CN112121747A

CN112121747A - Polymer coating reation kettle

Info

Publication number: CN112121747A
Application number: CN202010956132.7A
Authority: CN
Inventors: 林玉芳
Original assignee: Individual
Current assignee: Individual
Priority date: 2020-09-11
Filing date: 2020-09-11
Publication date: 2020-12-25

Abstract

The invention discloses a high polymer coating reaction kettle, which structurally comprises a reaction motor 1, a connecting rotating shaft 2, a reaction kettle body 3, a stepped cooling mechanism 4, a support 5 and a support rod 6, the reaction motor 1 is arranged above the reaction kettle body through a connecting rotating shaft, the stepped cooling mechanism is nested on the outer surface of the reaction kettle body, the support is fixed on the outer side surface of the stepped temperature reduction mechanism through a nut, the support rod is fixed at the bottom of the reaction kettle body through a bolt, the stepped temperature reduction mechanism is arranged, the reaction kettle body is cooled by stages, the surface of the kettle body is cooled by a small-area first-order through a cooling water source, carry out the second order cooling of great area again after the temperature is stable, avoid because the cooling too fast, the internal temperature difference of cauldron is big and leads to the cauldron body to produce the crackle, the scheduling problem bursts, when effectively cooling, also guarantee the security.

Description

Polymer coating reation kettle

Technical Field

The invention relates to the field of coating production equipment, in particular to a high-molecular coating reaction kettle.

Background

The coating is traditionally named as paint in China. The coating is a continuous film which is coated on the surface of a protected or decorated object and can form firm adhesion with the object to be coated, usually resin, oil or emulsion is taken as a main material, the material of the coating needs to be processed and produced through a reaction kettle in the production process, the temperature of a kettle body of the reaction kettle often needs to be increased in the processing process of the reaction kettle, the temperature needs to be timely reduced after the completion of the processing, but if the temperature reduction speed is too high, the temperature difference in the kettle body is too large, the damage of the kettle body is easy to cause, for example, the kettle body has cracks and the like, the coating is serious and even bursts, the coating is not safe, and the production cost is increased.

Disclosure of Invention

Aiming at the defects of the prior art, the invention is realized by the following technical scheme: a high polymer coating reaction kettle structurally comprises a reaction motor 1, a connecting rotating shaft 2, a reaction kettle body 3, a stepped cooling mechanism 4, a support 5 and a support rod 6, wherein the reaction motor 1 is arranged above the reaction kettle body through the connecting rotating shaft, the stepped cooling mechanism is nested on the outer surface of the reaction kettle body, the support is fixed on the outer side surface of the stepped cooling mechanism through nuts, and the support rod is fixed at the bottom of the reaction kettle body through bolts;

the stepped cooling mechanism comprises a water inlet shunting mechanism, a first-order cooling pipeline, a second-order cooling pipeline, a kettle body cooling casing, a water outlet, a temperature detector and a cooling water inlet pump, wherein the water inlet shunting mechanism is embedded into the kettle body cooling casing and is communicated with the first-order cooling pipeline and the second-order cooling pipeline, the kettle body cooling casing is nested on the outer surface of a reaction kettle body, the first-order cooling pipeline and the second-order cooling pipeline are respectively in an integrated structure with the kettle body cooling casing, the first-order cooling pipeline and the second-order cooling pipeline are alternately distributed on the outer surface of the reaction kettle body, the water outlet is embedded into the kettle body cooling casing and is communicated with the first-order cooling pipeline and the second-order cooling pipeline, the temperature detector is embedded into the kettle body cooling casing and is tightly attached to the surface of the reaction kettle body, the cooling water inlet pump is fixed on the kettle body casing through bolts and, the temperature detector passes through circuit and cooling intake pump zonulae occludens, the area of connection of second order cooling pipeline and the reation kettle cauldron body is greater than the area of connection of first order cooling pipeline and the reation kettle cauldron body, the perpendicular cross-section of order cooling pipeline and second order cooling pipeline all is semicircular structure.

As the further optimization of this technical scheme, the reposition of redundant personnel mechanism of intaking includes frame, reposition of redundant personnel chamber, lift slide rail, the lifter plate that divides the rank, water inlet, the cooling mechanism that divides the rank, the water sealing plate that divides the rank, the reposition of redundant personnel chamber is integrated structure with the frame of intaking, lift slide rail one side is located reposition of redundant personnel chamber left side and is intake frame fixed connection, and the opposite side is connected with the lifter plate cooperation that divides the rank, the lifter plate left side one end that divides the rank is connected with the water sealing plate surface vertical, the cooling mechanism that divides the rank is equipped with 2 groups to in proper order with the lifter plate swing joint that divides the rank.

