CN216144196U

CN216144196U - Condenser for resin reaction kettle

Info

Publication number: CN216144196U
Application number: CN202122128375.4U
Authority: CN
Inventors: 李永全; 陆子恒
Original assignee: Foshan Yuhai Resin Co ltd
Current assignee: Foshan Yuhai Resin Co ltd
Priority date: 2021-09-03
Filing date: 2021-09-03
Publication date: 2022-03-29
Anticipated expiration: 2031-09-03

Abstract

The utility model relates to the technical field of resin production, in particular to a condenser for a resin reaction kettle, which comprises a condensation pipe body, a connecting shaft, a first cooling sleeve and a second cooling sleeve, wherein the condensation pipe body inclines upwards from left to right; the connecting shaft is arranged in the condensing pipe body, and the left end and the right end of the connecting shaft are correspondingly connected with the left end and the right end of the inner wall of the condensing pipe body respectively; the first cooling jacket comprises a plurality of first U-shaped pipes which are spirally wound from left to right in sequence on a first liquid passing groove formed in the outer side of the connecting shaft and connected with two adjacent first liquid passing grooves, the first U-shaped pipes are located at the bottom side outside the first liquid passing groove, the second cooling jacket comprises a plurality of second U-shaped pipes which are spirally wound from left to right in sequence on a second liquid passing groove formed in the outer side of the condensing pipe body and connected with two adjacent second liquid passing grooves, and the second U-shaped pipes are located at the top side in the condensing pipe body. The utility model can reduce the reduction of the proportion of the raw materials and the waste of the materials, and ensure the quality of the resin finished product.

Description

Condenser for resin reaction kettle

Technical Field

The utility model relates to the technical field of resin production, in particular to a condenser for a resin reaction kettle.

Background

The resin generally refers to an organic polymer which has a softening or melting range after being heated, tends to flow by an external force when softened, and is solid, semi-solid, or liquid at room temperature. The resin may be classified into natural resin and synthetic resin according to the source resin. The synthetic resin is prepared by putting a plurality of raw materials into a reaction kettle, mixing and carrying out physical and chemical reaction.

However, in the reaction vessel of the prior art, steam is required to be introduced to heat and humidify the raw materials, and since the boiling point of part of the raw materials of the resin is large, the raw materials are heated and vaporized, and the pressure in the reaction vessel is increased. If the gas in the reaction kettle is directly discharged, the specific gravity of the raw materials is reduced, the materials are wasted, and the quality of the resin finished product is affected.

SUMMERY OF THE UTILITY MODEL

The utility model aims to solve the technical problem of providing a condenser for a resin reaction kettle, which reduces the reduction of the proportion of raw materials and the waste of materials and ensures the quality of resin finished products.

In order to solve the technical problem, the condenser for the resin reaction kettle comprises a condensation pipe body, a connecting shaft, a first cooling sleeve and a second cooling sleeve, wherein the first cooling sleeve and the second cooling sleeve are used for introducing cooling liquid; the connecting shaft is arranged in the condensing pipe body, and the left end and the right end of the connecting shaft are correspondingly connected with the left end and the right end of the inner wall of the condensing pipe body respectively; first cooling jacket includes a plurality of first U type pipes that turn right from a left side in proper order around establishing the first logical liquid groove in the connecting axle outside and connecting two adjacent first logical liquid grooves, first U type pipe is located the outside bottom side of first logical liquid groove, second cooling jacket includes a plurality of second U type pipes that turn right in proper order around establishing the second logical liquid groove in the condensation body outside and connecting two adjacent second logical liquid grooves from a left side, second U type pipe is located the top side in the condensation body.

As an improvement of the scheme, the axis of the condensation pipe body forms an included angle of 5-10 degrees with the horizontal plane.

As an improvement of the scheme, the liquid outlet pipe is obliquely arranged from left to right, and the air inlet pipe is obliquely arranged from left to right.

As an improvement of the scheme, the included angle between the liquid outlet pipe and the horizontal plane is 60-80 degrees, and the included angle between the air inlet pipe and the horizontal plane is 60-80 degrees.

As an improvement of the scheme, baffles inclining downwards from right to left are arranged at intervals on the top side in the liquid outlet pipe.

As an improvement of the scheme, the inner diameter of the liquid outlet pipe is smaller than that of the gas inlet pipe.

As an improvement of the scheme, the horizontal positions of the first cooling jacket and the second cooling jacket are between the horizontal position of the inlet of the liquid outlet pipe and the horizontal position of the outlet of the air inlet pipe.

As the improvement of the scheme, a first liquid passing pipe and a second liquid passing pipe extending out of the condensation pipe body are arranged at the left end and the right end of the first cooling jacket respectively, and a third liquid passing pipe and a fourth liquid passing pipe are arranged at the left end and the right end of the second cooling jacket respectively.

