CN219024270U - Precise temperature control system for silicone oil synthesis reaction kettle - Google Patents

Abstract

The utility model discloses an accurate temperature control system for a silicone oil synthesis reaction kettle, and particularly relates to the technical field of reaction kettles, which has the technical scheme that: including the reation kettle body, still include: the stirring assembly is used for transmitting heat or cold energy to the inside of the silicone oil, the stirring assembly is arranged in the reaction kettle body, and the heat or cold energy is diffused from inside to outside in the reaction kettle body, so that the temperature in the reaction kettle body is controlled, the temperature control assembly is arranged on the reaction kettle body, and the pneumatic driving assembly capable of operating the stirring assembly by utilizing the flow of gas has the beneficial effects that: the material required by the silicone oil synthesis can be heated and cooled firstly, and because the material is in a stirring state at this time, heat or cold of the material can flow into the reaction kettle body simultaneously, so that the temperature difference between the material required by the silicone oil synthesis and the temperature in the reaction kettle body can be reduced as much as possible, and the accuracy is improved.

Description

Precise temperature control system for silicone oil synthesis reaction kettle

Technical Field

The utility model relates to the field of reaction kettles, in particular to an accurate temperature control system for a silicone oil synthesis reaction kettle.

Background

Because the silicone oil has good hydrophilicity and strong hygroscopicity, has multiple functions of softness, static resistance, wetting and the like, and has wide application in the aspects of fabric softness, simulation finishing, shampoo, daily chemistry and the like.

Since the silicone oil synthesis reaction is an equilibration process, the temperature requirement is high during the silicone oil synthesis reaction. At present, the temperature control system of the silicone oil synthesis reaction kettle basically heats or cools the inner cavity of the reaction kettle, so that the temperature of the inner cavity of the reaction kettle can meet the requirement, but the internal temperature of the silicone oil can not meet the requirement due to the transmissibility of heat or cold, and the temperature difference exists between the internal temperature of the silicone oil synthesis reaction kettle and the temperature of the inner cavity of the reaction kettle, so that the temperature of the silicone oil synthesis reaction kettle can not be accurately controlled. Therefore, the utility model discloses an accurate temperature control system for a silicone oil synthesis reaction kettle.

Disclosure of Invention

Therefore, the utility model provides an accurate temperature control system for a silicone oil synthesis reaction kettle, which aims to solve the existing problems.

In order to achieve the above object, the present utility model provides the following technical solutions: the utility model provides a silicon oil synthesis reation kettle is with accurate temperature control system, includes the reation kettle body, still includes:

the stirring assembly is used for transmitting heat or cold into the silicone oil and is arranged in the reaction kettle body;

a temperature control component for controlling the temperature in the reaction kettle body by diffusing heat or cold from inside to outside in the reaction kettle body, and the temperature control component is arranged on the reaction kettle body;

the pneumatic driving assembly can enable the stirring assembly to operate by utilizing the flow of gas, and the pneumatic driving assembly is arranged on the reaction kettle body.

Further, the stirring assembly includes:

the inner wall of the reaction kettle body is rotationally connected with the hollow pipe through a bearing;

and the inner walls of the two ends of the hollow tube are fixedly provided with a plurality of heat conducting shafts.

Further, the method further comprises the following steps:

an electric drive assembly for electrically operating the stirring assembly;

the electric drive assembly includes:

the servo motor is fixedly arranged on one side of the reaction kettle body;

and the output end of the servo motor is fixedly provided with a rotating shaft.

Further, the electric drive assembly further includes:

the inner wall of the first belt pulley is fixedly provided with a rotating shaft;

the inner wall of the second belt pulley is fixedly provided with a hollow pipe, and the second belt pulley is connected with the first belt pulley through belt transmission.

Further, the temperature control assembly includes:

the air pump is fixedly arranged on one side of the reaction kettle body;

the input end of the air pump is fixedly provided with the first pipeline;

the output end of the air pump is fixedly provided with a second pipeline, and one end of the second pipeline is fixedly provided with a three-way joint;

the first electromagnetic valve is arranged on the second pipeline.

