CN204170731U - A kind of horizontal macromolecule Mechanico-chemical reactor - Google Patents

Abstract

The utility model discloses a horizontal macromolecule mechanochemical reactor, which comprises a horizontally placed reactor cylinder and a jacket wrapped outside the reactor cylinder. The reactor cylinder includes an inner cylinder and an outer cylinder, and the inner cylinder and the Driven by the motor of the inner cylinder and the motor of the outer cylinder, the outer cylinder rotates horizontally and axially in opposite directions. A ball milling space is formed between the outer wall of the inner cylinder and the inner wall of the outer cylinder. Several stirring arms are arranged on the outer wall of the inner cylinder. , the outer cylinder is provided with a material inlet and a material outlet, and the outer sleeve is provided with a material inlet and a material outlet. The utility model adopts the above structure, which can make discharging easier, reduce the operating torque and noise of the motor, prolong the service life of the equipment, and at the same time improve the cooling efficiency of the material and improve the performance of the mechanochemical reaction product.

Description

A horizontal polymer mechanochemical reactor

technical field

The utility model relates to the field of reactors, in particular to a horizontal polymer mechanochemical reactor.

Background technique

Polyvinyl chloride, as a general-purpose resin with high quality and low price, is widely used in construction, transportation, agriculture, electric power, medical, packaging and other fields of production and life (Medical Device Technology 2008, 19(6), 17-19). However, PVC often has a complex particle shape similar to the pomegranate structure (Journal of Vinyl Technology 1991, 13(1), 2-25), which makes its processing difficult.

The ball mill uses a lot of steel balls with different diameters as the medium. It can convert the energy in the movement of the steel balls into mechanochemical effects such as shearing, impact, and friction during operation, and crush the materials in the gaps of the steel balls. , shaping and chemical reactions, these effects can just destroy the PVC spherical particle structure and produce mechanical chemical reactions, thereby improving the processing performance of PVC, and finally improving the mechanical properties of PVC.

The ball mills currently used for mechanochemical modification of PVC are basically vertical ball mills (patent No. 200720026447.1). However, there are problems such as difficult materials and high operating noise. Therefore, a polymer mechanochemical reactor is urgently needed to overcome these deficiencies.

Utility model content

The purpose of this utility model is to provide a horizontal polymer mechanochemical reactor, which solves the problems of the current vertical polymer mechanochemical reactor with large operating torque, low material cooling efficiency, difficult discharge and high operating noise The problem.

In order to achieve the above object, the utility model adopts the following technical solutions to realize:

A horizontal polymer mechanochemical reactor, comprising a horizontally placed reactor cylinder and an outer jacket wrapped outside the reactor cylinder, the reactor cylinder includes an inner cylinder and an outer cylinder, the inner cylinder and the outer cylinder respectively Driven by the cylinder motor and the outer cylinder motor, it rotates horizontally and axially in opposite directions. A ball milling space is formed between the outer wall of the inner cylinder and the inner wall of the outer cylinder. There are several stirring arms on the outer wall of the inner cylinder. The outer cylinder The top is provided with a material inlet and a material outlet, and the outer jacket is provided with a material inlet and a material discharge port.

In this scheme, the materials and balls enter the ball milling space between the inner cylinder and the outer cylinder through the material inlet of the jacket and the material inlet of the outer cylinder, and the ball milling treatment of the materials is completed here. After the ball milling is completed, the materials are sequentially It is discharged from the discharge port of the outer cylinder and the discharge port of the jacket; since the reactor cylinder is placed horizontally, and the inner cylinder and the outer cylinder are driven by the inner cylinder motor and the outer cylinder motor to rotate horizontally and axially in opposite directions , which not only reduces the torque of the inner cylinder motor and the outer cylinder motor during operation, but also helps to prolong the service life of the equipment, and the reverse rotation of the inner cylinder and the outer casing can also improve the efficiency of the ball mill. In addition, since the jacket wraps the outside of the entire reactor cylinder, as long as the discharge port of the outer cylinder is opened, the material can be ensured to enter the jacket as much as possible and be discharged through the discharge port of the jacket, so that the discharge becomes Simple and easy to operate.

Further, as a preferred solution, the discharge port of the outer cylinder is provided with a sieve plate and a cover plate capable of sealing the discharge port, and the sieve plate is provided with sieve holes through which materials can pass.

In this scheme, the sieve plate can play the role of separating the material and the grinding ball. When the material is in the process of ball milling, the cover plate is closed, and the material cannot pass through the sieve plate. The sieve holes on the plate pass through, while the grinding balls cannot pass through the sieve plate, so that the material is also discharged during the process of separating the material from the grinding ball, making the discharge easier.

Further, as a preferred solution, the inlet and outlet of the outer cylinder are arranged symmetrically up and down on the outer cylinder.

Further, as a preferred solution, the inner cylinder is provided with a cooling water channel, and the outer cylinder is provided with an interlayer for accommodating cooling water. Through the action of the cooling water in the inner cylinder and the outer cylinder, the temperature of the material and the balls can be well controlled to prevent the reaction temperature from being too high, thereby improving the performance of the mechanochemical reaction product.

