CN114682201A - Resin reaction kettle - Google Patents

Abstract

The invention discloses a resin reaction kettle, which belongs to the technical field of chemical reaction equipment and comprises a damping rack and a reaction kettle body fixedly arranged on the damping rack, wherein a stirring and mixing component is arranged on the reaction kettle body. Through the convection current subassembly of design, the mixture strand flow that flows in or flows through the flow guide valve pipe, will be used in perpendicularly on the vortex by stirring vane and cutting wheel ring produced, thereby can further increase the mobile orbit of mixture at the internal at reation kettle cauldron, the auxiliary stirring, accelerate stirring speed, further improve stirring effect, can be in higher degree, the reinforcing is to the influence ability of reation kettle internal wall near mixture, on the one hand, do benefit to the degree of consistency that improves the mixture reaction, on the other hand, can avoid being located reation kettle internal wall near slow flow or motionlessness, and influence heat transfer or radiating effect, also can avoid taking place the scale deposit simultaneously, guarantee that heating device has better heat transfer effect all the time.

Description

Resin reaction kettle

Technical Field

The invention belongs to the technical field of chemical reaction equipment, and particularly relates to 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 has wide application, and can be used for painting manufacture and manufacture of other plastics.

The prior art discloses invention patents in the technical field of partial chemical reaction equipment, wherein the invention patent with the application number of CN109225109B discloses a high-efficiency reaction kettle for synthetic resin, and the technical problem solved by the patent is that the production quality of the synthetic resin is influenced due to uneven stirring and mixing of raw materials; meanwhile, in the production process of resin, the conventional synthetic resin device causes uneven heating of raw materials, thereby affecting the production effect of the synthetic resin; so that the technical solution is limited, and the patent has solved the above problems by the mutual cooperation of the structures of the swing unit, the fixing rod, the fixing plate, and the swing plate.

The existing reaction kettle for resin production still has some defects in the using process, in order to improve the synthesis efficiency of resin in the reaction kettle, a mechanical stirring mechanism is usually added in the reaction kettle, in order to reduce the resistance of the mechanical stirring mechanism and simultaneously improve the stability of the reaction kettle, the working coverage range of the added mechanical stirring mechanism is smaller than the inner diameter size of the reaction kettle, so that the mixing flow rate of resin raw materials flowing near the wall body of the reaction kettle is slow, the preparation efficiency and the product quality of the resin reaction kettle are seriously influenced, and the mechanical stirring mechanism turns to a certain degree, so that the flow direction of a mixed material in the reaction kettle is single, and the poor layering phenomenon is easy to occur.

Based on the technical scheme, the invention designs the resin reaction kettle to solve the problems.

Disclosure of Invention

The invention aims to: the resin reaction kettle is provided for solving the problems that the prior reaction kettle for resin production still has some defects in the using process, a mechanical stirring mechanism is usually additionally arranged in the reaction kettle for improving the synthesis efficiency of resin in the reaction kettle, the working coverage range of the additionally arranged mechanical stirring mechanism is smaller than the inner diameter size of the reaction kettle for reducing the resistance of the mechanical stirring mechanism and improving the stability of the reaction kettle, so that the mixing flow rate of resin raw materials flowing near the wall body of the reaction kettle is slow, the preparation efficiency and the product quality of the resin reaction kettle are seriously influenced, and the flow direction of a mixture in the reaction kettle is single due to the fact that the mechanical stirring mechanism turns to a certain direction, and the phenomenon of poor layering is easy to occur.

