CN222605444U

CN222605444U - Self-cleaning cooling crystallizer

Info

Publication number: CN222605444U
Application number: CN202420606727.3U
Authority: CN
Inventors: 夏凯; 王卫国; 董文林
Original assignee: Henan Jindadi Chemical Industry Co Ltd
Current assignee: Henan Jindadi Chemical Industry Co Ltd
Priority date: 2024-03-27
Filing date: 2024-03-27
Publication date: 2025-03-14
Anticipated expiration: 2034-03-27

Abstract

The utility model discloses a self-cleaning cooling crystallizer which comprises a processing tank body, wherein an adding port is formed in the upper end of the processing tank body, a cooling liquid input pipe and a cooling liquid output pipe are respectively arranged at two ends of the processing tank body, a cooler is arranged between the cooling liquid input pipe and the cooling liquid output pipe, a transmission mechanism is arranged on the side wall of the cooler, a cleaning mechanism is connected onto the transmission mechanism in a transmission manner, a motor is arranged at the upper end of the processing tank body, a stirring mechanism is arranged at the lower end of the processing tank body, the stirring mechanism is in transmission connection with the motor, and a plurality of discharging ports are fixedly connected to the lower end of the processing tank body. The cleaning brush can be driven to rotate through the flowing of the cooling liquid, and the surface of the cooler in the processing tank body is cleaned. The power of the stirring rod is not occupied. Meanwhile, when the cleaning brush is clamped, negative effects on the motor are avoided.

Description

Self-cleaning cooling crystallizer

Technical Field

The utility model relates to the technical field of chemical production, in particular to a self-cleaning cooling crystallizer.

Background

The cooling crystallizer is an important device for further separating out ammonium chloride products in the combined alkali production process and producing raw materials in the carbonization process. Since sodium chloride is unsaturated in half MII produced by the cold-drawn crystallizer and ammonium chloride is saturated, the formation of ammonium chloride can be promoted by adding sodium chloride to the salting-out crystallizer by the homoionic effect. The cooling crystallizer is an important ring in the process of the production of the combined alkali, and the stable operation of the equipment is the key of the load stability in the process of the production of the combined alkali.

Retrieving the prior art, publication number CN106745615A discloses cooling the crystallizer. The cooling crystallization storage tank is a cylindrical barrel body and is arranged on the support, a crystallization liquid inlet pipe and a discharging port are respectively arranged on the upper portion of the cooling crystallization storage tank, an overflow port, a cold fluid outlet and a liquid level meter interface connected with a liquid level meter are respectively arranged on the side wall of the cooling crystallization storage tank, a cleaning port, a cold fluid inlet and a crystal outlet are respectively arranged at the bottom of the cooling crystallization storage tank, the stirring device is arranged on the cooling crystallization storage tank, a frame type stirring paddle of the stirring device is arranged in the cooling crystallization storage tank, a brush capable of contacting with the inner wall of the cooling crystallization storage tank is arranged at the edge of the frame type stirring paddle, the brush can flush the inner wall of the cooling crystallization storage tank, and a crystal outlet stirrer capable of stirring a crystal liquid mixture at the crystal outlet of the cooling crystallization storage tank is arranged at the tail end of a stirring shaft of the stirring device.

In the comparison document, the brush which can be contacted with the inner wall of the cooling crystallization storage tank is arranged at the edge of the frame type stirring paddle, and the brush can wash the inner wall of the cooling crystallization storage tank. The stirring paddle is used for driving the contact hairbrush to clean the inner wall of the crystallization storage tank. The power of the stirring paddle is occupied, so that the rotating speed of the stirring paddle is influenced, and the motor is more likely to be driven to be damaged when the contact hairbrush is blocked.

Disclosure of utility model

The present utility model is directed to a self-cleaning cooling crystallizer to solve the above-mentioned problems.