As a further optimization of the technical scheme, the stepped cooling mechanism comprises a stepped flow guide first plate, a connecting frame, an anti-overflow mechanism and a stepped flow guide second plate, wherein the stepped flow guide first plate and the stepped flow guide second plate are respectively and movably connected with the stepped lifting plate, the stepped flow guide first plate and the stepped flow guide second plate are consistent in structure and are distributed in a symmetrical form, and the anti-overflow mechanism is arranged between the stepped flow guide first plate and the stepped flow guide second plate.

As the further optimization of the technical scheme, the connecting frame and the stepped lifting plate are of an integrated structure, the number of the connecting frame is 2, the connecting frame is of a frame structure and is connected with the stepped cooling mechanism in a matched mode, and the frame structure can achieve the passing of a cooling water source.

As a further optimization of the technical scheme, the first stepped flow guide plate is provided with a balance block and a movable ring, the balance block is fixed at the bottom of the first stepped flow guide plate, the movable ring is nested in the middle of the first stepped flow guide plate and is in clearance fit with the first stepped flow guide plate, and the first stepped flow guide plate is connected with the stepped lifting plate through the movable ring.

As a further optimization of the technical scheme, the anti-overflow mechanism comprises an opening and closing sleeve, a lifting track and a sliding groove, the lifting track is arranged on the inner wall of the rear side of the diversion cavity, the sliding groove is nested and connected with the rear side surface of the opening and closing sleeve and is in clearance fit with the rear side surface of the opening and closing sleeve, the sliding groove and the lifting track are of an integrated structure, and the sliding groove is distributed on the front side surface of the lifting track.

As a further optimization of the technical scheme, the opening and closing sleeve comprises a sleeve water inlet, a gravity steel block, a projecting pipe and a movable ball, the water inlet and the opening and closing sleeve are of an integrated structure, the water inlet is arranged at the bottom of the opening and closing sleeve and is in through connection with the inside of the opening and closing sleeve, one end of the bottom of the projecting pipe is connected with the gravity steel block, the movable ball is arranged on the outer side of the opening and closing sleeve and is movably connected with the projecting pipe, and the projecting pipe is provided with 2 groups and is symmetrically embedded and connected inside the opening and closing sleeve.

As the further optimization of this technical scheme, the gravity steel block is equipped with 2, locates the inside both sides of sleeve pipe that opens and shuts respectively, and when the second cooling stage was over, through the gravity of gravity steel block, can make extension pipe, activity ball withdraw to the sleeve pipe that opens and shuts intraductally, the passage of cooling water source when being convenient for first stage cooling.

Advantageous effects

According to the high-molecular coating reaction kettle, when the high-molecular coating reaction kettle is used, the kettle body of the reaction kettle is often required to be cooled, but the cooling speed is too high, and the surface of the kettle body of the reaction kettle is easy to crack due to large temperature difference, so that the kettle body is damaged; when the temperature detector detects that the temperature of the reaction kettle body is reduced, the temperature detector drives the cooling water inlet pump again through a line to increase the water pressure of water injection to the water inlet shunting mechanism, and under the guidance of the opening and closing sleeve, water flow impacts the first stepped flow guide plate and the second stepped flow guide plate, the first stepped flow guide plate rotates clockwise, the second stepped flow guide plate rotates anticlockwise, the top of the first stepped flow guide plate is attached to the top of the second stepped flow guide plate to form an umbrella shape, a cooling water source is difficult to pass through, the water pressure generates upward pressure to flush the stepped lifting plate and the stepped cooling mechanism connected with the stepped lifting plate, so that the water inlet of the first-order cooling pipeline is sealed by the stepped water sealing plate, the opening of the second-order cooling pipeline is opened, the cooling water source enters the second-order cooling pipeline to cool the surface of the reaction kettle body in a larger area, and the cooling speed can be improved through stepped cooling, avoid the damage of the reaction kettle body.