In order to achieve the purpose, the invention adopts the following technical scheme:

a resin reaction kettle comprises a damping rack and a reaction kettle body fixedly arranged on the damping rack, wherein a stirring and mixing assembly is arranged on the reaction kettle body, a convection assembly is fixedly connected to the position, corresponding to the stirring and mixing assembly, inside the reaction kettle body, and a flow control assembly is further arranged at the position, corresponding to the convection assembly, on the surface of the stirring and mixing assembly;

the convection current subassembly is including sliding the adapter sleeve, sliding the adapter sleeve and sliding the surface of cup jointing at drive formula stirring main shaft, sliding fixed cover on the extrados of adapter sleeve and having connect sealed piston disc, the top of sealed piston disc is a plurality of wedge seats of annular array fixedly connected with, the top fixedly connected with power conversion device of wedge seat, power conversion device keeps away from the one end fixed connection of wedge seat on the surface of drive formula stirring main shaft.

As a further description of the above technical solution:

the stirring mixing assembly comprises a driving type stirring main shaft, the driving type stirring main shaft is rotatably connected to the top of the inner side of the reaction kettle body, a plurality of passing connecting holes are formed in the position, corresponding to the inner portion of the reaction kettle body, of the surface of the driving type stirring main shaft, a switching sleeve is fixedly connected to the position, corresponding to the passing connecting holes, of the surface of the driving type stirring main shaft, a plurality of stirring blades are connected to the outer arc surface of the switching sleeve in a clamped mode, and one end, far away from the switching sleeve, of each stirring blade is communicated with a cutting wheel ring.

As a further description of the above technical solution:

the top of drive formula stirring main shaft and electric motor's output shaft fixed connection, the top at the reation kettle cauldron body is passed through frame fixed connection in the surface of electric motor fuselage, and the position of a plurality of through connecting holes need be according to the internal portion's of reation kettle structure setting.

As a further description of the above technical solution:

and a gas-liquid separation membrane is embedded into a port at one end of the gas pipeline, which is far away from the driving stirring main shaft.

As a further description of the above technical solution:

the utility model discloses a sealed piston disc's of reation kettle cauldron internal side wall, including sealed piston disc, sealed piston disc's position department, the sealed piston disc's of internal side wall of reation kettle, the sealed piston disc's of internal side wall department of corresponding on the reation kettle cauldron, first sliding connection has first sliding connection seat in the first sliding connection groove, the opposite face fixed connection of first sliding connection seat and sealed piston disc to the first sliding connection inboard corresponds the embedded first supporting spring that is connected with of position department of first sliding connection seat, first supporting spring's one end fixed connection is on the inside wall of first sliding connection groove, the other end and the first one side fixed connection that slides the connecting seat and is close.

As a further description of the above technical solution:

the power conversion device comprises a bridge-shaped connecting frame, one end of the bridge-shaped connecting frame is fixedly connected to the surface of the driving type stirring main shaft, a telescopic sleeve is sleeved at the other end of the bridge-shaped connecting frame, a spherical hoop sleeve is fixedly connected to the bottom end of the telescopic sleeve, a rolling ball is connected to the interior of the spherical hoop sleeve in a rolling mode, and the rolling ball is connected to the inclined plane of the wedge-shaped seat in a rolling mode.

As a further description of the above technical solution:

the wedge seat is set to two inclined planes along the rolling direction of the rolling ball, a second sliding connecting groove is formed in the position, corresponding to the bridge-type connecting frame, on the inner side wall of the telescopic sleeve, a second sliding connecting seat is connected to the inner side wall of the telescopic sleeve in a sliding mode, and the end face of the second sliding connecting seat is fixedly connected with the end face of the inner side of the second sliding connecting groove through a second supporting spring.

As a further description of the above technical solution:

the flow control assembly comprises a drainage valve pipe, the drainage valve pipe is clamped at the position, corresponding to the stirring blades, on the outer arc surface of the cutting wheel ring, a funnel-shaped cover is fixedly connected into a port, far away from one end of the cutting wheel ring, of the drainage valve pipe, a hemispheroid is connected with the inner side of the funnel-shaped cover in an embedded mode, and a circulation hole is formed in the position, corresponding to the funnel-shaped cover, on the spherical surface of the hemispheroid.

