CN214398456U - Ternary lithium powder process guipure conveyer - Google Patents

Abstract

The embodiment of the utility model provides a ternary lithium powder process guipure conveyer is related to, include: arranging a metal mesh belt on the surface of the ternary lithium powder-making mesh belt conveyor, wherein the metal mesh belt is arranged into a circle along the running direction of the ternary lithium powder-making mesh belt conveyor; the driving device is arranged on the inner side of the metal mesh belt and drives the metal mesh belt to do circular motion; and the water cooling pipeline is arranged on the inner side of the metal mesh belt and is attached along the metal mesh belt. The utility model discloses an embodiment has installed the water cooling pipeline additional on ternary lithium powder process guipure conveyer, through cooling to the metal mesh belt to indirectly cool off the fused salt, reached the embodiment of the utility model discloses an in-process ternary lithium powder process guipure conveyer just can carry out refrigerated guipure conveyer at the transport ternary lithium fused salt to this reduces the cool time of ternary lithium fused salt, has improved the efficiency of ternary lithium powder process.

Description

Ternary lithium powder process guipure conveyer

Technical Field

The embodiment of the utility model relates to a mesh belt conveyor, in particular to ternary lithium powder process mesh belt conveyor.

Background

At present, in the equipment for preparing the ternary lithium powder, the liquid drops of the ternary lithium raw material after welding need to be cooled, and in the existing cooling process, a mesh belt conveyor is not used for cooling, so that the cooling time is longer, and the existing mesh belt conveyor is usually of a non-water-cooling structure and is not suitable for transporting high-temperature materials. In molten salt plants, only raw materials or finished products that have been cooled are generally transported, with limited use.

SUMMERY OF THE UTILITY MODEL

An embodiment of the utility model aims at providing a ternary lithium powder process guipure conveyer can just can carry out refrigerated guipure conveyer at the in-process of carrying ternary lithium fused salt to this reduces the cool time of ternary lithium fused salt.

In order to achieve the above object, the utility model discloses an embodiment has designed a ternary lithium powder process guipure conveyer, a serial communication port, include:

the metal mesh belt is arranged on the surface of the ternary lithium powder making mesh belt conveyor, and the metal mesh belt is arranged into a circle along the running direction of the ternary lithium powder making mesh belt conveyor;

the driving device is arranged on the inner side of the metal mesh belt and drives the metal mesh belt to do circular motion;

and the water cooling pipeline is arranged on the inner side of the metal mesh belt and is attached to the metal mesh belt.

Further, the metal guipure be cyclic annular setting, the metal guipure include that a plurality of metal chain link strip circulation encircles and constitutes, a plurality of metal chain link strip detain mutually side by side and constitute the metal guipure.

Further, the driving device further includes:

the driving roller is transversely arranged at the annular part of the metal mesh belt, is arranged on the inner side of the metal mesh belt and drives the metal mesh belt to circularly run;

the driving motor is connected with one end of the driving roller through a shaft; the driving motor drives the driving roller to rotate, and drives the metal mesh belt to circularly surround the driving roller to run;

the driven roller is transversely arranged at the ring-shaped position at the other side of the metal mesh belt, the driven roller is arranged at the inner side of the metal mesh belt, and the driven roller rotates in the metal mesh belt.

Further, the water cooling pipeline still includes:

the cooling pipe is arranged in the middle of the water cooling pipeline; the cooling pipes are arranged in a coil pipe type structure in an end-to-end connection mode, and the cooling pipes are of a downward disk type structure;

the cooling pipe is provided with a plurality of cooling fins which penetrate into the cooling fins, the cooling fins are in a vertical sheet structure, and the cooling fins are arranged perpendicular to the cooling pipe;

the heat dissipation integrated chip is arranged on the outer side of the radiating fin and is parallel to the cooling pipe; the heat dissipation integrated chip is arranged in parallel on the cooling pipe; one side of the heat dissipation integrated chip is attached to the metal mesh belt.