The utility model provides the technical scheme that the processing tank comprises a processing tank body, wherein an adding port is formed in the upper end of the processing tank body, a cooling liquid input pipe and a cooling liquid output pipe are respectively arranged at two ends of the processing tank body, a cooler is arranged between the cooling liquid input pipe and the cooling liquid output pipe, a transmission mechanism is arranged on the side wall of the cooler, a cleaning mechanism is connected onto the transmission mechanism in a transmission manner, a motor is arranged at the upper end of the processing tank body, a stirring mechanism is arranged at the lower end of the processing tank body, the stirring mechanism is in transmission connection with the motor, and a plurality of discharging ports are fixedly connected to the lower end of the processing tank body.

Preferably, the cooler is tubular, an annular cavity is formed in the pipe wall of the cooler, two ends of the cooler are respectively connected with a cooling liquid input pipe and a cooling liquid output pipe, and the cooling liquid input pipe and the cooling liquid output pipe are communicated with the annular cavity of the cooler.

Preferably, the transmission mechanism comprises a first transmission gear, a first rotary groove is formed in the outer side wall of the cooler, the first transmission gear is arranged in the first rotary groove, the upper end of the first transmission gear is fixedly connected with a transmission shaft, the transmission shaft penetrates through the first rotary groove, the upper end of the transmission shaft is fixedly connected with a second transmission gear, a second rotary groove is formed in the annular cavity of the cooler, and the second rotary groove is matched with the second transmission gear.

Preferably, the cleaning mechanism comprises a driving ring, the inner wall of the driving ring is fixedly connected with driving teeth, the driving teeth are meshed with a second driving gear, the lower end of the driving ring is fixedly connected with a cleaning brush, a gap is formed in the cleaning brush in a shape matched with that of the cooler, and the gap is matched with a cooling liquid input pipe and a cooling liquid output pipe.

Preferably, the upper surface fixedly connected with a plurality of location props of drive ring, the lower surface fixedly connected with a plurality of supporting rollers of location props, a plurality of location props all set up the upper surface at the cooler, the supporting roller is connected with the upper surface of cooler.

Preferably, the stirring mechanism comprises a stirring rod, the stirring rod is attached to the inner wall of the lower end of the processing tank body, a rotating shaft is arranged in the middle of the stirring rod, and the rotating shaft is connected with a motor in a transmission manner.

Compared with the prior art, the utility model has the beneficial effects that the cleaning brush can be driven to rotate by the flowing of the cooling liquid to clean the surface of the cooler in the processing tank body. The power of the stirring rod is not occupied. Meanwhile, when the cleaning brush is clamped, negative effects on the motor are avoided. When the coolant is supplied from the coolant supply pipe to the inside of the cooler, the coolant is moved in the direction of the coolant output pipe. In the process of moving the cooling liquid, the cooling liquid can drive the first transmission gear to rotate. The first transmission gear drives the second transmission gear to rotate through the transmission shaft, and the second transmission gear can drive the transmission ring to rotate. In the process of rotating the transmission ring, the cleaning brush at the lower end of the transmission ring can be driven to clean the surface of the cleaner. When the cleaning brush is clamped, the first transmission gear is clamped along with the cleaning brush, other instruments are not driven to stop running, and the condition of burning out the motor is avoided.

Drawings

FIG. 1 is a schematic perspective view of the present utility model;

FIG. 2 is a schematic diagram of a cooler according to the present utility model;

FIG. 3 is a schematic view showing the internal structure of the drive ring according to the present utility model;

FIG. 4 is a schematic view of a positioning stay structure according to the present utility model;

FIG. 5 is a schematic diagram of a transmission mechanism according to the present utility model;

FIG. 6 is a schematic cross-sectional view of the present utility model.

The device comprises a tank body 1, a processing inlet 2, a cooling liquid input pipe 3, a cooling liquid output pipe 4, a cooler 5, a transmission mechanism 6, a cleaning mechanism 7, a motor 8, a stirring mechanism 9, a stirring mechanism 10, a discharge port 11, a first transmission gear 12, a first rotary groove 13, a transmission shaft 14, a second transmission gear 15, a second rotary groove 16, a transmission ring 17, a transmission gear 18, a cleaning brush 19, a positioning support 20, a supporting roller 21, a stirring rod 22 and a rotary shaft.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Referring to fig. 1-6, embodiments of the present utility model provide:

The embodiment comprises a processing tank body 1, wherein an adding port 2 is arranged at the upper end of the processing tank body 1, and a cooling liquid input pipe 3 and a cooling liquid output pipe 4 are respectively arranged at two ends of the processing tank body 1. A cooler 5 is arranged between the cooling liquid input pipe 3 and the cooling liquid output pipe 4. The cooling liquid flows into the cooler 5 from the cooling liquid input pipe 3 and finally flows out from the cooling liquid output pipe 4, thereby achieving the effect of cooling the inside of the processing tank body 1. The side wall of the cooler 5 is provided with a transmission mechanism 6, and the transmission mechanism 6 is connected with a cleaning mechanism 7 in a transmission way. The transmission mechanism 6 can transmit power to the cleaning mechanism 7 to drive the cleaning mechanism 7 to work. The upper end of the processing tank body 1 is provided with a motor 8, the lower end inside the processing tank body 1 is provided with a stirring mechanism 9, the stirring mechanism 9 is in transmission connection with the motor 8, and the lower end of the processing tank body 1 is fixedly connected with a plurality of discharge ports 10. The plurality of discharge ports 10 can be connected with a plurality of discharge pipes simultaneously for constituting a pipe network.

The cooler 5 is tubular, an annular cavity is formed in the pipe wall of the cooler 5, two ends of the cooler 5 are respectively connected with the cooling liquid input pipe 3 and the cooling liquid output pipe 4, and the cooling liquid input pipe 3 and the cooling liquid output pipe 4 are communicated with the annular cavity of the cooler 5. The cooling liquid is input into the annular cavity of the cooler 5 through the cooling liquid input pipe 3, and finally flows out through the cooling liquid output pipe 4, so that the temperature inside the processing tank body 1 can be reduced for crystallization.

The transmission mechanism 6 comprises a first transmission gear 11, a first rotary groove 12 is formed in the outer side wall of the cooler 5, and the first transmission gear 11 is arranged in the first rotary groove 12. The movement of the coolant in the cooler 5 can bring the first transmission gear 11 into rotation. The upper end of the first transmission gear 11 is fixedly connected with a transmission shaft 13, the transmission shaft 13 penetrates through the first rotary groove 12, and the upper end of the transmission shaft 13 is fixedly connected with a second transmission gear 14. The first transmission gear 11 can drive the second transmission gear 14 to rotate through the transmission shaft 13. A second rotary groove 15 is arranged in the annular cavity of the cooler 5, and the second rotary groove 15 is matched with the second transmission gear 14.

The cleaning mechanism 7 comprises a driving ring 16, the inner wall of the driving ring 16 is fixedly connected with driving teeth 17, the driving teeth 17 are meshed with a second driving gear 14, the lower end of the driving ring 16 is fixedly connected with a cleaning brush 18, the shape of the cleaning brush 18 is matched with that of the cooler 5, a gap is formed in the cleaning brush 18, and the gap is matched with the cooling liquid input pipe 3 and the cooling liquid output pipe 4.

The upper surface fixedly connected with a plurality of location props 19 of drive ring 16, the lower surface fixedly connected with a plurality of supporting roller shafts 20 of location props 19, a plurality of location props 19 all set up the upper surface at the cooler 5, supporting roller shafts 20 are connected with the upper surface of cooler 5. The support rollers 20 reduce the friction between the positioning struts 19 and the cooler 5, facilitating the rotation of the drive ring 16.

The stirring mechanism 9 comprises a stirring rod 21, the stirring rod 21 is attached to the inner wall of the lower end of the processing tank body 1, a rotating shaft 22 is arranged in the middle of the stirring rod 21, and the rotating shaft 22 is in transmission connection with the motor 8.