Further, as a preferred solution, the outer cylinder motor is provided with a positioning device. When shutting down, the positioning device can make the material inlet of the outer cylinder directly above and the material outlet directly below, or the material outlet directly above and the material inlet directly below, the former is convenient for feeding, and the latter is convenient for opening the cover plate for Subsequent discharge.

Further, as a preferred solution, the lower part of the jacket is a funnel-shaped structure, and the discharge port is located at the lowermost end of the funnel-shaped structure. The lower part of the jacket is designed to be funnel-shaped, so that the materials coming out of the outer cylinder can be collected at the lower part of the jacket, which is convenient for rapid discharge and makes the discharge convenient and easy.

Compared with the prior art, the utility model has the following advantages and beneficial effects:

(1) In this utility model, the reactor cylinder is designed to be placed horizontally, and the reactor cylinder is divided into an inner cylinder and an outer cylinder. The inner cylinder and the outer cylinder are respectively driven by the inner cylinder motor and the outer cylinder motor. The horizontal and axial rotation in the opposite direction not only reduces the torque of the inner cylinder motor and the outer cylinder motor during operation, reduces the noise, but also helps to prolong the service life of the equipment, and the reverse rotation of the inner cylinder and the outer casing can also improve the ball milling performance. efficiency.

(2) The jacket of the utility model is wrapped around the outside of the entire reactor cylinder. As long as the outlet of the outer cylinder is opened, the material can be ensured to enter the jacket as much as possible and be discharged through the outlet of the jacket, so that the The material becomes simple and easy to operate.

(3) The utility model sets cooling water passages and cooling water interlayers in the inner cylinder and the outer cylinder respectively. Under the action of cooling water, the temperature of materials and grinding balls can be well controlled to prevent the reaction temperature from being too high, and further It can improve the performance of mechanochemical reaction products.

(4) The utility model arranges a sieve plate and a cover plate at the discharge port of the outer cylinder. The sieve plate can play the role of separating materials and grinding balls. Through, when the ball milling is completed, open the cover plate, the material can pass through the sieve holes on the sieve plate, but the grinding balls cannot pass through the sieve plate, so that the separation of the material and the grinding balls is also achieved. Discharging makes discharging easier.

(5) The utility model is provided with a positioning device on the motor of the outer cylinder. When the machine stops, the positioning device can make the feeding port of the outer cylinder directly above and the discharge port directly below, or the discharge port directly above and the feed port It is directly below, so that it is convenient to feed materials, and it is convenient to open the cover plate for subsequent discharge, which can improve production efficiency.

Description of drawings

Fig. 1 is the overall structural representation of the utility model;

Fig. 2 is the structural representation of the reactor barrel of the present utility model;

Fig. 3 is a structural schematic diagram of the reactor cylinder of the present invention when it is rotating.

The names corresponding to the reference signs in the drawings are: 1. Reactor cylinder, 2. Outer jacket, 3. Inner cylinder, 4. Outer cylinder, 5. Feed inlet, 6. Discharge outlet, 7. Inner cylinder motor, 8. Outer cylinder motor, 9. Base, 10. Feed inlet, 11. Sieve plate, 12. Cover plate, 13. Stirring arm, 14. Cooling water channel, 15. Interlayer, 16. Grinding ball, 17. Material .

Detailed ways

The utility model will be further described in detail below in conjunction with the examples, but the implementation of the utility model is not limited thereto.

Example:

As shown in Figure 1, Figure 2 and Figure 3, a horizontal polymer mechanochemical reactor described in this embodiment includes a horizontally placed reactor cylinder 1 and a jacket 2 wrapped outside the reactor cylinder 1 , the reactor cylinder 1 and the outer casing 2 are placed horizontally on two bases 9, the reactor cylinder 1 includes an inner cylinder 3 and an outer cylinder 4, and the inner cylinder 3 and the outer cylinder 4 are respectively the inner cylinder motor 7 and the outer cylinder motor Driven by 8, it rotates horizontally and axially in the opposite direction. A ball milling space is formed between the outer wall of the inner cylinder 3 and the inner wall of the outer cylinder 4. A number of stirring arms 13 are arranged on the outer wall of the inner cylinder 3. The material inlet 10 and the material outlet, the jacket 2 is provided with the material inlet 5 and the material discharge port 6 .

In order to make discharging more convenient, in this embodiment, a sieve plate 11 and a cover plate 12 capable of sealing the discharge port are provided at the discharge port of the outer cylinder 4. The sieve plate 11 is provided with a sieve hole that allows the material to pass through. When the material is in the ball milling process In the middle, the cover plate 12 is closed, and the material cannot pass through the sieve plate 11. After the ball milling is completed, the cover plate 12 is opened, and the material can pass through the sieve holes on the sieve plate 11, while the grinding balls cannot pass through the sieve plate 11. , so that the discharge of the material is also realized during the process of separating the material from the grinding ball, making the discharge easier.