Furthermore, one end of the cooling pipe is provided with a cooling water inlet pipe joint; and the other end of the cooling pipe is provided with a cooling water outlet pipe joint.

Preferably, the ternary lithium powder process mesh belt conveyor further comprises:

the metal mesh belt framework is internally provided with a metal mesh belt; the metal mesh belt is positioned within a metal mesh belt frame.

Further, the metal mesh belt frame is of a slide type structure, the metal mesh belt is arranged along the metal mesh belt frame in a laminating mode, and the metal mesh belt is also of a slide type structure in the metal mesh belt frame.

Further, a guide wheel is fixed in the metal mesh belt frame along the edge of the metal mesh belt frame, and the metal mesh belt is limited in the metal mesh belt frame by the guide wheel.

Furthermore, the guide wheel is arranged into two layers on the metal mesh belt frame and respectively fixed on the upper edge of the metal mesh belt frame and the lower edge of the metal mesh belt frame, the metal mesh belt is sleeved on the guide wheel, and one side of the guide wheel clamps the edge of the metal mesh belt.

Further, a support frame is arranged below the metal mesh belt frame, the metal mesh belt frame and the metal mesh belt are fixed on the support frame, the support frame is in a right-angle shape, the metal mesh belt frame is obliquely fixed on the metal mesh belt frame, and a discharge plate is fixed on the upper part of the metal mesh belt frame below the metal mesh belt.

Compared with the prior art, the embodiment of the utility model, installed the water cooling pipeline additional on ternary lithium powder process guipure conveyer, through cooling to the metal guipure to indirectly cool off the fused salt, reached the embodiment of the utility model discloses an in-process ternary lithium powder process guipure conveyer just can carry out refrigerated guipure conveyer at the transport ternary lithium fused salt to this reduces the cool time of ternary lithium fused salt, has improved the efficiency of ternary lithium powder process.

Drawings

Fig. 1 is a schematic structural view of the present invention;

fig. 2 is a schematic left view of the metal mesh belt of the present invention;

fig. 3 is a schematic front view of the metal mesh belt of the present invention at a point a;

fig. 4 is a left side view of the water cooling pipeline of the present invention;

fig. 5 is a schematic front view of the water cooling pipeline of the present invention;

fig. 6 is a schematic left view of the inside of the metal mesh belt frame of the present invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention clearer, the following will explain in detail each embodiment of the present invention with reference to the accompanying drawings. However, it will be appreciated by those of ordinary skill in the art that in various embodiments of the invention, numerous technical details are set forth in order to provide a better understanding of the present application. However, the technical solutions claimed in the claims of the present application can be implemented without these technical details and with various changes and modifications based on the following embodiments.

The utility model discloses a first embodiment relates to a ternary lithium powder process guipure conveyer, as shown in fig. 1, include:

arranging a metal mesh belt 1 on the surface of the ternary lithium powder-making mesh belt conveyor, wherein the metal mesh belt 1 is used for conveying ternary lithium molten salt, and the metal mesh belt 1 is arranged into a circle along the running direction of the ternary lithium powder-making mesh belt conveyor; the metal mesh belt 1 is set to be a circulating structure in the running direction of the ternary lithium powder process mesh belt conveyor, and is conveyed from one end of the ternary lithium powder process mesh belt conveyor to the other end, and the conveying direction in the embodiment is from bottom to top.

The driving device 100 is arranged at the inner side of the metal mesh belt 1, the driving device 100 drives the metal mesh belt 1 to do circular motion, and the driving device 100 drives the metal mesh belt 1; conveying the ternary lithium powder-making mesh belt conveyor from one end to the other end;

the water cooling pipeline 200 is arranged on the inner side of the metal mesh belt 1, the water cooling pipeline 200 is arranged along the metal mesh belt 1 in a laminating mode, the water cooling pipeline 200 can be well cooled to the metal mesh belt 1, the metal mesh belt 1 can be cooled, and ternary lithium fused salt on the metal mesh belt 1 can be indirectly cooled.