As the improvement of the above scheme, the liquid inlet of the first liquid passing pipe, the liquid outlet of the second liquid passing pipe, the liquid inlet of the third liquid passing pipe and the liquid outlet of the fourth liquid passing pipe are arranged above the condensation pipe body.

As the improvement of the above scheme, the liquid inlet of the first liquid passing pipe is communicated with the liquid inlet of the third liquid passing pipe, and the liquid outlet of the second liquid passing pipe is communicated with the liquid outlet of the fourth liquid passing pipe.

The implementation of the utility model has the following beneficial effects:

the condenser for the resin reaction kettle is characterized in that a condensing pipe body, a connecting shaft, a liquid outlet pipe, an air inlet pipe, a first liquid passing groove, a first U-shaped pipe and a second liquid passing groove, preferably a second U-shaped pipe, are matched with each other, steam passes through an annular channel of the condensing pipe body and cools the steam from the inner side and the outer side, meanwhile, the first U-shaped pipe and the second U-shaped pipe which are filled with cooling liquid are matched with each other, the formation of condensate is accelerated, the condensate drops to the inner bottom side of the condensing pipe body and flows back to the resin reaction kettle through the liquid outlet pipe, raw materials vaporized in the resin reaction kettle and the steam are cooled into condensate which returns to the resin reaction kettle, the reduction of the specific gravity of the raw materials is reduced, the waste of the materials is reduced, and the quality of a resin finished product is ensured.

Drawings

FIG. 1 is a schematic structural view of a condenser for a resin reaction vessel in an embodiment of the present invention;

FIG. 2 is a schematic diagram of a first U-shaped pipe connecting two adjacent first liquid passing tanks according to an embodiment of the utility model;

FIG. 3 is a schematic diagram of a second U-shaped pipe connecting two adjacent second liquid passing tanks according to an embodiment of the present invention;

FIG. 4 is an enlarged view taken at A in FIG. 1;

fig. 5 is an enlarged view at B in fig. 1.

In the figure: 1. a condensation pipe body; 2. a connecting shaft; 3. a first cooling jacket; 4. a second cooling jacket; 11. a liquid outlet pipe; 12. an air inlet pipe; 31. a first liquid passing groove; 32. a first U-shaped pipe; 41. a second liquid passing tank; 42. a second U-shaped tube; 13. a baffle plate; 33. a first liquid through pipe; 34. a second liquid through pipe; 43. a third liquid passing pipe; 44. a fourth cross-flow pipe.

Detailed Description

The utility model will be further described with reference to the accompanying drawings and specific embodiments so as to more clearly understand the technical idea of the utility model claimed. It is only noted that the utility model is intended to be limited to the specific forms set forth herein, including any reference to the drawings, as well as any other specific forms of embodiments of the utility model.

As shown in fig. 1 to 5, the condenser for a resin reaction kettle in the embodiment of the present invention includes a condensation tube body 1, a connecting shaft 2, a first cooling jacket 3 for introducing a cooling liquid, and a second cooling jacket 4, wherein the condensation tube body 1 is inclined upward from left to right, a liquid outlet tube 11 is disposed at the left portion of the bottom side of the condensation tube body 1, and an air inlet tube 12 is disposed at the right portion of the bottom side of the condensation tube body 1; in fact, resin is condenser for reation kettle passes through drain pipe 11 and intake pipe 12 and reation kettle intercommunication (not drawing reation kettle in the picture), and in steam entered into condensation body 1 through intake pipe 12, the liquid that forms in condensation body 1 passed through drain pipe 11 and converges to reation kettle in.

The connecting shaft 2 is arranged in the condensing tube body 1, and the left end and the right end of the connecting shaft are respectively and correspondingly connected with the left end and the right end of the inner wall of the condensing tube body 1 to form an annular channel for steam to pass through; the first cooling jacket 3 comprises a plurality of first liquid passing grooves 31 which are spirally wound on the outer side of the connecting shaft 2 from left to right in sequence and first U-shaped pipes 32 which are connected with two adjacent first liquid passing grooves 31, the first liquid passing grooves 31 are communicated with cooling liquid, so that a first cooling surface is formed on the outer side of each first liquid passing groove 31, and the first U-shaped pipes 32 are positioned on the bottom side outside the first liquid passing grooves 31; the second cooling jacket 4 comprises a plurality of second liquid passing grooves 41 which are sequentially spirally wound from left to right and are arranged on the outer side of the condensation pipe body 1 and second U-shaped pipes 42 which are connected with two adjacent second liquid passing grooves 41, the second liquid passing grooves 41 are communicated with cooling liquid to form second cooling surfaces on the inner side walls of the condensation pipe body 1 which are in contact with the second liquid passing grooves 41, and the second U-shaped pipes 42 are positioned on the top side in the condensation pipe body 1.

