CN215389152U - Tubular reactor for continuous feeding reaction - Google Patents

Abstract

The utility model discloses a tubular reactor for continuous feeding reaction, which comprises a fixed frame, a mixing pipe, a discharging pipe, a stirring fin, a stirring rod, a second piston and a communicating pipe, wherein the mixing pipe is arranged at the bottom side of a transverse plate at the top of the fixed frame, one end of the mixing pipe is provided with a stirring motor, a plurality of partition plates are arranged on the upper inner wall and the lower inner wall of the mixing pipe in parallel, the stirring rod is arranged at the output end part of the stirring motor, the stirring rod sequentially penetrates through the interiors of the partition plates, the stirring fin is arranged on the stirring rod, the discharging pipe is arranged on the circumferential wall at the other end of the mixing pipe, when the materials are stirred, the materials are added into the mixing pipe, the stirring motor works to drive the stirring rod to rotate, under the matching of the stirring fin and the partition plates, the materials can be stirred and mixed in an S-shaped flowing manner, a better mixing effect can be achieved, and the continuous feeding and mixing without stopping the machine can be achieved, and continuous operation is realized, and better mixing efficiency is achieved.

Description

Tubular reactor for continuous feeding reaction

Technical Field

The utility model relates to the field of chemical equipment, in particular to a tubular reactor for continuous feeding reaction.

Background

The kettle type reactor is also called as a reaction kettle or a stirring reactor, the height of the kettle type reactor is generally equal to or slightly higher than the diameter of the kettle and is about 2 to 3 times of the diameter, a stirring device and a baffle are arranged in the kettle, a heat exchanger is arranged in the kettle according to different conditions to maintain the required reaction temperature, the heat exchanger can also be arranged outside the kettle to exchange heat through forced circulation of fluid, the existing equipment uses the kettle type reactor, the reaction time is long, the reaction feeding equivalent ratio is excessive by about 50 percent, the three wastes amount is large, the continuous feeding cannot be realized, and the feeding quality cannot be accurately controlled in the feeding process.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a tubular reactor for continuous feeding reaction, which solves the technical problems that the existing equipment uses a kettle type reactor, the reaction time is long, the reaction feeding equivalent ratio is too large and about 50 percent excessive, the three wastes are large, the continuous feeding cannot be realized, and the feeding quality cannot be accurately controlled in the feeding process.

The purpose of the utility model can be realized by the following technical scheme:

a tubular reactor for continuous feeding reaction comprises a fixing frame, a mixing pipe, a discharging pipe, a mixing wing, a mixing rod, a mixing motor, partition plates, a storage box, a supporting frame, a first spring, a limiting ball, a scale rod, a slide bar, a guide tank, a vacuum pump, a guide pipe, a lead screw, a guide motor, a screw, a middle rotary drum, a material barrel, a second spring, a first piston, a second piston and a communicating pipe, wherein the mixing pipe is arranged at the bottom side of a top transverse plate of the fixing frame, the mixing motor is arranged at one end of the mixing pipe, the partition plates are arranged on the upper inner wall and the lower inner wall of the mixing pipe in parallel, the mixing rod is arranged at the output end part of the mixing motor and sequentially penetrates through the partition plates, the mixing wing is arranged on the mixing rod, the discharging pipe is arranged on the circumferential wall at the other end of the mixing pipe, the supporting frame is welded at the top side of the fixing frame, the scale rod is vertically penetrated in the top transverse plate of the supporting frame, the top of scalar pole is fixed with spacing ball, first spring housing is established in the top outside of scalar pole, the scalar pole is vertical to be installed on the support frame, the vacuum pump is installed on the support frame, the top side at the mount is established to the guide pipe support, the one end at the passage is installed to the guide motor, install the lead screw in the pivot of guide motor.

As a further scheme of the utility model: the gauge rod and the sliding rod are arranged in parallel, the material storage box is communicated with the material guide tank through a guide pipe, and a valve is arranged on the guide pipe.

As a further scheme of the utility model: the emptying port of the vacuum pump is connected with the material storage tank through a hose, and the bottom end of the material guide tank is connected with the material guide pipe through a hose.

As a further scheme of the utility model: the middle rotary drum and the material barrel are arranged on the top side of the fixing frame in parallel, the first piston and the second piston are respectively arranged inside the middle rotary drum and the material barrel, a second spring is fixed between the second piston and the top side barrel wall of the material barrel, a screw rod is arranged on the top side of the first piston, and the screw rod is arranged in the top side barrel wall of the middle rotary drum in a penetrating mode through threaded fit.

As a further scheme of the utility model: and a valve is arranged on the communicating pipe.

As a further scheme of the utility model: the material guide pipe and the middle rotary drum are respectively communicated with the material mixing pipe through guide pipes.