Foretell structure provides a ternary lithium powder process guipure conveyer and has utilized and installed water cooling pipeline 200 additional on ternary lithium powder process guipure conveyer, through cooling down to metal mesh belt 1 to the indirect fused salt cools off, has reached the embodiment of the utility model discloses an in-process ternary lithium powder process guipure conveyer just can carry out refrigerated guipure conveyer at the transport ternary lithium fused salt to this reduces the cool time of ternary lithium fused salt, has improved the efficiency of ternary lithium powder process.

As shown in fig. 2 and 3, the metal mesh belt 1 is in an annular arrangement, the metal mesh belt 1 comprises a plurality of metal link strips 11 which are circularly surrounded, the plurality of metal link strips 11 are buckled side by side to form the metal mesh belt 1, the metal mesh belt 1 adopts the metal link strips 11 which are circularly surrounded and the plurality of metal link strips 11 are buckled side by side to form the metal mesh belt 1, ternary lithium molten salt can be well placed on the metal mesh belt 1, and meanwhile, due to the adoption of the structure that the metal link strips 11 are circularly surrounded and the plurality of metal link strips 11 are buckled side by side, the surface of the soft metal mesh belt 1 can be formed, and the conveying structure of the metal mesh belt 1 is favorable for conveying.

As shown in fig. 2 and 3, the driving device 100 according to the present embodiment further includes:

a driving roller 2 is transversely arranged at the annular part of the metal mesh belt 1, the driving roller 2 is arranged at the inner side of the metal mesh belt 1, and the driving roller 2 drives the metal mesh belt 1 to circularly run; the driving roller 2 is arranged in the annular part of the metal mesh belt 1 and is used for driving the metal mesh belt 1 to circularly run, so that the metal mesh belt 1 can convey ternary lithium molten salt from bottom to top;

a driving motor 3 connected with the driving motor 3 through a shaft at one end of the driving roller 2; the driving motor 3 drives the driving roller 3 to rotate, and drives the metal mesh belt 1 to circularly wind the driving roller 2 to run; thus, the motor 3 drives the driving roller 2 to rotate, the driving roller 2 drives the metal mesh belt 1 to circularly rotate around the driving roller 2, and a driving structure of the driving motor 3 is formed.

The metal mesh belt driving device comprises a metal mesh belt 1, and is characterized in that a driven roller 4 is transversely arranged at the annular position on the other side of the metal mesh belt 1, the driven roller 4 is arranged on the inner side of the metal mesh belt 1, the driven roller 4 rotates in the metal mesh belt 1, the driven roller 4 is mainly a part for surrounding the annular position on the other side of the metal mesh belt 1, a driving roller 2 is driven by a motor 3 to rotate, the driving roller 2 drives the metal mesh belt 1 to circularly surround the driving roller 2 to operate, so that the metal mesh belt 1 on the driven roller 4 is driven to circularly operate, and the basic structure of the driving device 100 is formed.

As shown in fig. 4 and 5, the water cooling pipeline 200 further includes:

a cooling pipe 5 is arranged in the middle of the water cooling pipeline 200; the cooling pipes 5 are arranged in a coil pipe type structure in an end-to-end connection mode, and the cooling pipes 5 are in a downward disk type structure; cooling tube 5 sets up at water cooling pipeline 200, has adopted 5 end to end's of cooling tube coil structure, extends downwards along the slope of metal guipure 1 moreover, can cool off metal guipure 1 well, indirectly cools off the fused salt to this reduces the cool time of ternary lithium fused salt, has improved the efficiency of ternary lithium powder process.

The cooling pipe 5 is provided with a radiating fin 6 which penetrates into the cooling fin 6, the radiating fin 6 is of a vertical sheet structure, and the radiating fin 5 is vertical to the cooling pipe 5; the cooling pipe 5 is embedded in the radiating fins 6, so that the radiating fins 6 can be well cooled, the metal mesh belt 1 can be cooled, and the technical effect of indirectly cooling ternary lithium molten salt is achieved.