It should be noted that, the condenser body 1, the connecting shaft 2, the liquid outlet pipe 11, the air inlet pipe 12, the first liquid passing tank 31, the first U-shaped pipe 32, and the second liquid passing tank 41 are preferably made of stainless steel, and have excellent thermal conductivity and simultaneously play a role in reducing corrosion of resin raw materials to the condenser.

The condenser for the resin reaction kettle has the following specific working principle: the steam in the reaction kettle enters the annular channel of the condensation pipe body 1 and contacts with the outer side of the first liquid through groove 31 and the inner side wall of the condensation pipe body 1 contacting with the second liquid through groove 41 and is cooled, and the condensate in the form falls to the inner bottom side of the condensation pipe body 1 from the outer side of the first liquid through groove 31 and the side wall of the condensation pipe body 1; furthermore, the first U-shaped pipe 32 is contacted with the steam to condense and drip the steam to the inner bottom side of the condensation tube body 1, the second U-shaped pipe 42 is contacted with the steam to condense and drip the steam to the outer side of the first liquid passing groove 31 and drip from the inner bottom side of the first liquid passing groove 31 and the first U-shaped pipe 32 to the inner bottom side of the condensation tube body 1, and finally, the condensed steam gathered at the inner bottom side of the condensation tube body 1 flows back to the resin reaction kettle through the liquid outlet pipe 11.

The condenser for the resin reaction kettle is characterized in that a condensing tube body 1, a connecting shaft 2, a liquid outlet pipe 11, an air inlet pipe 12, a first liquid passing groove 31, a first U-shaped pipe 32 and a second liquid passing groove 41, preferably a second U-shaped pipe 42, are matched with each other, steam passes through an annular channel of the condensing tube body 1 and cools the steam from the inner side and the outer side, meanwhile, the first U-shaped pipe 32 and the second U-shaped pipe 42 which are filled with cooling liquid are matched with each other, the formation of condensate is accelerated, the condensate drops to the inner bottom side of the condensing tube body 1 and flows back to the resin reaction kettle through the liquid outlet pipe 11, raw materials vaporized in the resin reaction kettle and the steam are cooled into condensate and return to the resin reaction kettle, the reduction of the specific gravity of the raw materials and the waste of the materials are reduced, and the quality of a resin finished product is ensured.

It should be noted that the axis of the condensation tube body 1 and the horizontal plane preferably form an included angle of 5-10 degrees, so that the joint of the liquid outlet tube 11 and the condensation tube body 1 is lower than the joint of the air inlet tube 12 and the condensation tube body 1, and the condensate enters the liquid outlet tube 11 along the inner bottom side of the condensation tube body 1 under the action of gravity.

Further, the liquid outlet pipe 11 is preferably arranged in a downward inclination from left to right, so that the condensate flows into the resin reaction kettle in a downward inclination manner; the air inlet pipe 12 is preferably arranged in an inclined manner from left to right upwards, steam enters the condensation pipe body 1 in an inclined manner upwards, and condensate formed by contact of a small part of steam and the inner wall of the air inlet pipe 12 flows back into the resin reaction kettle from the bottom side of the air inlet pipe 12. Furthermore, the included angle between the liquid outlet pipe 11 and the horizontal plane is preferably 60-80 degrees, and the included angle between the air inlet pipe 12 and the horizontal plane is preferably 60-80 degrees, so that the condensate flows back into the resin reaction kettle along the inclined plane.

It is worth mentioning that baffles 13 inclining downwards from right to left are preferably arranged at intervals on the inner top side of the liquid outlet pipe 11, and the steam contacts with the baffles 13 to generate condensate and make the condensate drop to the inner bottom side of the liquid outlet pipe 11.

In practice, the inner diameter of outlet pipe 11 is preferably smaller than the inner diameter of inlet pipe 12, corresponding to the volume reduction after liquefaction of the vapor.

It should be noted that the horizontal positions of the first cooling jacket 3 and the second cooling jacket 4 are preferably between the horizontal position of the inlet of the liquid outlet pipe 11 and the horizontal position of the outlet of the air inlet pipe 12, and the steam enters the condensation tube body 1 through the outlet of the air inlet pipe 12, moves from right to left, is cooled by the first cooling jacket 3 and the second cooling jacket 4 to become condensate, and leaves the condensation tube body 1 from the inlet of the liquid outlet pipe 11.

