CN221714269U - Reation kettle control by temperature change mechanism for catalyst production - Google Patents

Abstract

The utility model relates to the field of chemical technology, and specifically to a temperature control mechanism for a reactor for catalyst production, comprising a side plate 1 and a side plate 2, a plurality of connecting seats are arranged between the side plate 1 and the side plate 2, a connecting plate 1 is arranged at the top of the side plate 1, a connecting plate 2 is arranged at the top of the side plate 2, a top seat is arranged between the tops of the connecting plate 1 and the connecting plate 2, a connecting pipe is arranged at the top of the top seat, a liquid inlet pipe 1 and a liquid inlet pipe 2 are arranged at the other end of the connecting pipe through a tee, a valve 1 is arranged on the outer wall of the connecting pipe, a support plate 1 is arranged at the bottom end of the side plate 1, a support plate 2 is arranged at the bottom end of the side plate 2, and a bottom plate is arranged between the bottom ends of the support plate 1 and the support plate 2. The utility model adopts the method of installing a temperature control device inside the reactor body, and cooperating with a stirring mechanism to perform rapid and uniform temperature control operations on the materials in the reactor body, thereby improving the efficiency and effect of temperature control, increasing the practicality of the reactor, and better meeting the actual production and processing needs.

Description

A temperature control mechanism for a reactor used in catalyst production

Technical Field

The utility model relates to the technical field of chemical engineering, in particular to a temperature control mechanism for a reaction kettle used in catalyst production.

Background Art

A reactor is broadly understood as a container for physical or chemical reactions. Through the structural design and parameter configuration of the container, the heating, evaporation, cooling and low-speed mixing functions required by the process are achieved. Reactors are widely used in the fields of petroleum, chemical industry, rubber, pesticides, dyes, medicines and food.

Currently, most of the reactors on the market are not conducive to uniform temperature control operations. The temperature control medium is set on the periphery of the reactor body, the temperature control efficiency of the material inside the reactor body is low, and the heat exchange and cooling technology have certain deficiencies, which have a certain impact on use.

Therefore, in view of the above problems, the existing temperature control mechanism of the reactor needs to be improved.

Utility Model Content

In order to solve the above problems, the utility model designs a temperature control mechanism for a reaction kettle used in catalyst production.

In order to achieve the above technical objectives and the above technical effects, the present invention is implemented through the following technical solutions:

A temperature control mechanism for a reactor for catalyst production comprises a side plate 1 and a side plate 2, a plurality of connecting seats are arranged between the side plate 1 and the side plate 2, a connecting plate 1 is arranged at the top end of the side plate 1, a connecting plate 2 is arranged at the top end of the side plate 2, a top seat is arranged between the top ends of the connecting plate 1 and the connecting plate 2, a connecting pipe is arranged at the top end of the top seat, a liquid inlet pipe 1 and a liquid inlet pipe 2 are respectively arranged at the other end of the connecting pipe through a tee, a valve 1 is arranged on the outer wall of the connecting pipe, a support plate 1 is arranged at the bottom end of the side plate 1, a support plate 2 is arranged at the bottom end of the side plate 2, a bottom plate is arranged between the bottom ends of the support plate 1 and the support plate 2, a drain pipe is arranged at the bottom end of the bottom plate, and a valve 2 is arranged on the outer wall of the drain pipe.

Furthermore, the number of the connecting seats in each group is two, and they are arranged with a gap between the side plate 1 and the side plate 2 from top to bottom.

Furthermore, the connecting seat is composed of left and right rod bodies and a semicircular plate in the middle.

Furthermore, the centers of the connecting seat, the top seat and the bottom plate are located on the same vertical line.

Furthermore, the connecting pipe, the top seat, the connecting plate 1, the side plate 1, the connecting seat, the side plate 2, the supporting plate 2, the bottom plate and the drain pipe are connected to each other.