As shown in fig. 4 and 5, the heat dissipating integrated chip 7 is provided outside the heat dissipating fins 6 in parallel with the cooling pipe 5; the heat dissipation integrated sheet 7 is arranged in parallel with the cooling pipe 5; one side of the heat dissipation integrated chip 7 is attached to the metal mesh belt 1, and the heat dissipation integrated chip 7 is mainly used for transferring heat of ternary lithium molten salt and protecting the cooling pipe 5 and the radiating fins 6 in the operation process of the metal mesh belt 1, so that the cooling pipe 5 and the radiating fins 6 are prevented from being damaged in the operation process of the metal mesh belt 1.

In order to realize the cooling function of the ternary lithium molten salt, cooling water is conveniently introduced, and as shown in fig. 4 and 5, a heat dissipation integrated sheet 7 is arranged on the outer side of the heat dissipation sheet 6 and in parallel with the cooling pipe 5; thus, the heat dissipation integrated chip 7 can transmit the heat of the ternary lithium fused salt, the heat dissipation integrated chip 7 protects the cooling pipe 5 and the radiating fin 6, the cooling pipe 5 and the radiating fin 6 are prevented from being damaged in the running process of the metal mesh belt 1, and the heat dissipation integrated chip 7 is arranged at one end of the cooling pipe 5 in parallel and is provided with a cooling water inlet pipe joint 8; the other end of the cooling pipe 5 is provided with a cooling water outlet pipe joint 9. The cooling water inlet pipe joint 8 and the cooling water outlet pipe joint 9 are used for connecting cooling water, so that the cooling fins 6 and the cooling pipes 5 can be used for cooling.

As shown in fig. 1 and 6, the ternary lithium pulverizing mesh belt conveyor in this embodiment further includes:

a metal mesh belt frame 10, wherein a metal mesh belt 1 is arranged in the frame of the metal mesh belt frame 10; the metal mesh belt 1 is positioned in a metal mesh belt frame 10, the metal mesh belt frame 10 is used for installing and fixing the metal mesh belt 1, and the metal mesh belt 1 runs in the metal mesh belt frame 10 in a circulating mode.

As shown in fig. 1 and 6, the metal mesh belt frame is a slide type structure 10, the metal mesh belt 1 is attached to the metal mesh belt frame 10, the metal mesh belt 1 can be limited in the metal mesh belt frame 10, and meanwhile, the water cooling pipeline 200 can better cool the metal mesh belt 1, so that the cooling effect of the ternary lithium molten salt is ensured. The metal mesh belt 1 is also in a slide type structure in the metal mesh belt frame 10, so that the metal mesh belt 1 can run in the metal mesh belt frame 10 in a fitting manner.

In order to make the metal mesh belt 1 run in the metal mesh belt frame 10 better, as shown in fig. 6, a guide wheel 11 is fixed in the metal mesh belt frame 10 along the edge of the metal mesh belt frame 10, and the guide wheel 11 restrains the metal mesh belt 1 in the metal mesh belt frame 10 1.

As further shown in fig. 6, in order to make the guide wheel 11 fix the metal mesh belt 1 better, the guide wheel 11 is provided with two layers on the metal mesh belt frame 10, and fixed on the upper edge of the metal mesh belt frame 10 and the lower edge of the metal mesh belt frame 10 respectively, the metal mesh belt 1 is sleeved on the guide wheel 11, and one side of the guide wheel 11 blocks the edge of the metal mesh belt 1.

In order to support the metal mesh belt frame 10, as shown in fig. 1, a support frame 12 is arranged below the metal mesh belt frame 10, the metal mesh belt frame 10 and the metal mesh belt 1 are both fixed on the support frame 12, the support frame 12 is in a right-angle shape, so that ternary lithium molten salt is convenient to transport, the metal mesh belt frame 10 is obliquely fixed on the support frame 12, and a discharge plate 13 is fixed above the metal mesh belt frame 10 below one side of the metal mesh belt 1.

It will be understood by those skilled in the art that the foregoing embodiments are specific examples of the invention, and that various changes in form and details may be made therein without departing from the spirit and scope of the invention in its practical application.