Further, the temperature control assembly further comprises:

the refrigerator is fixedly arranged on one side of the reaction kettle body;

the air outlet end of the refrigerator is fixedly provided with the third pipeline, and one end of the third pipeline is fixedly provided with a three-way joint;

the second electromagnetic valve is arranged on the third pipeline;

and the booster pump is arranged on the third pipeline.

Further, the temperature control assembly further comprises:

one end of the first hard pipe is fixedly provided with a three-way joint;

the other end of the first hard tube is fixedly provided with a second hard tube;

the U-shaped heating pipe is fixedly arranged in the second hard pipe;

the third hard tube, the one end fixed mounting third hard tube of second hard tube, and the one end of third hard tube is equipped with the hollow tube, the one end of third hard tube is rotated through the bearing and is connected in the hollow tube.

Further, the pneumatic drive assembly includes:

the sealing box is fixedly arranged on the other side of the reaction kettle body, and one end of the hollow pipe penetrates through the sealing box;

the inner wall of the wind wheel is fixedly provided with a hollow tube, and the wind wheel is positioned in the inner cavity of the sealing box.

Further, the pneumatic drive assembly further comprises:

one end of the hollow pipe is rotationally connected with the fourth hard pipe through a bearing, one end of the fourth hard pipe is fixedly arranged on the inner wall of the top end of the sealing box, and one end of the fourth hard pipe is positioned on one side of the wind wheel;

and the inner wall of the bottom end of the sealing box is provided with an exhaust hole.

Further, the top inner wall of the reaction kettle body is fixedly provided with a temperature sensor, the top of the reaction kettle body is fixedly provided with a controller, and one end of the controller is connected with an electric driving assembly, a temperature control assembly and the temperature sensor.

The beneficial effects of the utility model are as follows:

1. the stirring assembly is arranged to transfer heat or cold into the silicone oil, and the temperature control assembly is arranged to enable the heat or cold to diffuse from inside to outside in the reaction kettle body, so that the temperature in the reaction kettle body is controlled, and therefore materials required by silicone oil synthesis can be heated and cooled firstly, and because the materials are in a stirring state at this time, the heat or cold can flow into the reaction kettle body at the same time, the temperature difference between the materials required by silicone oil synthesis and the temperature in the reaction kettle body can be reduced as much as possible, and the accuracy is improved;

2. through setting up the flow that pneumatic drive assembly utilized gas and make stirring subassembly operation, have the effect that can avoid relying on electric power to make stirring subassembly carry out the operation all the time, and then can practice thrift the electric quantity to a certain extent.

Drawings

FIG. 1 is a schematic diagram of a front view of a structure provided by the present utility model;

FIG. 2 is a schematic side view of a structure provided by the present utility model;

FIG. 3 is a schematic front view of a temperature control assembly according to the present utility model;

FIG. 4 is a schematic front view of an electric drive assembly according to the present utility model;

FIG. 5 is a schematic front view of a pneumatic drive assembly provided by the present utility model;

fig. 6 is a schematic side view of a pneumatic drive assembly provided by the present utility model.

In the figure: the reaction kettle body 10, the stirring assembly 20, the hollow tube 21, the heat conducting shaft 22, the electric driving assembly 30, the servo motor 31, the rotating shaft 32, the first belt pulley 33, the belt 34, the second belt pulley 35, the temperature control assembly 40, the air pump 41, the first pipeline 42, the second pipeline 43, the first electromagnetic valve 431, the third pipeline 44, the second electromagnetic valve 441, the booster pump 442, the refrigerator 45, the first hard tube 46, the second hard tube 47, the U-shaped heating tube 48, the third hard tube 49, the pneumatic driving assembly 50, the sealing box 51, the wind wheel 52, the fourth hard tube 53, the exhaust hole 54, the temperature sensor 60 and the controller 70.

Detailed Description

The preferred embodiments of the present utility model will be described below with reference to the accompanying drawings, it being understood that the preferred embodiments described herein are for illustration and explanation of the present utility model only, and are not intended to limit the present utility model.