As a further description of the above technical solution:

fixedly connected with linkage seat on the hemisphere deviates from the one side of fill shape cover, the position department that corresponds linkage seat on the drainage valve pipe inside wall has seted up the third and has slided the spread groove, sliding connection has the third to slide the spread groove and slide the connecting seat in the third, the terminal surface department that the third slided the connecting seat passes through the terminal surface fixed connection that third supporting spring slided the spread groove inboard with the third.

As a further description of the above technical solution:

the surface joint of the reation kettle cauldron body has raw materials to introduce the pipeline, the port of raw materials introduction pipeline is located the below of sealed piston dish, be provided with first control valve on the raw materials introduction pipeline, the bottom joint of the reation kettle cauldron body has resin product to draw forth the pipeline, be provided with the second control valve on the resin product draws forth the pipeline.

In summary, due to the adoption of the technical scheme, the invention has the beneficial effects that:

1. in the invention, through the designed convection assembly, the driving type stirring main shaft can drive the power conversion device and the wedge-shaped seat to generate relative motion in the process of fast rotation, when a rolling ball arranged in the power conversion device rolls upwards along one inclined surface of the wedge-shaped seat, the sealed piston disc can slide downwards in the first sliding connecting groove through the first sliding connecting seat and apply pressure on the second supporting spring, the air pressure intensity corresponding to the upper part of the sealed piston disc in the reaction kettle body can be gradually reduced along with the downward movement of the sealed piston disc and tends to be in a negative pressure state, the hemisphere can move towards the direction far away from the hopper-shaped cover according to the negative pressure drainage effect, the flow of the drainage valve pipe in unit time can be further increased, when the rolling ball rolls downwards along the other inclined surface of the wedge-shaped seat, the pressure acted on the wedge-shaped seat by the rolling ball is gradually reduced, under the action of the restoring elasticity of the first supporting spring, the first sliding connecting seat is pushed to drive the sealed piston disc to slide upwards in the first sliding connecting groove, under the action effect of the sealed piston disc, the air pressure strength of the position, corresponding to the upper part of the sealed piston disc, in the reaction kettle body is quickly enhanced, under the pushing of high air pressure, the mixture flowing into the driving type stirring main shaft through the flow control assembly is quickly returned and sprayed out, and the mixture flow flowing into or out through the drainage valve pipe is vertically acted on vortex generated by the stirring blades and the cutting wheel ring, so that the flow track of the mixture in the reaction kettle body can be further increased, the stirring speed is increased, the stirring effect is further improved, the influence on the mixture near the inner wall of the reaction kettle body can be enhanced to a higher degree, on the one hand, do benefit to the degree of consistency that improves the mixture reaction, on the other hand can avoid being located near the internal wall of reation kettle slow flow or the motionlessness, and influence heat transfer or radiating effect, also can avoid taking place the scale deposit simultaneously, guarantees that heating device has better heat transfer effect all the time.

2. According to the invention, the operation of the electric motor is controlled through the designed stirring and mixing component, when the electric motor works, the output shaft of the electric motor drives the driving type stirring main shaft to rapidly rotate in the reaction kettle body, the plurality of adapter sleeves and the stirring blades rapidly rotate in the reaction kettle body under the driving of the driving type stirring main shaft, and meanwhile, the cutting wheel ring shears fluid generated by the common centrifugal action of the driving type stirring main shaft, the adapter sleeves and the stirring blades under the driving of the stirring blades, so that a strong vortex is formed in the reaction kettle body under the auxiliary effect of the cutting wheel ring, and the stirring effect is further improved.

3. According to the invention, through the designed gas-liquid separation membrane and the designed vent pipeline, the vent pipeline is used for communicating the driving stirring main shaft and the reaction kettle body, so that the circulation and the conversion of gas flow are facilitated, and the gas-liquid separation membrane is used for realizing the separation between gas and colloidal fluid, so that the mixture in the reaction kettle body is prevented from entering the sealed piston disc.