The utility model has the beneficial effects that: the method comprises the steps that a powdery reagent is placed in a storage box, when materials enter a material guide tank, the overall mass of the material guide tank is increased, a slide rod is driven to slide downwards, the position of a marking rod is aligned through a limiting ball, the material mass of the material guide tank can be judged according to the spring coefficient of a first spring, the material can be accurately controlled to supplement the mass, the liquid materials are stored in a material barrel, when the material guide tank is used, a screw rod is rotated, a first piston is driven to slide, the volume of the materials is set, a valve on a communicating pipe is opened, the materials enter a middle rotating barrel, the materials in the middle rotating barrel can be accurately limited, the materials can be accurately thrown in the middle rotating barrel, and the accurate material proportioning is guaranteed;

when the compounding stirring, in adding the compounding pipe with the material, the agitator motor operation drives the puddler rotation, under the cooperation of stirring wing and baffle, can realize that the material is "S" type flow stirring and mixes, reaches better mixed effect, at the flow mixing in-process, can realize not shutting down the continuous feed and mix, realizes continuity operation, reaches better compounding efficiency.

Drawings

In order to facilitate understanding for those skilled in the art, the present invention will be further described with reference to the accompanying drawings.

FIG. 1 is an overall front perspective view of the present invention;

FIG. 2 is a perspective overall side view of the present invention;

FIG. 3 is an overall internal structural view of the present invention;

in the figure: 1. a fixed mount; 2. a mixing pipe; 3. a discharge pipe; 4. stirring fins; 5. a stirring rod; 6. a stirring motor; 7. a partition plate; 8. a material storage box; 9. a support frame; 10. a first spring; 11. a limiting ball; 12. a gauge rod; 13. a slide bar; 14. a material guiding tank; 15. a vacuum pump; 16. a material guide pipe; 17. a screw rod; 18. a material guiding motor; 19. a screw; 20. a middle rotating cylinder; 21. a material cylinder; 22. a second spring; 23. a first piston; 24. a second piston; 25. a communication pipe is provided.

Detailed Description

The technical solutions of the present invention will be described clearly and completely with reference to the following embodiments, and it should be understood 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.

As shown in fig. 1-3, a tubular reactor for continuous feeding reaction comprises a fixed frame 1, a mixing tube 2, a discharging tube 3, a mixing fin 4, a stirring rod 5, a stirring motor 6, a partition plate 7, a material storage tank 8, a support frame 9, a first spring 10, a limiting ball 11, a scalar rod 12, a slide rod 13, a material guide tank 14, a vacuum pump 15, a material guide tube 16, a screw rod 17, a material guide motor 18, a screw rod 19, a transfer cylinder 20, a material cylinder 21, a second spring 22, a first piston 23, a second piston 24 and a communicating tube 25, wherein the mixing tube 2 is installed on the bottom side of a transverse plate at the top of the fixed frame 1, the stirring motor 6 is installed at one end of the mixing tube 2, a plurality of partition plates 7 are installed in parallel on the upper and lower inner walls of the mixing tube 2, the stirring rod 5 is installed at the output end of the stirring motor 6, the stirring rod 5 sequentially penetrates through the partition plates 7, the mixing fin 4 is installed on the stirring rod 5, the discharging tube 3 is installed at the other end of the circumferential wall of the mixing tube 2, support frame 9 welds the dress in the top side of mount 1, and in the top diaphragm of support frame 9 was vertically worn to establish by mark measuring pole 12, the top of mark measuring pole 12 was fixed with spacing ball 11, and first spring 10 cover was established outside the top of mark measuring pole 12, and mark measuring pole 12 is vertical to be installed on support frame 9, and vacuum pump 15 installs on support frame 9, and the top side at mount 1 is erect to passage 16, and the one end at passage 16 is installed to guide motor 18, installs lead screw 17 in the pivot of guide motor 18.

The gauge rod 12 and the slide bar 13 are arranged in parallel, the storage tank 8 is communicated with the guide tank 14 through a guide pipe, a valve is installed on the guide pipe, an emptying port of the vacuum pump 15 is connected with the storage tank 8 through a hose, the bottom end of the guide tank 14 is connected with the guide pipe 16 through a hose, and delivery of materials can be achieved in a matched mode.

Well rotary drum 20 and material section of thick bamboo 21 are installed in parallel on the top side of mount 1, and first piston 23 and second piston 24 are installed respectively in well rotary drum 20 and material section of thick bamboo 21, are fixed with second spring 22 between the top side section of thick bamboo wall of second piston 24 and material section of thick bamboo 21, and screw rod 19 is installed to the top side of first piston 23, and screw rod 19 is worn to establish in the top side section of thick bamboo wall of well rotary drum 20 through the screw-thread fit, can realize throwing in the transportation of liquid material.

The middle rotating drum 20 and the material barrel 21 are communicated through a communicating pipe 25, a valve is arranged on the communicating pipe 25, and the material guide pipe 16 and the middle rotating drum 20 are respectively communicated with the material mixing pipe 2 through guide pipes, so that the materials are conveyed.