Example 1:

referring to fig. 1-6, the precise temperature control system for the silicone oil synthesis reaction kettle provided by the utility model comprises a reaction kettle body 10, wherein a temperature sensor 60 is fixedly arranged on the inner wall of the top end of the reaction kettle body 10, a controller 70 is fixedly arranged on the top of the reaction kettle body 10, and one end of the controller 70 is connected with an electric driving assembly 30, a temperature control assembly 40 and the temperature sensor 60.

Further comprises: an electric drive assembly 30 for electrically operating the stirring assembly 20;

the electric drive assembly 30 includes: a servo motor 31, a rotating shaft 32, a first belt pulley 33, and a second belt pulley 35;

the servo motor 31 is fixedly arranged on one side of the reaction kettle body 10, the output end of the servo motor 31 is fixedly provided with a rotating shaft 32, the inner wall of the first belt pulley 33 is fixedly provided with the rotating shaft 32, the inner wall of the second belt pulley 35 is fixedly provided with the hollow tube 21, and the second belt pulley 35 and the first belt pulley 33 are in transmission connection through a belt 34, wherein the servo motor 31 adopts a motor without self-locking.

Working principle: the materials required for synthesizing the silicone oil are put into the reaction kettle body 10 through a feed port (not marked in the figure), at this time, the rotating shaft 32 is rotated by the servo motor 31, and when the rotating shaft 32 is rotated, the hollow tube 21 is rotated by the first pulley 33, the second pulley 35 and the belt 34.

Further comprises: a stirring assembly 20 for transferring heat or cold to the inside of the silicone oil, and the stirring assembly 20 is installed in the reaction kettle body 10;

the stirring assembly 20 includes: hollow tube 21, heat conduction shaft 22;

the inner wall of the reaction kettle body 10 is rotationally connected with a hollow pipe 21 through a bearing, and a plurality of heat conducting shafts 22 are fixedly arranged on the inner walls of the two ends of the hollow pipe 21;

working principle: when the hollow tube 21 rotates, the heat conducting shaft 22 is driven to rotate, so that the rotating heat conducting shaft 22 mixes materials required by silicone oil synthesis.

Further comprises: a temperature control assembly 40 for controlling the temperature in the reaction kettle body 10 by diffusing heat or cold from inside to outside in the reaction kettle body 10, wherein the temperature control assembly 40 is installed on the reaction kettle body 10;

the temperature control assembly 40 includes: the air pump 41, the first pipe 42, the second pipe 43, the first electromagnetic valve 431, the refrigerator 45, the third pipe 44, the second electromagnetic valve 441, the booster pump 442, the first hard pipe 46, the second hard pipe 47, the U-shaped heating pipe 48, the third hard pipe 49;

the air pump 41 is fixedly arranged on one side of the reaction kettle body 10, the first pipeline 42 is fixedly arranged at the input end of the air pump 41, the second pipeline 43 is fixedly arranged at the output end of the air pump 41, one end of the second pipeline 43 is fixedly provided with a three-way joint, a first electromagnetic valve 431 is arranged on the second pipeline 43, the refrigerator 45 is fixedly arranged on one side of the reaction kettle body 10, the air outlet end of the refrigerator 45 is fixedly provided with a third pipeline 44, one end of the third pipeline 44 is fixedly provided with a three-way joint, the second electromagnetic valve 441 is arranged on the third pipeline 44, the booster pump 442 is arranged on the third pipeline 44, one end of the first hard pipe 46 is fixedly provided with a three-way joint, the other end of the first hard pipe 46 is fixedly provided with a second hard pipe 47, the U-shaped heating pipe 48 is fixedly arranged in the second hard pipe 47, one end of the second hard pipe 47 is fixedly provided with a third hard pipe 49, one end of the third hard pipe 49 is provided with a hollow pipe 21, and one end of the third hard pipe 49 is rotatably connected in the hollow pipe 21 through a bearing;