Drawings

FIG. 1 is a schematic view of the overall structure of a resin reaction kettle according to the present invention;

FIG. 2 is a schematic structural view of a sectional view of a reaction kettle body in a resin reaction kettle according to the present invention;

FIG. 3 is an enlarged schematic structural view of a position A in a resin reaction kettle according to the present invention;

FIG. 4 is a schematic structural view of a driving stirring main shaft in a resin reaction kettle according to the present invention;

FIG. 5 is a schematic cross-sectional view of a power conversion apparatus in a resin reaction vessel according to the present invention;

FIG. 6 is an enlarged schematic structural view of a position B in a resin reaction kettle according to the present invention;

fig. 7 is a schematic cross-sectional structural view of a flow control assembly in a resin reaction kettle according to the present invention.

Illustration of the drawings:

1. a shock-absorbing frame; 2. a reaction kettle body; 3. a stirring and mixing assembly; 301. a driving type stirring main shaft; 302. an electric motor; 303. an adapter sleeve; 304. a stirring blade; 305. cutting the wheel ring; 4. a convection assembly; 401. a sliding connecting sleeve; 402. a sealed piston disc; 403. a first sliding connection seat; 404. a first sliding connecting groove; 405. a first support spring; 406. a wedge seat; 407. a power conversion device; 4071. a bridge-type connecting frame; 4072. a telescoping sleeve; 4073. a second sliding connection seat; 4074. a second sliding connecting groove; 4075. a second support spring; 4076. a spherical hoop sleeve; 4077. rolling the beads; 408. an air duct; 409. a gas-liquid separation membrane; 5. a flow control assembly; 501. a drain valve tube; 502. a bucket shaped cover; 503. a hemisphere; 504. a flow-through hole; 505. a linkage seat; 506. a third sliding connection seat; 507. a third sliding connecting groove; 508. a third support spring; 6. a feedstock introduction conduit; 7. a first control valve; 8. a resin product outlet pipe; 9. a second control valve.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-7, the present invention provides a technical solution: a resin reaction kettle comprises a damping rack 1 and a reaction kettle body 2 fixedly mounted on the damping rack 1, wherein a stirring and mixing assembly 3 is mounted on the reaction kettle body 2, a convection assembly 4 is fixedly connected to the position, corresponding to the stirring and mixing assembly 3, inside the reaction kettle body 2, and a flow control assembly 5 is further arranged at the position, corresponding to the convection assembly 4, on the surface of the stirring and mixing assembly 3;

the convection assembly 4 comprises a sliding connecting sleeve 401, the sliding connecting sleeve 401 is sleeved on the surface of the driving type stirring main shaft 301 in a sliding manner, a sealing type piston disc 402 is fixedly sleeved on the outer arc surface of the sliding connecting sleeve 401, the top of the sealing type piston disc 402 is fixedly connected with a plurality of wedge-shaped seats 406 in an annular array manner, a power conversion device 407 is fixedly connected above the wedge-shaped seats 406, and one end, far away from the wedge-shaped seats 406, of the power conversion device 407 is fixedly connected on the surface of the driving type stirring main shaft 301.

Specifically, as shown in fig. 2, stirring hybrid module 3 includes drive formula stirring main shaft 301, drive formula stirring main shaft 301 rotates the top of connecting at the internal side of reation kettle cauldron 2, a plurality of connecting holes of passing have been seted up to drive formula stirring main shaft 301 surface corresponding reation kettle cauldron body 2 inside position department, and the fixed cover of drive formula stirring main shaft 301 surface corresponding position department of passing the connecting hole has connect adapter sleeve 303, the joint has a plurality of stirring vane 304 on the extrados of adapter sleeve 303, the one end intercommunication that adapter sleeve 303 was kept away from to stirring vane 304 has cutting wheel ring 305.