The beneficial effects of the utility model are:

The utility model adopts a temperature control device installed inside the kettle body. The temperature control device adopts two side plates and a middle connecting mechanism. Cold and hot media flow from one side plate into the other side plate through the middle connecting mechanism, and uniform temperature control operations are performed on the middle and the outer side. The stirring mechanism is cooperated to perform rapid and uniform temperature control operations on the materials in the kettle body, thereby improving the efficiency and effect of temperature control, increasing the practicability of the reactor, and better meeting actual production and processing needs.

BRIEF DESCRIPTION OF THE DRAWINGS

In order to more clearly illustrate the technical solutions of the embodiments of the utility model, the drawings required for describing the embodiments are briefly introduced below. Obviously, the drawings described below are only some embodiments of the utility model. For ordinary technicians in this field, other drawings can be obtained based on these drawings without creative work.

Fig. 1 is a schematic diagram of the structure of the utility model.

In the accompanying drawings, the components represented by the reference numerals are listed as follows:

1. Side panel one, 2. Side panel two, 3. Connecting seat, 4. Connecting plate one, 5. Connecting plate two, 6. Top seat, 7. Connecting pipe, 8. Liquid inlet pipe one, 9. Liquid inlet pipe two, 10. Valve one, 11. Support plate one, 12. Support plate two, 13. Bottom plate, 14. Drain pipe, 15. Valve two.

DETAILED DESCRIPTION

The following will be combined with the drawings in the embodiments of the utility model to clearly and completely describe the technical solutions in the embodiments of the utility model. Obviously, the described embodiments are only part of the embodiments of the utility model, not all of the embodiments. Based on the embodiments of the utility model, all other embodiments obtained by ordinary technicians in this field without creative work are within the scope of protection of the utility model.

Referring to FIG. 1-1, a temperature control mechanism for a reactor for catalyst production comprises a side plate 1 and a side plate 2, a plurality of connecting seats 3 are arranged between the side plate 1 and the side plate 2, a connecting plate 4 is arranged at the top of the side plate 1, a connecting plate 5 is arranged at the top of the side plate 22, a top seat 6 is arranged between the tops of the connecting plates 14 and 25, a connecting pipe 7 is arranged at the top of the top seat 6, a liquid inlet pipe 18 and a liquid inlet pipe 2 9 are respectively arranged at the other end of the connecting pipe 7 through a tee, a valve 10 is arranged on the outer wall of the connecting pipe 7, a support plate 11 is arranged at the bottom end of the side plate 1, a support plate 2 12 is arranged at the bottom end of the side plate 22, a bottom plate 13 is arranged between the bottom ends of the support plates 11 and 12, a drain pipe 14 is arranged at the bottom end of the bottom plate 13, and a valve 2 15 is arranged on the outer wall of the drain pipe 14.

Furthermore, the number of connecting seats 3 in each group is two, and the gap is arranged between the side plate 1 and the side plate 2 from top to bottom. The cold and hot media flow in the side plate 1, the side plate 2 and the connecting seat 3 to heat or cool them. The side plate 1, the side plate 2 and the connecting seat 3 are placed on the outside and the middle of the kettle body to perform uniform temperature control on the middle and the outside.

Furthermore, the connecting seat 3 is composed of left and right rod bodies and a semicircular plate in the middle. The kettle body stirring rod passes through the top seat 6 and the connecting seat 3. The stirring blade is placed under the bottom connecting seat 3. The side plate 1, the side plate 2 and the connecting seat 3 are placed on the outside and the middle of the kettle body, and cooperate with the stirring mechanism to quickly and evenly control the temperature of the material in the kettle body.

Furthermore, the centers of the connecting seat 3 , the top seat 6 and the bottom plate 13 are located on the same vertical line, which facilitates passing the kettle body stirring rod through the top seat 6 and the connecting seat 3 .

Furthermore, the connecting pipe 7, the top seat 6, the connecting plate 14, the side plate 1, the connecting seat 3, the side plate 22, the support plate 212, the bottom plate 13 and the drain pipe 14 are connected to each other, and the cold and hot water are transported into the connecting pipe 7 and the top seat 6 through the liquid inlet pipe 18 or the liquid inlet pipe 29, enter the side plate 11 through the connecting plate 14, are transported into the side plate 22 through multiple connecting seats 3, are transported into the bottom plate 13 through the support plate 212, and are discharged and collected through the drain pipe 14.