The working principle of the utility model is as follows: when materials are mixed, a powdery reagent is put into a storage box 8, a vacuum pump 15 is used for operation, a material guide tank 14 is evacuated, the material guide tank 14 is in a negative pressure state, a valve on a guide pipe for connecting the storage box 8 and the material guide tank 14 is opened, the powdery material is pumped into the material guide tank 14, the whole mass of the material guide tank 14 is increased when the material enters the material guide tank 14, a slide rod 13 is driven to slide downwards, the position of a calibration rod 12 is aligned through a limiting ball 11, the material mass of the material guide tank 14 can be judged according to the spring coefficient of a first spring 10, the material supplementing mass of the material can be accurately controlled, after the material is supplemented, a material guide motor 18 is operated to drive a screw rod 17 to rotate, the material is input into a material mixing pipe 2, the liquid material is stored into a material barrel 21, when the screw rod 19 is rotated to drive the first piston 23 to slide, the volume of the material is set, the valve on a communicating pipe 25 is opened, and the material with the material barrel 21 entering a middle rotating barrel 20, can realize that the material in the centering rotary drum 20 is accurate to be injectd, when the compounding stirring, add the material in the mixture pipe 2, agitator motor 6 operation drives puddler 5 rotatory, under the cooperation of stirring wing 4 and baffle 7, can realize that the material is "S" type flow stirring and mixes, reach better mixed effect, in the flow mixing process, can realize not shutting down the continuous feed and mix, realize continuity operation, reach better compounding efficiency.

The preferred embodiments of the utility model disclosed above are intended to be illustrative only. The preferred embodiments are not intended to be exhaustive or to limit the utility model to the precise embodiments disclosed. Obviously, many modifications and variations are possible in light of the above teaching. The embodiments were chosen and described in order to best explain the principles of the utility model and the practical application, to thereby enable others skilled in the art to best utilize the utility model. The utility model is limited only by the claims and their full scope and equivalents.

Claims (6)

1. A tubular reactor for continuous feeding reaction is characterized by comprising a fixing frame (1), a mixing pipe (2), a discharging pipe (3), a stirring wing (4), a stirring rod (5), a stirring motor (6), partition plates (7), a storage box (8), a support frame (9), a first spring (10), a limiting ball (11), a scalar rod (12), a sliding rod (13), a material guiding tank (14), a vacuum pump (15), a material guiding pipe (16), a screw rod (17), a material guiding motor (18), a screw rod (19), a transfer cylinder (20), a material cylinder (21), a second spring (22), a first piston (23), a second piston (24) and a communicating pipe (25), wherein the mixing pipe (2) is installed on a transverse plate at the top of the fixing frame (1), the stirring motor (6) is installed at one end of the mixing pipe (2), and the partition plates (7) are installed on the upper inner wall and the lower inner wall of the mixing pipe (2) in parallel, the output end part of a stirring motor (6) is installed on the stirring rod (5), the stirring rod (5) sequentially penetrates through the inside of a partition plate (7), a stirring wing (4) is installed on the stirring rod (5), a discharging pipe (3) is installed on the circumferential wall of the other end of a mixing pipe (2), a support frame (9) is welded on the top side of a fixing frame (1), a measuring rod (12) vertically penetrates through a top transverse plate of the support frame (9), a limiting ball (11) is fixed at the top end of the measuring rod (12), a first spring (10) is sleeved outside the top end of the measuring rod (12), the measuring rod (12) is vertically installed on the support frame (9), a vacuum pump (15) is installed on the support frame (9), a guide pipe (16) is erected on the top side of the fixing frame (1), and a guide motor (18) is installed at one end of the guide pipe (16), and a screw rod (17) is arranged on a rotating shaft of the material guide motor (18).

2. The tubular reactor for continuous feed reaction according to claim 1, wherein the metering rod (12) and the sliding rod (13) are arranged in parallel, and the storage tank (8) and the guide tank (14) are communicated through a guide pipe, and a valve is arranged on the guide pipe.

3. The tubular reactor for continuous feed reaction according to claim 1, wherein the evacuation port of the vacuum pump (15) is connected to the storage tank (8) through a hose, and the bottom end of the guide tank (14) is connected to the guide pipe (16) through a hose.

4. The tubular reactor for continuous feeding reaction according to claim 1, wherein the middle rotary drum (20) and the material barrel (21) are installed in parallel on the top side of the fixed frame (1), the first piston (23) and the second piston (24) are installed inside the middle rotary drum (20) and the material barrel (21) respectively, a second spring (22) is fixed between the second piston (24) and the top side barrel wall of the material barrel (21), the top side of the first piston (23) is provided with a screw rod (19), and the screw rod (19) is arranged in the top side barrel wall of the middle rotary drum (20) in a threaded fit manner.

5. The tubular reactor of continuous feed reaction according to claim 1, characterized in that the middle rotating cylinder (20) and the material cylinder (21) are connected through a communicating tube (25), and a valve is arranged on the communicating tube (25).

6. The tubular reactor for continuous feed reaction according to claim 1, characterized in that the material guide tube (16) and the middle rotating cylinder (20) are respectively communicated with the material mixing tube (2) through a conduit.

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