When the second stage is cooled, in order to prevent a cooling water source from overflowing into the first-order cooling pipeline and ensure that the second-order cooling pipeline can be smoothly opened, an anti-overflow mechanism is additionally arranged, namely when water pressure is injected, part of the cooling water source is injected into the opening and closing sleeve pipe through the sleeve pipe water inlet under the action of the water pressure, the gravity steel block, the extension pipe and the movable ball are sequentially pushed out towards the outer side to form a V shape, the opening and closing sleeve pipe moves towards the upper side along the lifting track under the action of the water pressure, the movable ball is respectively attached to the inner side surfaces of the first stepped flow guide plate and the second stepped flow guide plate, the movable ball is respectively attached to the top of the first stepped flow guide plate and the top of the second stepped flow guide plate under the double sealing of the attachment of the first stepped flow guide plate and the inner side surfaces of the second stepped flow guide plate, the water source is prevented from passing through.

Compared with the prior art, the invention has the following advantages:

the reaction kettle is cooled in stages by arranging the step-type cooling mechanism, the surface of the kettle body is cooled in a small-area first-order mode through the cooling water source, and the second-order cooling in a larger area is carried out after the temperature is stable, so that the problems of cracking, bursting and the like of the kettle body caused by too fast cooling and large temperature difference in the kettle body are avoided, the temperature is effectively cooled, and the safety is also ensured.

Drawings

Other features, objects and advantages of the invention will become more apparent upon reading of the detailed description of non-limiting embodiments with reference to the following drawings:

FIG. 1 is a schematic structural diagram of a high molecular coating reactor of the present invention.

Fig. 2 is a schematic structural diagram of the stepped cooling mechanism of the present invention.

Fig. 3 is a schematic structural diagram of the inflow water diversion mechanism of the present invention.

Fig. 4 is a schematic structural diagram of the stepped cooling mechanism of the present invention.

Fig. 5 is a schematic structural diagram of the anti-overflow mechanism of the present invention.

FIG. 6 is a schematic view of the operation of the water inlet diversion mechanism of the present invention.

In the figure: the device comprises a reaction motor 1, a connecting rotating shaft 2, a reaction kettle body 3, a stepped cooling mechanism 4, a support 5, a support rod 6, a water inlet shunting mechanism 41, a first-order cooling pipeline 42, a second-order cooling pipeline 43, a kettle body cooling casing 44, a water outlet 45, a temperature detector 46, a cooling water inlet pump 47, a water inlet frame 410, a shunting cavity 411, a lifting slide rail 412, a stepped lifting plate 413, a water inlet 414, a stepped cooling mechanism 415, a stepped water sealing plate 416, a stepped flow guide first plate a, a connecting frame b, an anti-overflow mechanism c, a stepped flow guide second plate d, a balance block a1, a movable ring a2, an opening and closing sleeve c1, a lifting track c2, a chute c3, a sleeve water inlet c11, a gravity steel block c12, an extension pipe c13 and a movable ball c 14.

Detailed Description

In order to make the technical means, the original characteristics, the achieved purposes and the effects of the invention easy to understand, the following description and the accompanying drawings further illustrate the preferred embodiments of the invention.

Example one

Referring to fig. 1-4, the invention provides a high polymer coating reaction kettle, which structurally comprises a reaction motor 1, a connecting rotating shaft 2, a reaction kettle body 3, a stepped cooling mechanism 4, a support 5 and a support rod 6, wherein the reaction motor 1 is arranged above the reaction kettle body 3 through the connecting rotating shaft 2, the stepped cooling mechanism 4 is nested on the outer surface of the reaction kettle body 3, the support 5 is fixed on the outer side surface of the stepped cooling mechanism 4 through a nut, and the support rod 6 is fixed at the bottom of the reaction kettle body 3 through a bolt;

the stepped cooling mechanism 4 comprises a water inlet shunting mechanism 41, a first-order cooling pipeline 42, a second-order cooling pipeline 43, a kettle body cooling casing 44, a water outlet 45, a temperature detector 46 and a cooling water inlet pump 47, wherein the water inlet shunting mechanism 41 is embedded into the kettle body cooling casing 44 and is communicated with the first-order cooling pipeline 42 and the second-order cooling pipeline 43, the kettle body cooling casing 44 is nested on the outer surface of the reaction kettle body 3, the first-order cooling pipeline 42 and the second-order cooling pipeline 43 are respectively in an integrated structure with the kettle body cooling casing 44, the first-order cooling pipeline 42 and the second-order cooling pipeline 43 are alternately distributed on the outer surface of the reaction kettle body 3, the kettle body cooling casing 44 is embedded into the inner side of the water outlet 45 and is communicated with the first-order cooling pipeline 42 and the second-order cooling pipeline 43, and the temperature detector 46 is embedded into the kettle body cooling casing 44, cooling intake pump 47 passes through on the bolt fastening cauldron body cooling jacket shell 44 to through pipeline and 41 through connections of reposition of redundant personnel mechanism of intaking, thermodetector 46 passes through circuit and cooling intake pump 47 zonulae occludens, the area of being connected of second order cooling pipeline 43 and reation kettle body 3 is greater than the area of being connected of first order cooling pipeline 42 and reation kettle body 3.