The implementation mode is specifically as follows: the electric motor 302 is controlled to operate, when the electric motor 302 works, an output shaft of the electric motor 302 drives the driving type stirring main shaft 301 to rotate rapidly in the reaction kettle body 2, under the driving of the driving type stirring main shaft 301, the plurality of adapter sleeves 303 and the stirring blades 304 rotate rapidly in the reaction kettle body 2, meanwhile, under the driving of the stirring blades 304, the cutting wheel ring 305 shears fluid generated by the common centrifugal action of the driving type stirring main shaft 301, the adapter sleeves 303 and the stirring blades 304, and under the auxiliary effect of the cutting wheel ring 305, a strong vortex is formed in the reaction kettle body 2.

Specifically, as shown in fig. 2, the top end of the driving stirring main shaft 301 is fixedly connected to an output shaft of the electric motor 302, the surface of the body of the electric motor 302 is fixedly connected to the top of the reaction kettle body 2 through a frame, the positions of the plurality of through connection holes need to be set according to the structure inside the reaction kettle body 2, the surface of the driving stirring main shaft 301 is further clamped with a ventilation pipe 408, and a gas-liquid separation membrane 409 is embedded in a port of the ventilation pipe 408 at one end away from the driving stirring main shaft 301.

The implementation mode is specifically as follows: the vent pipe 408 is used for communicating the driving type stirring main shaft 301 with the reaction kettle body 2, so that the air flow can be conveniently circulated and converted, and the gas-liquid separation membrane 409 is used for separating gas from colloidal fluid, so that the mixture in the reaction kettle body 2 is prevented from entering the sealed piston disc 402.

Specifically, as shown in fig. 2 and 3, a first sliding connection groove 404 is formed in a position on the inner side wall of the reaction kettle body 2 corresponding to the sealed piston disc 402, a first sliding connection seat 403 is slidably connected in the first sliding connection groove 404, the first sliding connection seat 403 is fixedly connected with the opposite surface of the sealed piston disc 402, a first support spring 405 is embedded in a position on the inner side of the first sliding connection groove 404 corresponding to the first sliding connection seat 403, one end of the first support spring 405 is fixedly connected to the inner side wall of the first sliding connection groove 404, and the other end of the first support spring 405 is fixedly connected with the close surface of the first sliding connection seat 403.

The implementation mode is specifically as follows: during the process of fast rotation of the driving stirring spindle 301, the driving stirring spindle will also drive the power conversion device 407 and the wedge base 406 to make relative motion, when the rolling ball 4077 arranged in the power conversion device 407 rolls upwards along one inclined surface of the wedge base 406, the sealing piston disc 402 will slide downwards in the first sliding connection groove 404 through the first sliding connection seat 403 and apply pressure on the second support spring 4075, as the sealing piston disc 402 moves downwards, the strength of the air pressure inside the reaction kettle body 2 corresponding to the upper side of the sealing piston disc 402 will gradually decrease, when the rolling ball 4077 rolls downwards along the other inclined surface of the wedge base 406, because the pressure of the rolling ball 4077 acting on the wedge base 406 gradually decreases, under the action of the restoring elastic force of the first support spring 405, the first sliding connection seat 403 will be pushed to drive the sealing piston disc 402 to slide upwards and fast in the first sliding connection groove 404, under the action effect of the sealed piston disc 402, the air pressure strength in the reaction kettle body 2 corresponding to the position above the sealed piston disc 402 will be rapidly enhanced, under the pushing of high air pressure, the mixture flowing into the driving type stirring main shaft 301 through the flow control assembly 5 will rapidly flow back and be sprayed out, and the mixture flow flowing into or out through the drainage valve pipe 501 will vertically act on the vortex generated by the stirring blades 304 and the cutting wheel ring 305, so that the flow path of the mixture in the reaction kettle body 2 can be further increased.

