CN217410698U - Material transferring mechanism between reaction kettles - Google Patents

Abstract

The utility model discloses a material transfer mechanism between reaction kettles, which comprises a reaction kettle main body, a transfer mechanism and a heat preservation mechanism; the reaction kettle main body is connected with a discharge end and a feed end; the transfer mechanism is connected between the pair of reaction kettle bodies and used for conveying materials in one reaction kettle body into the other reaction kettle body, and comprises a first transfer pipe and a second transfer pipe, the first transfer pipe and the second transfer pipe are respectively connected with the discharge end and the feed end, and the first transfer pipe and the second transfer pipe are respectively connected to different reaction kettle bodies. The utility model discloses a setting of corresponding mechanism can increase the heat preservation effect of material transfer pipe between a plurality of reation kettle, reduces the loss of material in transportation process heat energy, and then can reduce the consumption of heat energy, guarantees the normal reaction efficiency of material, also can save reation kettle's power consumption, can save user's cost input to a certain extent.

Description

Material transferring mechanism between reaction kettles

Technical Field

The utility model belongs to the technical field of reation kettle, concretely relates to material transfers mechanism between reation kettle.

Background

The reaction kettle is a container for physical or chemical reaction, and the heating, evaporation, cooling and low-speed mixing functions required by the process are realized through the structural design and parameter configuration of the container. The reaction kettle is widely applied to the fields of petroleum, chemical industry, rubber, pesticides, dyes, medicines, foods and the like, and is a pressure container for completing technological processes of vulcanization, nitration, hydrogenation, alkylation, polymerization, condensation and the like.

Part material is when carrying out production, need utilize a plurality of reation kettle to carry out reaction processing, in order to improve the transport efficiency of material between reation kettle, generally can use the transfer pipe and transfer the pump, but present transfer pipe lacks heat preservation device, when the material is carried in the transfer pipe, especially liquid material, the condition that has heat loss easily, and then when the material reentrants reation kettle, need spend more heat energy to go the temperature that promotes the material, not only prolong the reaction time of material, still increase the consumption of reation kettle electric energy easily, thereby increase user's use cost.

Therefore, in order to solve the above technical problems, it is necessary to provide a material transfer mechanism between reaction vessels.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a material transfer mechanism between reation kettle to solve foretell reation kettle material transfer pipe and cause the problem of heat energy loss because of lacking heat preservation device.

In order to achieve the above object, an embodiment of the present invention provides the following technical solutions:

the material transfer mechanism between the reaction kettles comprises a reaction kettle main body, a transfer mechanism and a heat preservation mechanism;

the reaction kettle main body is connected with a discharge end and a feed end;

the transfer mechanism is connected between the pair of reaction kettle main bodies and is used for conveying materials in one reaction kettle main body into the other reaction kettle main body, the transfer mechanism comprises a first transfer pipe and a second transfer pipe, the first transfer pipe and the second transfer pipe are respectively connected with the discharge end and the feed end, and the first transfer pipe and the second transfer pipe are respectively connected to different reaction kettle main bodies;

the heat preservation mechanism is connected between the first transfer pipe and the second transfer pipe and used for preserving heat and conveying materials.

Further, the discharge end is arranged at the lower end of the reaction kettle main body, and the feed end is arranged at the upper end of the reaction kettle main body. The discharge end is used for discharging materials, and the feed end is used for discharging high-temperature gas in the reaction kettle main body.

Furthermore, a transfer pump is connected to the first transfer pipe and used for pumping the material in one of the reaction kettle main bodies, so that the material can be conveyed to other reaction kettle main bodies for secondary reaction.

Further, the heat preservation mechanism comprises a heat preservation box for containing heat preservation liquid;

the insulation can is characterized in that a connecting pipe is fixedly connected in the insulation can, two ends of the connecting pipe are respectively connected with the first conveying pipe and the second conveying pipe, and the connecting pipe is used for connecting the first conveying pipe and the second conveying pipe, sensing the temperature of the insulation liquid and insulating materials conveyed through the connecting pipe.

Furthermore, the connecting pipe is made of heat-conducting metal, and when the temperature of the heat-insulating liquid rises, the connecting pipe can sense the temperature transmitted by the heat-insulating liquid, so that the heat of the materials conveyed in the connecting pipe can be insulated;

the insulation can is filled with insulation liquid, and the insulation liquid is arranged on the outer side of the connecting pipe and used for absorbing heat in high-temperature gas conveyed by the feeding end, so that materials conveyed in the connecting pipe can be insulated.