In fact, the left and right ends of the first cooling jacket 3 are preferably provided with a first liquid passing pipe 33 and a second liquid passing pipe 34 respectively extending out of the condensation tube body 1, and the first liquid passing pipe 33 and the second liquid passing pipe 34 are connected with an external refrigeration device (not shown in the figure) to form a cooling liquid circulation; a third liquid passing pipe 43 and a fourth liquid passing pipe 44 are preferably provided at each of the left and right ends of the second cooling jacket 4, and connected to an external cooling device (not shown) through the third liquid passing pipe 43 and the fourth liquid passing pipe 44 to form a cooling liquid circulation, and the external cooling device cools the cooling liquid to maintain the cooling liquid in the first cooling jacket 3 and the second cooling jacket 4 at a predetermined cooling temperature, thereby ensuring a cooling effect.

Further, the liquid inlet of the first liquid passing pipe 33, the liquid outlet of the second liquid passing pipe 34, the liquid inlet of the third liquid passing pipe 43 and the liquid outlet of the fourth liquid passing pipe 44 are preferably arranged above the condensation pipe body 1, so that the influence on the layout of the feeding pipelines on the top surface of the resin reaction kettle is reduced. Furthermore, the liquid inlet of the first liquid passing pipe 33 is preferably communicated with the liquid inlet of the third liquid passing pipe 43, i.e. connected with the liquid outlet of the external refrigeration device through a liquid inlet pipeline (not shown in the figure); the outlet of the second liquid-passing pipe 34 is preferably connected to the outlet of the fourth liquid-passing pipe 44, i.e. connected to the inlet of an external refrigeration device (not shown in the figure) via a liquid-returning pipe, so as to realize the circulation flow of the cooling liquid.

The above description is only an embodiment of the present invention, and not intended to limit the scope of the present invention, and all modifications of equivalent structures and equivalent processes, which are made by using the contents of the present specification and the accompanying drawings, or directly or indirectly applied to other related technical fields, are included in the scope of the present invention.

Claims

1. The utility model provides a condenser for resin reation kettle which characterized in that: the cooling device comprises a condensation pipe body, a connecting shaft, a first cooling sleeve and a second cooling sleeve, wherein the first cooling sleeve and the second cooling sleeve are used for introducing cooling liquid, the condensation pipe body inclines upwards from left to right, a liquid outlet pipe is arranged at the left part of the bottom side of the condensation pipe body, and an air inlet pipe is arranged at the right part of the bottom side of the condensation pipe body; the connecting shaft is arranged in the condensing pipe body, and the left end and the right end of the connecting shaft are correspondingly connected with the left end and the right end of the inner wall of the condensing pipe body respectively; first cooling jacket includes a plurality of first U type pipes that turn right from a left side in proper order around establishing the first logical liquid groove in the connecting axle outside and connecting two adjacent first logical liquid grooves, first U type pipe is located the outside bottom side of first logical liquid groove, second cooling jacket includes a plurality of second U type pipes that turn right in proper order around establishing the second logical liquid groove in the condensation body outside and connecting two adjacent second logical liquid grooves from a left side, second U type pipe is located the top side in the condensation body.

2. The condenser for a resin reaction vessel according to claim 1, wherein: the axis of the condensation pipe body forms an included angle of 5-10 degrees with the horizontal plane.

3. The condenser for a resin reaction vessel as claimed in claim 2, wherein: the drain pipe is inclined downwards from left to right, and the intake pipe is inclined upwards from left to right.

4. A condenser for a resin reaction vessel according to claim 3, wherein: the included angle between the liquid outlet pipe and the horizontal plane is 60-80 degrees, and the included angle between the air inlet pipe and the horizontal plane is 60-80 degrees.

5. The condenser for a resin reaction vessel as set forth in claim 4, wherein: baffles inclining downwards from right to left are arranged at intervals on the inner top side of the liquid outlet pipe.

6. A condenser for a resin reaction vessel according to claim 3, wherein: the inner diameter of the liquid outlet pipe is smaller than that of the gas inlet pipe.

7. A condenser for a resin reaction vessel as defined in any one of claims 1 to 6, wherein: the horizontal positions of the first cooling jacket and the second cooling jacket are between the horizontal position of the inlet of the liquid outlet pipe and the horizontal position of the outlet of the air inlet pipe.

8. The condenser for a resin reaction vessel as claimed in claim 7, wherein: both ends are equipped with respectively about first cooling jacket and stretch out the external first liquid pipe and the second liquid pipe of leading to of condenser pipe, both ends are equipped with third liquid pipe and the fourth liquid pipe of leading to respectively about the second cooling jacket.

9. The condenser for a resin reaction vessel as claimed in claim 8, wherein: the liquid inlet of the first liquid passing pipe, the liquid outlet of the second liquid passing pipe, the liquid inlet of the third liquid passing pipe and the liquid outlet of the fourth liquid passing pipe are arranged above the condensation pipe body.

10. The condenser for a resin reaction vessel as claimed in claim 9, wherein: the inlet of first liquid passing pipe and the inlet intercommunication of third liquid passing pipe, the liquid outlet of second liquid passing pipe and the liquid outlet intercommunication of fourth liquid passing pipe.