Specifically, as shown in fig. 5 and 6, the power conversion device 407 includes a bridge-shaped connecting frame 4071, one end of the bridge-shaped connecting frame 4071 is fixedly connected to the surface of the driving-type stirring main shaft 301, a telescopic sleeve 4072 is sleeved on the other end of the bridge-shaped connecting frame 4071, a spherical hoop 4076 is fixedly connected to the bottom end of the telescopic sleeve 4072, a rolling ball 4077 is connected to the spherical hoop 4076 in a rolling manner, the rolling ball 4077 is connected to the inclined surface of the wedge-shaped seat 406 in a rolling manner, the wedge-shaped seat 406 is set to be two inclined surfaces along the rolling direction of the rolling ball 4077, a second sliding connecting groove 4074 is formed in a position on the inner side wall of the telescopic sleeve 4072 corresponding to the bridge-shaped connecting frame 4071, a second sliding connecting seat 4073 is slidably connected to the second sliding connecting groove 4074, and the end surface of the second sliding connecting seat 4073 is fixedly connected to the end surface of the inner side of the second sliding connecting groove 4074 through a second support spring 4075.

Specifically, as shown in fig. 7, the flow control assembly 5 includes a drainage valve pipe 501, the drainage valve pipe 501 is connected to the position corresponding to the stirring blade 304 on the outer arc surface of the cutting wheel ring 305 in a clamping manner, a funnel-shaped cover 502 is fixedly connected to the port of the drainage valve pipe 501 far away from one end of the cutting wheel ring 305, a hemisphere 503 is connected to the inner side of the funnel-shaped cover 502 in an embedded manner, a circulation hole 504 is formed in the position corresponding to the funnel-shaped cover 502 on the spherical surface of the hemisphere 503, a linkage seat 505 is fixedly connected to the side of the hemisphere 503 far away from the funnel-shaped cover 502, a third sliding connection groove 507 is formed in the position corresponding to the linkage seat 505 on the inner side wall of the drainage valve pipe 501, a third sliding connection seat 506 is slidably connected to the third sliding connection groove 507, and the end face of the third sliding connection seat 506 is fixedly connected to the end face of the third sliding connection groove 507 through a third support spring 508.

The implementation mode is specifically as follows: the air pressure intensity inside the reaction kettle body 2 corresponding to the upper part of the sealed piston disc 402 will gradually decrease and tend to be in a negative pressure state, and according to the negative pressure drainage effect, the hemisphere 503 will move towards the direction far away from the hopper-shaped cover 502, so that the flow of the drainage valve pipe 501 in unit time can be increased.

Specifically, as shown in fig. 1, a raw material introducing pipe 6 is clamped on the surface of the reaction kettle body 2, a port of the raw material introducing pipe 6 is located below the sealed piston disc 402, a first control valve 7 is arranged on the raw material introducing pipe 6, a resin product leading pipe 8 is clamped at the bottom of the reaction kettle body 2, and a second control valve 9 is arranged on the resin product leading pipe 8.

The implementation mode is specifically as follows: opening first control valve 7, alright leading-in the inside of the reation kettle cauldron body 2 with the resin production batching through raw materials inlet line 6, opening second control valve 9, just can utilize the resin product stand-off pipe to discharge the resin of producing.