Furthermore, a first purifying part and a second purifying part are arranged in the heat insulation box, the first purifying part and the second purifying part are arranged on the upper side of the heat insulation liquid and are arranged on the outer side of the connecting pipe, and the first purifying part and the second purifying part are used for purifying gas entering the heat exchange in the heat insulation box, so that the gas is not easy to pollute the environment.

Furthermore, a plurality of exhaust holes are formed in the upper top surface of the heat insulation box, and the interior of the heat insulation box is communicated with the outside through the exhaust holes and used for exhausting gas after heat exchange.

Furthermore, the heat insulation box is connected with a gas pipe, one end of the gas pipe, far away from the heat insulation box, is communicated with the interior of the reaction kettle main body for conveying materials, when the reaction kettle main body conveys the materials, high-temperature gas can be stored in the reaction kettle main body due to work reaction of the reaction kettle main body, and the high-temperature gas enters the heat insulation box through the gas pipe for heat exchange, so that heat insulation liquid in the heat insulation box is heated, and the materials conveyed in the connecting pipe can be insulated;

the gas transmission pipe is provided with a one-way valve, so that the heat preservation liquid is not easy to flow backwards into the reaction kettle main body.

Compared with the prior art, the utility model has the advantages of it is following:

the utility model discloses a setting of corresponding mechanism can increase the heat preservation effect that material forwarded the pipe between a plurality of reation kettle, reduces the material in the loss of heat energy of transportation process, and then can reduce the consumption of heat energy, guarantees the normal reaction efficiency of material, also can save reation kettle's power consumption, can save user's cost input to a certain extent.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings needed to be used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments described in the present invention, and for those skilled in the art, other drawings can be obtained according to the drawings without creative efforts.

FIG. 1 is a perspective view of a material transfer mechanism between reaction vessels according to an embodiment of the present invention;

FIG. 2 is a partial cross-sectional view of a material transfer mechanism between reaction vessels according to an embodiment of the present invention;

fig. 3 is a schematic structural diagram of a in fig. 2.

In the figure: 1. the reaction kettle comprises a reaction kettle main body, 101, a discharge end, 102, a feed end, 2, a transfer mechanism, 201, a first transfer pipe, 202, a second transfer pipe, 203, a transfer pump, 3, a heat preservation mechanism, 301, a heat preservation box, 302, a connecting pipe, 303, heat preservation liquid, 304, a first purification piece, 305, a second purification piece, 306, an exhaust hole, 307 and an air conveying pipe.

Detailed Description

The present invention will be described in detail below with reference to embodiments shown in the drawings. However, the present invention is not limited to the embodiments, and the structural, method or functional changes made by those skilled in the art according to the embodiments are all included in the scope of the present invention.

The utility model discloses a material transfer mechanism between reation kettle, refer to fig. 1-3 and show, including reation kettle main part 1, transfer mechanism 2, heat preservation mechanism 3.

Wherein, be connected with discharge end 101 and feed end 102 on the reation kettle main part 1, the discharge end 101 is used for discharging the material in the reation kettle main part 1, and feed end 102 is used for the exhaust.

In addition, the discharge end 101 is provided at the lower end of the reaction vessel body 1, and the feed end 102 is provided at the upper end of the reaction vessel body 1, that is, in the state shown in fig. 1, so as to completely discharge the materials in the reaction vessel body 1.

Referring to fig. 1-3, transfer mechanism 2 is connected between a pair of reaction vessel main bodies 1 for conveying the material in one reaction vessel main body 1 to the other reaction vessel main body 1, specifically, in the present invention, the material is conveyed from the left reaction vessel main body 1 to the right reaction vessel main body 1.

The transfer mechanism 2 comprises a first transfer pipe 201 and a second transfer pipe 202, the first transfer pipe 201 and the second transfer pipe 202 are respectively connected with the discharge end 101 and the feed end 102, and the first transfer pipe 201 and the second transfer pipe 202 are respectively connected to different reactor bodies 1 for conveying materials.

In addition, the outer sides of the first transfer pipe 201 and the second transfer pipe 202 are both provided with heat insulation cotton for further reducing the heat loss of the materials in the conveying process.

Specifically, the first transfer pipe 201 is connected to a transfer pump 203 for pumping the material in the left reaction vessel body 1, and further transferring the material to the right reaction vessel body 1 for re-reaction.