working principle: when the temperature in the reaction kettle body 10 needs to be reduced, the controller 70 controls the refrigerator 45, the second electromagnetic valve 441 and the booster pump 442 so that the cold energy generated by the refrigerator 45 flows into the hollow tube 21 through the third pipeline 44, the first hard tube 46, the second hard tube 47 and the third hard tube 49, and the cold energy is transferred to materials required by silicone oil synthesis under the action of the heat conducting shaft 22 until the temperature in the reaction kettle body 10 reaches the required temperature;

when the temperature in the reaction kettle body 10 needs to be increased, the controller 70 controls the air pump 41, the first electromagnetic valve 431 and the U-shaped heating pipe 48 to enable air to flow into the hollow pipe 21 through the first pipeline 42, the second pipeline 43, the first hard pipe 46, the second hard pipe 47 and the third hard pipe 49, so that heat of the air is transferred to materials required by silicone oil synthesis under the action of the heat conducting shaft 22 until the temperature in the reaction kettle body 10 reaches the required temperature;

wherein the controller 70 has the capability to adjust the power of the refrigerator 45 and the U-shaped heating tube 48.

Example 2:

on the basis of embodiment 1, a pneumatic driving assembly 50 capable of operating the stirring assembly 20 by using the flow of gas is provided, and the pneumatic driving assembly 50 is mounted on the reaction kettle body 10;

the pneumatic drive assembly 50 includes: the sealing box 51, the wind wheel 52, the fourth rigid pipe 53 and the exhaust hole 54;

the sealing box 51 is fixedly arranged on the other side of the reaction kettle body 10, one end of the hollow tube 21 penetrates through the sealing box 51, the inner wall of the wind wheel 52 is fixedly provided with the hollow tube 21, the wind wheel 52 is positioned in the inner cavity of the sealing box 51, one end of the hollow tube 21 is rotationally connected with the fourth rigid tube 53 through a bearing, one end of the fourth rigid tube 53 is fixedly arranged on the inner wall of the top end of the sealing box 51, one end of the fourth rigid tube 53 is positioned on one side of the wind wheel 52, and the inner wall of the bottom end of the sealing box 51 is provided with an exhaust hole 54;

working principle: when the temperature in the reaction kettle body 10 is adjusted, the controller 70 turns off the servo motor 31, at this time, air flowing into the hollow tube 21 flows into the sealing box 51 through the fourth hard tube 53, and when the air flows into the sealing box 51, one side of the wind wheel 52 is impacted, so that the wind wheel 52 drives the hollow tube 21 to rotate.

The above description is of the preferred embodiments of the present utility model, and any person skilled in the art may modify the present utility model or make modifications to the present utility model with the technical solutions described above. Therefore, any simple modification or equivalent made according to the technical solution of the present utility model falls within the scope of the protection claimed by the present utility model.

Claims (10)

1. The utility model provides a silicon oil synthesis reation kettle is with accurate temperature control system, includes the reation kettle body (10), its characterized in that: further comprises:

the stirring assembly (20) is used for transmitting heat or cold into the silicone oil, and the stirring assembly (20) is arranged in the reaction kettle body (10);

a temperature control component (40) for controlling the temperature in the reaction kettle body (10) by diffusing heat or cold from inside to outside in the reaction kettle body (10), wherein the temperature control component (40) is arranged on the reaction kettle body (10);

and a pneumatic driving assembly (50) capable of operating the stirring assembly (20) by utilizing the flow of gas, and the pneumatic driving assembly (50) is mounted on the reaction kettle body (10).

2. The precise temperature control system for a silicone oil synthesis reaction kettle according to claim 1, wherein: the stirring assembly (20) comprises:

the inner wall of the reaction kettle body (10) is rotationally connected with the hollow pipe (21) through a bearing;

the inner walls of the two ends of the hollow tube (21) are fixedly provided with a plurality of heat conducting shafts (22).