Claims (10)

1. The utility model provides a ternary lithium powder process guipure conveyer which characterized in that includes:

the metal mesh belt is arranged on the surface of the ternary lithium powder making mesh belt conveyor, and the metal mesh belt is arranged into a circle along the running direction of the ternary lithium powder making mesh belt conveyor;

the driving device is arranged on the inner side of the metal mesh belt and drives the metal mesh belt to do circular motion;

and the water cooling pipeline is arranged on the inner side of the metal mesh belt and is attached to the metal mesh belt.

2. The ternary lithium pulverizing mesh belt conveyor according to claim 1, wherein the metal mesh belt is arranged in a ring shape, and comprises a plurality of metal chain link strips circularly and circularly arranged, and the metal mesh belt is formed by buckling a plurality of metal chain link strips side by side.

3. The ternary lithium pulverizing mesh belt conveyor of claim 1, wherein the driving device further comprises:

the driving roller is transversely arranged at the annular part of the metal mesh belt, is arranged on the inner side of the metal mesh belt and drives the metal mesh belt to circularly run;

the driving motor is connected with one end of the driving roller through a shaft; the driving motor drives the driving roller to rotate, and drives the metal mesh belt to circularly surround the driving roller to run;

the driven roller is transversely arranged at the ring-shaped position at the other side of the metal mesh belt, the driven roller is arranged at the inner side of the metal mesh belt, and the driven roller rotates in the metal mesh belt.

4. The ternary lithium pulverizing mesh belt conveyor of claim 1, wherein the water cooling pipeline further comprises:

the cooling pipe is arranged in the middle of the water cooling pipeline; the cooling pipes are arranged in a coil pipe type structure in an end-to-end connection mode, and the cooling pipes are of a downward disk type structure;

the cooling pipe is provided with a plurality of cooling fins which penetrate into the cooling fins, the cooling fins are in a vertical sheet structure, and the cooling fins are arranged perpendicular to the cooling pipe;

the heat dissipation integrated chip is arranged on the outer side of the radiating fin and is parallel to the cooling pipe; the heat dissipation integrated chip is arranged in parallel on the cooling pipe; one side of the heat dissipation integrated chip is attached to the metal mesh belt.

5. The ternary lithium pulverizing mesh belt conveyor of claim 4, wherein a cooling water inlet pipe joint is arranged at one end of the cooling pipe; and the other end of the cooling pipe is provided with a cooling water outlet pipe joint.

6. The ternary lithium pulverizing mesh belt conveyor according to any one of claims 1 to 5, further comprising:

the metal mesh belt framework is internally provided with a metal mesh belt; the metal mesh belt is positioned within a metal mesh belt frame.

7. The ternary lithium powder process mesh belt conveyor according to claim 6, wherein the metal mesh belt frame is of a slide structure, the metal mesh belt is attached along the metal mesh belt frame, and the metal mesh belt is also of a slide structure in the metal mesh belt frame.

8. The ternary lithium pulverizing mesh belt conveyor according to claim 7, wherein a guide wheel is fixed in the metal mesh belt frame along the edge of the metal mesh belt frame, and the guide wheel restrains the metal mesh belt in the metal mesh belt frame.

9. The ternary lithium powder process mesh belt conveyor according to claim 8, wherein the guide wheel is arranged on the metal mesh belt frame in two layers, the two layers are respectively fixed on the upper edge of the metal mesh belt frame and the lower edge of the metal mesh belt frame, the metal mesh belt is sleeved on the guide wheel, and one side of the guide wheel clamps the edge of the metal mesh belt.

10. The mesh belt conveyor for ternary lithium powder manufacturing according to claim 9, wherein a support frame is arranged below the metal mesh belt frame, the metal mesh belt frame and the metal mesh belt are fixed on the support frame, the support frame is in a right angle shape, the metal mesh belt frame is obliquely fixed on the support frame, and a discharge plate is fixed below one side of the metal mesh belt and above the metal mesh belt frame.

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