Referring to fig. 2 to 3, the heat-insulating mechanism 3 is connected between the first transfer pipe 201 and the second transfer pipe 202, and is used for heat-insulating and conveying the material, so as to ensure the overall temperature of the material, prevent the heat of the material from losing, and further reduce the time for reheating the material by the reaction kettle main body 1.

Wherein, heat preservation mechanism 3 includes insulation can 301 for hold heat preservation liquid 303, insulation can 301 is the non-heat-conducting material, can reduce the probability that heat loss of heat preservation liquid 303, guarantees the heat preservation effect of heat preservation liquid 303 to the material.

Preferably, the heat insulation box 301 is fixedly connected with the side wall of the reaction kettle main body 1, so as to ensure the stability of the heat insulation box 301 in use.

In addition, a connecting pipe 302 is fixedly connected in the heat preservation box 301, and two ends of the connecting pipe 302 are respectively connected with the first transfer pipe 201 and the second transfer pipe 202, and are used for connecting the first transfer pipe 201 and the second transfer pipe 202, sensing the temperature transferred by the heat preservation liquid 303, and preserving heat of the material conveyed through the connecting pipe 302.

Preferably, connecting pipe 302 is heat conduction metal material, and when heat preservation liquid 303 heaies up, connecting pipe 302 can respond to the temperature of heat preservation liquid 303 transmission, and then can keep warm to the material of carrying in the connecting pipe 302.

Specifically, the heat preservation tank 301 is filled with a heat preservation liquid 303, and the heat preservation liquid 303 is disposed outside the connection pipe 302 and is used for absorbing heat in the high-temperature gas in the reaction kettle main body 1 conveyed through the feeding end 102, so that heat preservation can be performed on the material conveyed in the connection pipe 302.

Preferably, heat preservation liquid 303 is water, and water is convenient for draw materials, and the specific heat capacity of water is big, and water is difficult for running off after absorbing the heat, guarantees heat preservation liquid 303 to the heat preservation effect of carrying the material in the connecting pipe 302.

In addition, the heat preservation box 301 is connected with a liquid feeding pipe, so that the heat preservation liquid 303 can be conveniently filled by workers, and the heat preservation effect of the heat preservation liquid 303 is ensured.

Referring to fig. 2 to 3, a first purifying member 304 and a second purifying member 305 are disposed in the heat insulation box 301, the first purifying member 304 and the second purifying member 305 are both disposed on the upper side of the heat insulation liquid 303 and outside the connecting pipe 302, and the first purifying member 304 and the second purifying member 305 are both used for purifying the gas entering the heat insulation box 301, so that the gas is not likely to pollute the environment.

Preferably, the first purging element 304 and the second purging element 305 are commercially available purging materials.

A plurality of exhaust holes 306 are formed in the upper top surface of the insulation can 301, and the inside of the insulation can 301 is communicated with the outside through the exhaust holes 306 and used for exhausting gas in the insulation can 301, so that the insulation can 301 is not prone to over-pressure.

In addition, be connected with gas-supply pipe 307 on insulation can 301, the one end that insulation can 301 was kept away from to gas-supply pipe 307 is linked together with the inside of the reation kettle main part 1 of transported substance, because left side reation kettle main part 1 during operation can produce high temperature, when left side reation kettle main part 1 transported substance, the high-temperature gas in the left side reation kettle main part 1 enters into insulation can 301 through gas-supply pipe 307 and carries out the heat transfer, make the heat preservation liquid 303 in the insulation can 301 heat up, and then can improve the temperature of connecting pipe 302, be used for keeping warm to the material of carrying in the connecting pipe 302.

Specifically, install the check valve on the gas-supply pipe 307 for in heat preservation liquid 303 is difficult for flowing backward and enters into reation kettle main part 1, also make gas-supply pipe 307 open when needs simultaneously, reduce the reaction influence to material in the reation kettle main part 1.