3. The precise temperature control system for a silicone oil synthesis reaction kettle according to claim 2, wherein: further comprises:

an electric drive assembly (30) for electrically operating the stirring assembly (20);

the electric drive assembly (30) includes:

the servo motor (31) is fixedly arranged on one side of the reaction kettle body (10);

and the rotating shaft (32) is fixedly arranged at the output end of the servo motor (31), and the rotating shaft (32) is fixedly arranged at the output end of the servo motor.

4. A precise temperature control system for a silicone oil synthesis reaction kettle according to claim 3, wherein: the electric drive assembly (30) further includes:

the first belt pulley (33), the inner wall of the first belt pulley (33) is fixedly provided with a rotating shaft (32);

the inner wall of the second belt pulley (35) is fixedly provided with a hollow tube (21), and the second belt pulley (35) is in transmission connection with the first belt pulley (33) through a belt (34).

5. The precise temperature control system for a silicone oil synthesis reaction kettle according to claim 1, wherein: the temperature control assembly (40) includes:

the air pump (41) is fixedly arranged on one side of the reaction kettle body (10);

the input end of the air pump (41) is fixedly provided with the first pipeline (42);

the output end of the air pump (41) is fixedly provided with the second pipeline (43), and one end of the second pipeline (43) is fixedly provided with a three-way joint;

and the first electromagnetic valve (431) is arranged on the second pipeline (43), and the first electromagnetic valve (431) is arranged on the second pipeline.

6. The precise temperature control system for a silicone oil synthesis reaction kettle according to claim 5, wherein: the temperature control assembly (40) further includes:

the refrigerator (45) is fixedly arranged on one side of the reaction kettle body (10);

the air outlet end of the refrigerator (45) is fixedly provided with the third pipeline (44), and one end of the third pipeline (44) is fixedly provided with a three-way joint;

a second electromagnetic valve (441), the second electromagnetic valve (441) being provided on the third pipe (44);

-a booster pump (442), said booster pump (442) being arranged on the third conduit (44).

7. The precise temperature control system for a silicone oil synthesis reaction kettle according to claim 6, wherein: the temperature control assembly (40) further includes:

the first hard pipe (46), one end of the first hard pipe (46) is fixedly provided with a three-way joint;

the second hard tube (47), the other end of the first hard tube (46) is fixedly provided with the second hard tube (47);

the U-shaped heating pipe (48), the U-shaped heating pipe (48) is fixedly arranged in the second hard pipe (47);

and one end of the second hard tube (47) is fixedly provided with the third hard tube (49), one end of the third hard tube (49) is provided with a hollow tube (21), and one end of the third hard tube (49) is rotatably connected in the hollow tube (21) through a bearing.

8. The precise temperature control system for a silicone oil synthesis reaction kettle according to claim 2, wherein: the pneumatic drive assembly (50) comprises:

the sealing box (51) is fixedly arranged on the other side of the reaction kettle body (10), and one end of the hollow tube (21) penetrates through the sealing box (51);

the inner wall of the wind wheel (52) is fixedly provided with the hollow tube (21), and the wind wheel (52) is positioned in the inner cavity of the sealing box (51).

9. The precise temperature control system for a silicone oil synthesis reaction kettle according to claim 8, wherein: the pneumatic drive assembly (50) further comprises:

one end of the hollow pipe (21) is rotationally connected with the fourth hard pipe (53) through a bearing, one end of the fourth hard pipe (53) is fixedly arranged on the inner wall of the top end of the sealing box (51), and one end of the fourth hard pipe (53) is positioned on one side of the wind wheel (52);

the exhaust hole (54) is formed in the inner wall of the bottom end of the sealing box (51), and the exhaust hole (54) is formed in the inner wall of the bottom end of the sealing box.

10. The precise temperature control system for a silicone oil synthesis reaction kettle according to claim 1, wherein: the temperature sensor (60) is fixedly arranged on the inner wall of the top end of the reaction kettle body (10), the controller (70) is fixedly arranged on the top of the reaction kettle body (10), and one end of the controller (70) is connected with the electric driving assembly (30), the temperature control assembly (40) and the temperature sensor (60).

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