The working principle is as follows: when the electric stirring kettle is used, the electric motor 302 is controlled to operate, when the electric motor 302 works, an output shaft of the electric motor 302 drives the driving type stirring main shaft 301 to rotate rapidly in the reaction kettle body 2, the plurality of adapter sleeves 303 and the stirring blades 304 are driven by the driving type stirring main shaft 301 to rotate rapidly in the reaction kettle body 2, meanwhile, the cutting wheel ring 305 is driven by the stirring blades 304 to cut fluid generated by the centrifugal action of the driving type stirring main shaft 301, the adapter sleeves 303 and the stirring blades 304, under the auxiliary effect of the cutting wheel ring 305, a strong vortex is formed in the reaction kettle body 2, the stirring effect is further improved, the driving type stirring main shaft 301 also drives the power conversion device 407 and the wedge-shaped seat 406 to move relatively in the process of rotating rapidly, and when the rolling beads 4077 arranged in the power conversion device 407 rolls upwards along an inclined plane of the wedge-shaped seat 406, the sealed piston disc 402 will slide downwards in the first sliding connection groove 404 through the first sliding connection seat 403 and exert pressure on the second support spring 4075, as the sealed piston disc 402 moves downwards, the air pressure inside the reaction kettle 2 corresponding to the upper portion of the sealed piston disc 402 will gradually decrease and tend to be in a negative pressure state, according to the negative pressure drainage effect, the hemisphere 503 will move towards the direction away from the hopper-shaped cover 502, and further the flow rate of the drainage valve pipe 501 in unit time can be increased, when the rolling ball 4077 rolls downwards along the other inclined surface of the wedge-shaped seat 406, because the pressure of the rolling ball 4077 acting on the wedge-shaped seat 406 gradually decreases, under the action of the restoring elastic force of the first support spring 405, the first sliding connection seat 403 will be pushed to drive the sealed piston disc 402 to slide upwards in the first sliding connection groove 404 rapidly, under the action effect of the sealed piston disc 402, the air pressure intensity in the reaction kettle body 2 corresponding to the position above the sealed piston disc 402 will be rapidly enhanced, under the push of high air pressure, the mixture flowing into the driving type stirring main shaft 301 through the flow control assembly 5 will rapidly flow back and be ejected, the mixture stream flowing into or out through the drainage valve pipe 501 will vertically act on the vortex generated by the stirring blade 304 and the cutting wheel ring 305, thereby further increasing the flow track of the mixture in the reaction kettle body 2, assisting the stirring, accelerating the stirring speed, further improving the stirring effect, enhancing the influence capability on the mixture near the inner wall of the reaction kettle body 2 at a higher degree, on one hand, being beneficial to improving the reaction uniformity of the mixture, on the other hand, avoiding the influence on the heat transfer or heat dissipation effect due to the slow flow or standing still near the inner wall of the reaction kettle body 2, meanwhile, scaling can be avoided, and the heating device is guaranteed to have a good heat transfer effect all the time.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be able to cover the technical scope of the present invention and the equivalent alternatives or modifications according to the technical solution and the inventive concept of the present invention within the technical scope of the present invention.

Claims (10)

1. The utility model provides a resin reaction kettle, includes that shock attenuation frame (1) and shock attenuation frame (1) go up fixed mounting's the reation kettle cauldron body (2), install stirring on the reation kettle cauldron body (2) and mix subassembly (3) to the inside fixedly connected with convection current subassembly (4) of position department that corresponds stirring and mix subassembly (3) of reation kettle cauldron body (2), the position department that stirring mixes subassembly (3) surface correspondence convection current subassembly (4) still is provided with flow control subassembly (5), its characterized in that:

convection current subassembly (4) are including sliding connection cover (401), stirring hybrid module (3) are including drive formula stirring main shaft (301) to sliding connection cover (401) slip the surface of cup jointing at drive formula stirring main shaft (301), fixed cup jointing has sealed piston disc (402) on the extrados of sliding connection cover (401), the top of sealed piston disc (402) is a plurality of wedge seats (406) of annular array fixedly connected with, the top fixedly connected with power conversion device (407) of wedge seat (406), one end fixed connection that wedge seat (406) were kept away from in power conversion device (407) is on the surface of drive formula stirring main shaft (301).

2. The resin reaction kettle according to claim 1, wherein the driving type stirring main shaft (301) is rotatably connected to the top of the inner side of the reaction kettle body (2), a plurality of through connecting holes are formed in the surface of the driving type stirring main shaft (301) corresponding to the position inside the reaction kettle body (2), a switching sleeve (303) is fixedly sleeved on the surface of the driving type stirring main shaft (301) corresponding to the position of the through connecting holes, a plurality of stirring blades (304) are clamped on the extrados surface of the switching sleeve (303), and one ends, far away from the switching sleeve (303), of the stirring blades (304) are communicated with a cutting wheel ring (305).

