel is provided with a cooling water circulation interlayer, the cooling water circulation interlayer is provided with a water inlet and a water outlet, and the heat dissipation frame is connected with the water outlet of the cooling water circulation interlayer.

2. A colloidal electrolyte cooling mechanism as claimed in claim 1, wherein: the transmission cooling assembly further comprises a screw rod arranged in the conveying cylinder, and a rotating motor arranged on one side of the conveying cylinder.

3. A colloidal electrolyte cooling mechanism as claimed in claim 2, wherein: the feeding hopper opening is formed in the top of the conveying cylinder, and the discharging opening is formed in the bottom of the conveying cylinder.

4. A colloidal electrolyte cooling mechanism as claimed in claim 1, wherein: the water storage tank comprises a water storage tank body, a water inlet arranged above the water storage tank body, and a water guide slope arranged at the bottom of the water storage tank body.

5. A colloidal electrolyte cooling mechanism as claimed in claim 4, wherein: one side of the water storage tank body is communicated with the water pump, and the other side of the water storage tank body is communicated with the heat dissipation frame.

6. A colloidal electrolyte cooling mechanism as claimed in claim 1, wherein: the water pump is connected with the water inlet of the cooling water circulation interlayer.

7. A colloidal electrolyte cooling mechanism as claimed in claim 1, wherein: the heat dissipation frame comprises a heat dissipation water pipe, a plurality of heat dissipation fins fixedly arranged on the periphery of the heat dissipation water pipe, and fixing plates fixedly arranged at the upper end and the lower end of the plurality of heat dissipation fins.