When the left reaction kettle main body 1 needs to be conveyed, the transfer pump 203 and the one-way valve on the gas pipe 307 are opened, high-temperature gas in the left reaction kettle main body 1 enters the heat insulation box 301 through the gas pipe 307 and fully contacts with heat insulation liquid 303 in the heat insulation box 301, heat exchange is carried out by using the heat insulation liquid 303, the heat insulation liquid 303 can absorb heat in the high-temperature gas and raise the temperature, and as the connecting pipe 302 is made of a heat conduction metal material, when the temperature of the heat insulation liquid 303 rises, the connecting pipe 302 can absorb the temperature transmitted by the heat insulation liquid 303, so that the temperature of the heat insulation liquid 303 also rises;

the heat-exchanged gas is filtered by the first purifying part 304 and the second purifying part 305 and is exhausted through the exhaust hole 306, so that the pollution of the gas to the air environment is reduced;

when the transfer pump 203 operates, the transfer pump 203 extracts the material in the left-side reaction kettle main body 1 through the first transfer pipe 201, the material enters the connecting pipe 302 through the first transfer pipe 201, because the temperature of the connecting pipe 302 is higher, the connecting pipe 302 can transfer heat to the material, and then can keep warm to the material, the material continues to flow, through the second transfer pipe 202, the feed end 102 enters into the right-side reaction kettle main body 1, not only can reduce the thermal loss of the material in the conveying process, but also can reduce the electric energy consumption of the material heated again by the right-side reaction kettle main body 1, the normal reaction efficiency of the material is ensured, and the purpose of energy conservation can be achieved to a certain extent.

According to the technical scheme provided by the utility model, the utility model discloses following beneficial effect has:

the utility model discloses a setting of corresponding mechanism can increase the heat preservation effect of material transfer pipe between a plurality of reation kettle, reduces the loss of material in transportation process heat energy, and then can reduce the consumption of heat energy, guarantees the normal reaction efficiency of material, also can save reation kettle's power consumption, can save user's cost input to a certain extent.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential attributes thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention 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.

Furthermore, it should be understood that although the present description refers to embodiments, not every embodiment may contain only a single embodiment, and such description is for clarity only, and those skilled in the art should integrate the description, and the embodiments may be combined as appropriate to form other embodiments understood by those skilled in the art.

Claims (8)

1. Material transfer mechanism between reation kettle, its characterized in that includes:

the reaction kettle comprises a reaction kettle main body (1), wherein a discharge end (101) and a feed end (102) are connected to the reaction kettle main body (1);

the transfer mechanism (2) is connected between the pair of reaction kettle bodies (1) and is used for conveying the material in one reaction kettle body (1) into the other reaction kettle body (1);

the transfer mechanism (2) comprises a first transfer pipe (201) and a second transfer pipe (202), the first transfer pipe (201) and the second transfer pipe (202) are respectively connected with the discharge end (101) and the feed end (102), and the first transfer pipe (201) and the second transfer pipe (202) are respectively connected to different reaction kettle bodies (1);

and the heat preservation mechanism (3) is connected between the first transfer pipe (201) and the second transfer pipe (202) and used for preserving heat and conveying materials.

2. The material transfer mechanism between reaction kettles as claimed in claim 1, wherein said discharge end (101) is provided at the lower end of the main body (1) of the reaction kettle, and said feed end (102) is provided at the upper end of the main body (1) of the reaction kettle.

3. The material transfer mechanism between reaction kettles of claim 1, wherein a transfer pump (203) is connected to said first transfer pipe (201).

4. The material transfer mechanism between reaction kettles of claim 1, wherein said heat-insulating mechanism (3) comprises a heat-insulating box (301), a connecting pipe (302) is fixedly connected inside said heat-insulating box (301), and both ends of said connecting pipe (302) are respectively connected to said first transfer pipe (201) and said second transfer pipe (202).

5. The material transfer mechanism between reaction kettles according to claim 4, wherein said connecting pipe (302) is made of heat conductive metal, said heat-insulating box (301) is filled with heat-insulating liquid (303), and said heat-insulating liquid (303) is disposed outside said connecting pipe (302).

6. The material transfer mechanism between reaction kettles of claim 5, wherein said heat-insulating box (301) is provided with a first purifying member (304) and a second purifying member (305), said first purifying member (304) and said second purifying member (305) are both disposed on the upper side of said heat-insulating liquid (303) and outside said connecting pipe (302).

7. The material transfer mechanism between reaction kettles of claim 6, wherein said insulation cabinet (301) is perforated with a plurality of vent holes (306) on the top surface, and the interior of said insulation cabinet (301) is connected to the outside through said vent holes (306).

8. The material transfer mechanism between reaction kettles as claimed in claim 7, wherein said insulation can (301) is connected with a gas pipe (307), one end of said gas pipe (307) far away from the insulation can (301) is communicated with the interior of the reaction kettle main body (1) for conveying material, and said gas pipe (307) is equipped with a one-way valve.

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