3. A resin reactor according to claim 2, wherein the top end of the driving stirring main shaft (301) is fixedly connected with the output shaft of the electric motor (302), the surface of the body of the electric motor (302) is fixedly connected with the top of the reactor body (2) through the frame, and the positions of the plurality of through connection holes need to be set according to the structure inside the reactor body (2).

4. The resin reaction kettle according to claim 1, wherein a vent pipe (408) is further clamped on the surface of the driving stirring main shaft (301), and a gas-liquid separation membrane (409) is embedded in a port of the vent pipe (408) far away from one end of the driving stirring main shaft (301).

5. A resin reactor according to claim 4, wherein the inner side wall of the reactor body (2) is provided with a first sliding connecting groove (404) at a position corresponding to the sealed piston disc (402), the first sliding connecting groove (404) is slidably connected with a first sliding connecting seat (403), the opposite surfaces of the first sliding connecting seat (403) and the sealed piston disc (402) are fixedly connected, a first supporting spring (405) is embedded at a position corresponding to the first sliding connecting seat (403) at the inner side of the first sliding connecting groove (404), one end of the first supporting spring (405) is fixedly connected to the inner side wall of the first sliding connecting groove (404), and the other end of the first supporting spring (405) is fixedly connected with a surface close to the first sliding connecting seat (403).

6. A resin reactor according to claim 1, wherein the power conversion device (407) comprises a bridge-shaped connecting frame (4071), one end of the bridge-shaped connecting frame (4071) is fixedly connected to the surface of the driving stirring main shaft (301), the other end of the bridge-shaped connecting frame (4071) is sleeved with a telescopic sleeve (4072), the bottom end of the telescopic sleeve (4072) is fixedly connected with a spherical hoop (4076), a rolling ball (4077) is roll-connected in the spherical hoop (4076), and the rolling ball (4077) is roll-connected to the inclined surface of the wedge seat (406).

7. A resin reactor according to claim 6, wherein the wedge base (406) is configured as two inclined surfaces along the rolling direction of the rolling ball (4077), a second sliding connecting groove (4074) is formed on the inner side wall of the telescopic sleeve (4072) at a position corresponding to the bridge-type connecting frame (4071), a second sliding connecting seat (4073) is slidably connected in the second sliding connecting groove (4074), and the end surface of the second sliding connecting seat (4073) is fixedly connected with the end surface inside the second sliding connecting groove (4074) through a second supporting spring (4075).

8. The resin reaction kettle according to claim 1, wherein the flow control assembly (5) comprises a drainage valve pipe (501), the drainage valve pipe (501) is clamped at a position corresponding to the stirring blade (304) on the outer arc surface of the cutting wheel ring (305), a hopper-shaped cover (502) is fixedly connected in a port of one end of the drainage valve pipe (501) far away from the cutting wheel ring (305), a hemisphere (503) is connected in an embedded manner on the inner side of the hopper-shaped cover (502), and a circulation hole (504) is formed in a position corresponding to the hopper-shaped cover (502) on the spherical surface of the hemisphere (503).

9. The resin reaction kettle according to claim 8, wherein a linkage seat (505) is fixedly connected to one surface of the hemisphere (503) departing from the hopper-shaped cover (502), a third sliding connection groove (507) is formed in the inner side wall of the drainage valve tube (501) at a position corresponding to the linkage seat (505), the third sliding connection groove (507) is slidably connected with a third sliding connection seat (506), and the end surface of the third sliding connection seat (506) is fixedly connected with the end surface of the inner side of the third sliding connection groove (507) through a third support spring (508).

10. A resin reaction kettle according to claim 1, wherein a raw material introducing pipeline (6) is clamped on the surface of the reaction kettle body (2), a port of the raw material introducing pipeline (6) is positioned below the sealed piston disc (402), a first control valve (7) is arranged on the raw material introducing pipeline (6), a resin product leading-out pipeline (8) is clamped at the bottom of the reaction kettle body (2), and a second control valve (9) is arranged on the resin product leading-out pipeline (8).

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