The detailed connection means are well-known technologies in the art. All components in this solution are universal standard parts or components known to technicians in this field. The structures and principles are known to technicians in this field through technical manuals or conventional experimental methods.

A specific application of this embodiment is:

When in use, the device is assembled into the kettle body, the side plate 1 and the side plate 2 are attached to the inner wall of the kettle body, the top seat 6 is located at the top, the bottom plate 13 is located at the bottom, the top end of the connecting pipe 7 extends out of the kettle body, the liquid inlet pipe 1 8 and the liquid inlet pipe 2 9 are connected to the cold and hot water mechanism respectively, the bottom end of the discharge pipe 14 extends out of the kettle body, the kettle body stirring rod passes through the top seat 6 and the connecting seat 3, the stirring blade is placed below the bottom connecting seat 3, and is located between the side plate 1 and the side plate 2;

The cold and hot water are transported into the connecting pipe 7 and the top seat 6 through the liquid inlet pipe 1 8 or the liquid inlet pipe 2 9, enter the side plate 1 through the connecting plate 1 4, are transported into the side plate 2 2 through multiple connecting seats 3, are transported into the bottom plate 13 through the supporting plate 2 12, and are discharged and collected through the drain pipe 14. The cold and hot media circulate in the side plate 1 1, the side plate 2 2 and the connecting seat 3 to be heated or cooled. The side plate 1 1, the side plate 2 2 and the connecting seat 3 are placed on the outer side and the middle part of the kettle body, and the middle part and the outer side are evenly temperature controlled. The stirring mechanism is used to quickly and evenly control the temperature of the material in the kettle body.

Of course, the above description is not a limitation of the present invention, and the present invention is not limited to the above examples. Any changes, modifications, additions or substitutions made by ordinary technicians in this technical field within the essential scope of the present invention should fall within the protection scope of the present invention.

Claims (5)

1. A temperature control mechanism for a reactor for catalyst production, characterized in that it comprises a side plate 1 (1) and a side plate 2 (2), A plurality of connecting seats (3) are provided between the side plate 1 (1) and the side plate 2 (2); a connecting plate 1 (4) is provided at the top end of the side plate 1 (1); a connecting plate 2 (5) is provided at the top end of the side plate 2 (2); a top seat (6) is provided between the top ends of the connecting plates 1 (4) and 2 (5); a connecting pipe (7) is provided at the top end of the top seat (6); a liquid inlet pipe 1 (8) and a liquid inlet pipe 2 (9) are provided at the other end of the connecting pipe (7) through a tee, respectively; a valve 1 (10) is provided on the outer wall of the connecting pipe (7); a supporting plate 1 (11) is provided at the bottom end of the side plate 1 (1); a supporting plate 2 (12) is provided at the bottom end of the side plate 2 (2); a bottom plate (13) is provided between the bottom ends of the supporting plates 1 (11) and 2 (12); a liquid discharge pipe (14) is provided at the bottom end of the bottom plate (13); a valve 2 (15) is provided on the outer wall of the liquid discharge pipe (14). 2. A temperature control mechanism for a reactor for catalyst production according to claim 1, characterized in that: the number of the connecting seats (3) in each group is two, and the gap is arranged between the side plate 1 (1) and the side plate 2 (2) from top to bottom. 3. A temperature control mechanism for a reactor for catalyst production according to claim 1, characterized in that: the connecting seat (3) is composed of rods on the left and right sides and a semicircular plate in the middle. 4. A temperature control mechanism for a reactor for catalyst production according to claim 1, characterized in that the centers of the connecting seat (3), the top seat (6) and the bottom plate (13) are located on the same vertical line. 5. A temperature control mechanism for a reactor for catalyst production according to claim 1, characterized in that the connecting pipe (7), top seat (6), connecting plate 1 (4), side plate 1 (1), connecting seat (3), side plate 2 (2), support plate 2 (12), bottom plate (13) and drain pipe (14) are connected to each other.