During the processing of the processing tank 1, the liquid to be processed is added into the processing tank 1 from the upper adding port 2, and then the cooling liquid is input through the cooling liquid input pipe 3. When the coolant is supplied from the coolant supply pipe 3 to the inside of the cooler 5, the coolant is moved in the direction of the coolant output pipe 4. During the movement of the cooling liquid, the cooling liquid drives the first transmission gear 11 to rotate. The first transmission gear 11 drives the second transmission gear 14 to rotate through the transmission shaft 13, and the second transmission gear 14 can drive the transmission ring 16 to rotate. During the rotation of the drive ring 16, the cleaning brush 18 at the lower end of the drive ring 16 can be driven to clean the surface of the cleaner. When the cleaning brush 18 is jammed, the first transmission gear 11 is jammed therewith, and other instruments are not driven to stop running. The motor 8 drives the stirring rod 21 to rotate through the rotating shaft 22, and drives the raw materials in the processing tank body 1 to rotate. The slurry after the processing is discharged from a plurality of discharge ports 10 at the lower end of the processing tank 1.

It will be evident to those skilled in the art that the utility model is not limited to the details of the foregoing illustrative embodiments, and that the present utility model may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are, therefore, to be considered in all respects as illustrative and not restrictive, the scope of the utility model being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Claims

1. The self-cleaning cooling crystallizer comprises a processing tank body (1) and is characterized in that an adding port (2) is formed in the upper end of the processing tank body (1), a cooling liquid input pipe (3) and a cooling liquid output pipe (4) are respectively arranged at two ends of the processing tank body (1), a cooler (5) is arranged between the cooling liquid input pipe (3) and the cooling liquid output pipe (4), a transmission mechanism (6) is arranged on the side wall of the cooler (5), a cleaning mechanism (7) is connected to the transmission mechanism (6) in a transmission mode, a motor (8) is arranged at the upper end of the processing tank body (1), a stirring mechanism (9) is arranged at the lower end of the inside of the processing tank body (1), the stirring mechanism (9) is in transmission connection with the motor (8), and a plurality of discharge ports (10) are fixedly connected to the lower end of the processing tank body (1).

2. The self-cleaning cooling crystallizer as in claim 1, wherein the cooler (5) is tubular, an annular cavity is formed in the pipe wall of the cooler (5), two ends of the cooler (5) are respectively connected with the cooling liquid input pipe (3) and the cooling liquid output pipe (4), and the cooling liquid input pipe (3) and the cooling liquid output pipe (4) are communicated with the annular cavity of the cooler (5).

3. The self-cleaning cooling crystallizer as in claim 2, wherein the transmission mechanism (6) comprises a first transmission gear (11), a first rotary groove (12) is formed in the outer side wall of the cooler (5), the first transmission gear (11) is arranged in the first rotary groove (12), the upper end of the first transmission gear (11) is fixedly connected with a transmission shaft (13), the transmission shaft (13) penetrates through the first rotary groove (12), the upper end of the transmission shaft (13) is fixedly connected with a second transmission gear (14), a second rotary groove (15) is formed in the annular cavity of the cooler (5), and the second rotary groove (15) is matched with the second transmission gear (14).

4. The self-cleaning cooling crystallizer as in claim 3, wherein the cleaning mechanism (7) comprises a driving ring (16), the inner wall of the driving ring (16) is fixedly connected with a driving tooth (17), the driving tooth (17) is meshed with a second driving gear (14), the lower end of the driving ring (16) is fixedly connected with a cleaning brush (18), the shape of the cleaning brush (18) is matched with that of the cooler (5), and a notch is formed in the cleaning brush (18) and is matched with the cooling liquid input pipe (3) and the cooling liquid output pipe (4).

5. The self-cleaning cooling crystallizer as in claim 4, wherein the upper surface of the transmission ring (16) is fixedly connected with a plurality of positioning supports (19), the lower surface of the positioning supports (19) is fixedly connected with a plurality of supporting rollers (20), the positioning supports (19) are all arranged on the upper surface of the cooler (5), and the supporting rollers (20) are connected with the upper surface of the cooler (5).

6. The self-cleaning cooling crystallizer as in claim 5, wherein the stirring mechanism (9) comprises a stirring rod (21), the stirring rod (21) is attached to the inner wall of the lower end of the processing tank body (1), a rotating shaft (22) is arranged in the middle of the stirring rod (21), and the rotating shaft (22) is in transmission connection with the motor (8).