The reposition of redundant personnel mechanism 41 of intaking is including intaking frame 410, reposition of redundant personnel chamber 411, lift slide 412, the elevating plate 413 of stepping, water inlet 414, stepping cooling mechanism 415, stepping water sealing plate 416, the reposition of redundant personnel chamber 411 is located inside the frame 410 of intaking, the reposition of redundant personnel chamber 411 is integrated structure with the frame 410 of intaking, elevating slide 412 one side is located reposition of redundant personnel chamber 411 left side and is intake frame 410 fixed connection, and the opposite side is connected with the cooperation of stepping elevating plate 413, stepping elevating plate 413 left side one end and stepping water sealing plate 416 perpendicular surface are connected, stepping cooling mechanism 415 is equipped with 2 groups to in proper order with stepping elevating plate 413 swing joint.

The stepped temperature reduction mechanism 415 comprises a stepped flow guide first plate a, a connecting frame b, an anti-overflow mechanism c and a stepped flow guide second plate d, wherein the stepped flow guide first plate a and the stepped flow guide second plate d are respectively and movably connected with the stepped lifting plate 413, the stepped flow guide first plate a and the stepped flow guide second plate d are consistent in structure and are distributed in a symmetrical mode, and the anti-overflow mechanism c is arranged between the stepped flow guide first plate a and the stepped flow guide second plate d.

The connection frame b and the stepped lifting plate 413 are of an integrated structure, the connection frame b is provided with 2 connection frames, and the connection frame b is of a frame structure and is connected with the stepped cooling mechanism 415 in a matched mode.

The stepped flow guide first plate a is provided with a balance block a1 and a movable ring a2, the balance block a1 is fixed at the bottom of the stepped flow guide first plate a, the movable ring a2 is nested in the middle of the stepped flow guide first plate a and is in clearance fit with the stepped flow guide first plate a, and the stepped flow guide first plate a is connected with the stepped lifting plate 413 through the movable ring a 2.

The anti-overflow mechanism c comprises an opening and closing sleeve c1, a lifting track c2 and a sliding chute c3, wherein the lifting track c2 is arranged on the inner wall of the rear side of the diversion cavity 411, the sliding chute c3 is connected with the rear side surface of the opening and closing sleeve c1 in a nested mode and is in clearance fit, the sliding chute c3 and the lifting track c2 are of an integrated structure, and the sliding chute c3 is distributed on the front side surface of the lifting track c 2.

When the temperature-reducing device is used, the reaction kettle body 3 is required to be subjected to temperature-reducing treatment, but the temperature-reducing speed is too high, and the temperature difference is large, so that cracks are easily generated on the surface of the reaction kettle body 3 to cause damage, therefore, when the temperature-reducing device is used, the temperature of the reaction kettle body 3 is detected by the temperature detector 46, when the temperature is high, the temperature-reducing water source with low water pressure is pumped into the water inlet shunting mechanism 41 by the line-driven temperature-reducing water inlet pump 47, and the water source is stored in the shunting cavity 411 due to low water pressure at the moment, and after the water level is increased, the water source flows over the connecting frame b, flows into the first-order temperature-reducing pipeline 42 communicated with the shunting cavity 411, flows downwards to the water outlet 45 along the surface of the reaction kettle body 3, and is; when the temperature detector 46 detects that the temperature of the reaction kettle body 3 drops, the temperature detector drives the cooling water inlet pump 47 through a line again to increase the water injection pressure of the water inlet diversion mechanism 41, and under the guidance of the opening sleeve, water flow impacts the first step diversion plate a and the second step diversion plate d, the first step diversion plate a rotates clockwise, the second step diversion plate d rotates anticlockwise, the top of the first step diversion plate a is attached to the top of the second step diversion plate d to form an umbrella shape, a cooling water source is difficult to pass through, the water pressure generates upward pressure to flush the lifting plate 413 and the cooling mechanism 415 connected with the lifting plate, so that the water inlet of the first step cooling pipeline 42 is sealed by the water sealing plate 416, the opening of the second step cooling pipeline 43 is opened, the cooling water source enters the second step cooling pipeline 43 to cool the surface of the reaction kettle body 3 in a large area, through cooling by stages, the damage of the reaction kettle body can be avoided while the cooling speed is improved.