In order to facilitate feeding and discharging, in this embodiment, the feeding port 10 and the discharging port of the outer cylinder 4 are symmetrically arranged on the outer cylinder 4 up and down.

In order to better control the temperature of materials and grinding balls, prevent the reaction temperature from being too high, and improve the performance of the mechanochemical reaction product, a cooling water channel 14 is provided inside the inner cylinder 3 in this embodiment, and a cooling water channel 14 is provided on the outer cylinder 4 to accommodate cooling water. Mezzanine 15.

In order to better realize the positioning of the feed port 10 and the discharge port of the outer cylinder 4, it can stop at the feed port 5 or the discharge port 6 of the outer casing 2 correspondingly when the machine is shut down, so as to facilitate the feeding and discharging. In this embodiment, a positioning device is provided on the outer cylinder motor 8, and the positioning device can make the feeding port 10 of the outer cylinder 4 directly above and the discharge port directly below, or the discharge port is directly above and the feeding port 10 is directly below. Below, so that it is convenient to feed materials, and it is convenient to open the cover plate 12 for subsequent discharge.

In order to facilitate discharging, in this embodiment, the lower part of the jacket 2 is designed as a funnel-shaped structure, and the discharge port 6 is located at the lowermost end of the funnel-shaped structure.

The working principle of the present embodiment: firstly, stop the feed port 10 of the outer cylinder 4 directly above by the positioning device of the outer cylinder motor 8, open the feed port 5 of the overcoat 2 and the feed port 10 of the outer cylinder 4, and place the Materials 17 and grinding balls 16 are put into the outer cylinder 4, the feed inlet 10 and the feed inlet 5 are closed, the cooling water channel 14 and the interlayer 15 are fed with cooling water, the inner cylinder motor 7 and the outer cylinder motor 8 are started, the inner cylinder 3 and the The outer cylinder 4 rotates in the opposite direction. After the ball milling is completed, stop the machine, stop the outlet of the outer cylinder 4 at the top through the positioning device of the outer cylinder motor 8, open the inlet 5 of the jacket 2, and then open the outlet of the outer cylinder 4. The cover plate 12 at the discharge port closes the feed port 5 of the jacket 2, and starts the inner cylinder motor 7 and the outer cylinder motor 8 again. At this time, the material 17 is thrown out of the reactor cylinder 1 through the sieve holes on the sieve plate 11 , and enter the funnel structure at the lower part of the jacket 2; after a period of time, through the positioning device of the outer cylinder motor 8, the outlet of the outer cylinder 4 is stopped directly above, the inlet 5 of the outer jacket 2 is opened, and the outer cylinder is closed Cover plate 12 of 4 and the feed inlet 5 of overcoat 2, run outer cylinder motor 8 again, make the feed inlet 10 of outer cylinder 4 stop at just above, carry out feeding next time. The discharge can be realized by opening the discharge port 6 at the bottom of the jacket 2 .

The above is only a preferred embodiment of the utility model, and does not limit the utility model in any form. Any simple modification or equivalent change made to the above embodiments according to the technical essence of the utility model falls within the scope of the present utility model. Within the protection scope of the present utility model.

Claims (6)

1. A horizontal polymer mechanochemical reactor, characterized in that: it includes a horizontally placed reactor cylinder (1) and a jacket (2) wrapped outside the reactor cylinder (1), the reactor cylinder The body (1) includes an inner cylinder (3) and an outer cylinder (4), and the inner cylinder (3) and the outer cylinder (4) are respectively driven by the inner cylinder motor (7) and the outer cylinder motor (8) to rotate in opposite directions. Rotating horizontally and axially, a ball milling space is formed between the outer wall of the inner cylinder (3) and the inner wall of the outer cylinder (4). Several stirring arms (13) are arranged on the outer wall of the inner cylinder (3), and the outer cylinder ( 4) It is provided with a material inlet (10) and a material outlet, and the jacket (2) is provided with a material inlet (5) and a material outlet (6). 2. A horizontal polymer mechanochemical reactor according to claim 1, characterized in that: the outlet of the outer cylinder (4) is provided with a sieve plate (11) and a cover capable of sealing the outlet plate (12), and the sieve plate (11) is provided with sieve holes for materials to pass through. 3. A horizontal polymer mechanochemical reactor according to claim 1, characterized in that: the feed port (10) and the discharge port of the outer cylinder (4) are vertically symmetrically arranged on the outer cylinder (4 )superior. 4. A horizontal polymer mechanochemical reactor according to claim 1, characterized in that: the inner cylinder (3) is provided with a cooling water channel (14), and the outer cylinder (4) is provided with Interlayer (15) for holding cooling water. 5. A horizontal polymer mechanochemical reactor according to claim 1, characterized in that: the outer cylinder motor (8) is provided with a positioning device. 6. A horizontal polymer mechanochemical reactor according to claim 1, characterized in that: the lower part of the jacket (2) is a funnel-shaped structure, and the discharge port (6) is located at the lowermost end of the funnel-shaped structure .