Example two

Referring to fig. 5-6, the present invention provides a polymeric paint reaction kettle, which includes an overflow preventing mechanism c, wherein the overflow preventing mechanism c includes an opening and closing sleeve c1, a lifting rail c2 and a sliding chute c3, the lifting rail c2 is disposed on the inner wall of the rear side of the diversion cavity 411, the sliding chute c3 is nested and connected with the rear side surface of the opening and closing sleeve c1, and is in clearance fit, the sliding chute c3 and the lifting rail c2 are integrated, and the sliding chute c3 is distributed on the front side surface of the lifting rail c 2.

The opening and closing sleeve c1 comprises a sleeve water inlet c11, a gravity steel block c12, an extension pipe c13 and a movable ball c14, the water inlet c11 and the opening and closing sleeve c1 are of an integrated structure, the water inlet c11 is arranged at the bottom of the opening and closing sleeve c1 and is communicated with the inside of the opening and closing sleeve c1, one end of the bottom of the extension pipe c13 is connected with the gravity steel block c12, the movable ball c14 is arranged on the outer side of the opening and closing sleeve c1 and is movably connected with the extension pipe c13, and 2 groups of the extension pipe c13 are arranged and are symmetrically embedded into the opening and closing sleeve c 1.

The gravity steel blocks c12 are provided with 2 and are respectively arranged on two sides inside the opening and closing sleeve c 1.

On the basis of the first embodiment, when the temperature is reduced in the second stage, the temperature reduction water source is prevented from overflowing into the first-stage temperature reduction pipeline 42, the second-stage temperature reduction pipeline 43 can be ensured to be opened smoothly, an overflow prevention mechanism c is additionally arranged, namely, when the water pressure is injected, part of the cooling water source is injected into the opening and closing sleeve c1 through the sleeve water inlet c11 under the action of the water pressure, the gravity steel block c12, the extension pipe c13 and the movable ball c14 are sequentially pushed out towards the outer side to form a V shape, and the opening and closing sleeve c1 moves upward along the lifting track c2 under the water pressure, so that the movable ball c1 is respectively attached to the inner side surfaces of the first step flow guide plate a and the second step flow guide plate d, under the double sealing of the joint of the top of the first stepped flow guiding plate a and the top of the second stepped flow guiding plate d and the joint of the movable ball c1 with the inner side surfaces of the first stepped flow guiding plate a and the second stepped flow guiding plate d respectively, and water is prevented from passing through, so that the stepped lifting plate 413 can move upwards more smoothly under the action of water pressure.

While there have been shown and described what are at present considered the fundamental principles of the invention, the essential features and advantages thereof, it will be understood by those skilled in the art that the present invention is not limited by the embodiments described above, which are merely illustrative of the principles of the invention, but rather, is capable of numerous changes and modifications in various forms without departing from the spirit or essential characteristics thereof, and it is intended that the invention be limited not by the foregoing descriptions, but rather by the appended claims and their equivalents.

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

1. The utility model provides a polymer coating reation kettle, its structure includes reaction motor (1), connects pivot (2), the reation kettle cauldron body (3), hierarchical cooling mechanism (4), support (5), branch (6), reation kettle cauldron body (3) top is located through connecting pivot (2) in reation kettle (1), hierarchical cooling mechanism (4) nestification is in reation kettle cauldron body (3) surface, support (5) are fixed in hierarchical cooling mechanism (4) outside through the nut on the surface, branch (6) are fixed in reation kettle body (3) bottom through the bolt fastening, its characterized in that:

hierarchical cooling mechanism (4) are including intaking reposition of redundant personnel mechanism (41), first-order cooling pipeline (42), second order cooling pipeline (43), cauldron body cooling cover shell (44), delivery port (45), thermodetector (46), cooling intake pump (47), it imbeds cauldron body cooling cover shell (44) and first-order cooling pipeline (42), second order cooling pipeline (43) through connection to intake reposition of redundant personnel mechanism (41), cauldron body cooling cover shell (44) nests in reation kettle body (3) surface, first-order cooling pipeline (42), second order cooling pipeline (43) are the integral structure with cauldron body cooling cover shell (44) respectively, first-order cooling pipeline (42) and second order cooling pipeline (43) alternate distribution are in reation kettle body (3) surface, delivery port (45) inboard embedding cauldron body cooling cover shell (44) and first-order cooling pipeline (42), Second order cooling pipeline (43) through connection, thermodetector (46) embedding cauldron body cooling cover shell (44) are closely laminated with reation kettle body (3) surface and are connected, cooling intake pump (47) are through on bolt fastening cauldron body cooling cover shell (44) to through pipeline and inflow reposition of redundant personnel mechanism (41) through connection, thermodetector (46) are through circuit and cooling intake pump (47) zonulae occludens, the area of connection of second order cooling pipeline (43) and reation kettle body (3) is greater than the area of connection of first order cooling pipeline (42) and reation kettle body (3).

2. The polymer coating reactor of claim 1, wherein: the reposition of redundant personnel mechanism of intaking (41) is including intaking frame (410), reposition of redundant personnel chamber (411), lift slide rail (412), hierarchical lifter plate (413), water inlet (414), hierarchical cooling mechanism (415), hierarchical sealing plate (416), it is inside that frame (410) of intaking is located in reposition of redundant personnel chamber (411), it is the integral structure with frame (410) of intaking to divide the chamber (411), lift slide rail (412) one side is located and is divided chamber (411) left side and frame (410) fixed connection of intaking, and the opposite side is connected with hierarchical lifter plate (413) cooperation, hierarchical lifter plate (413) left side one end is connected with hierarchical sealing plate (416) surface vertical, hierarchical cooling mechanism (415) are equipped with 2 groups to in proper order with hierarchical lifter plate (413) swing joint.

3. The polymer coating reactor of claim 2, wherein: step cooling mechanism (415) is including step water conservancy diversion first board (a), linking frame (b), anti-overflow mechanism (c), step water conservancy diversion second board (d), step water conservancy diversion first board (a), step water conservancy diversion second board (d) respectively with step lifter plate (413) swing joint, step water conservancy diversion first board (a) is unanimous with step water conservancy diversion second board (d) structure to be the symmetric form and distribute, anti-overflow mechanism (c) are located between step water conservancy diversion first board (a) and step water conservancy diversion second board (d).

4. The polymer coating reactor of claim 2, wherein: connection frame (b) are integral structure with stepping lifter plate (413), connection frame (b) are equipped with 2, connection frame (b) are frame construction to be connected with stepping cooling mechanism (415) cooperation.

5. A polymer coating reactor as defined in claim 2 or 3, wherein: the stepped flow guide plate (a) is provided with a balance block (a1) and a movable ring (a2), the balance block (a1) is fixed at the bottom of the stepped flow guide plate (a), the movable ring (a2) is nested in the middle of the stepped flow guide plate (a) and is in clearance fit, and the stepped flow guide plate (a) is connected with a stepped lifting plate (413) through the movable ring (a 2).

6. A polymer coating reactor according to claim 3, wherein: anti-overflow mechanism (c) is including opening and shutting sleeve pipe (c1), lift track (c2), spout (c3), the inner wall of reposition of redundant personnel chamber (411) rear side is located to lift track (c2), spout (c3) and opening and shutting sleeve pipe (c1) rear side surface nestification link to for clearance fit, spout (c3) are the integral structure with lift track (c2), spout (c3) distributes in lift track (c2) front side surface.

7. The polymer coating reactor of claim 6, wherein: the opening and closing sleeve (c1) comprises a sleeve water inlet (c11), a gravity steel block (c12), an extension pipe (c13) and a movable ball (c14), the water inlet (c11) and the opening and closing sleeve (c1) are of an integrated structure, the water inlet (c11) is formed in the bottom of the opening and closing sleeve (c1) and is in through connection with the inside of the opening and closing sleeve (c1), one end of the bottom of the extension pipe (c13) is connected with the gravity steel block (c12), the movable ball (c14) is arranged on the outer side of the opening and closing sleeve (c1) and is movably connected with the extension pipe (c13), and the extension pipe (c13) is provided with 2 groups and is symmetrically embedded and connected to the inside of the opening and closing sleeve (c 1).

8. The polymer coating reactor of claim 7, wherein: the number of the gravity steel blocks (c12) is 2, and the gravity steel blocks are respectively arranged on two sides inside the opening and closing sleeve (c 1).