CN115285527A - Lignin-based composite ceramic additive microwave radiation induction preparation system - Google Patents

Abstract

The invention discloses a microwave radiation-induced preparation system for lignin-based composite ceramic additives. Connect the device main body case, the device main body chassis is fixedly connected to the raw material insertion pipe limit fixing block, the raw material insertion pipe limit fixing block is fixedly connected to the raw material insertion pipe fixed connection pipe, and the raw material insertion pipe is fixedly connected The tube fixing connection raw material is placed into the tube fixing connection tube fixing gasket. By arranging the independent raw material temporary storage bins of the lignin-based composite ceramic additive inside the device, the device can ensure the production quality of the product during the production of the lignin-based composite ceramic additive, and avoid the lack of product quality caused by mutual contamination of raw materials. At the same time, the anti-vibration device set at the bottom of the device ensures the safety of the device during operation.

Description

A microwave radiation-induced preparation system for lignin-based composite ceramic additives

technical field

The invention relates to the technical field of ceramics, in particular to a microwave radiation-induced preparation system for lignin-based composite ceramic additives.

Background technique

Ceramic additives are a general term for chemical additives added to meet the process requirements and performance needs in the production of ceramic industry. The amount of ceramic additives used in production is not large, but their role is very important. The development of ceramic additives has become an important part of the development of the ceramic industry. Aspects; Microwave technology was originally used in the field of communication, and has been successfully applied to chemical reactions, digestion and extraction of samples, environmental protection, etc., and has the advantages of saving energy and time, simplifying operating procedures, reducing the use of organic solvents, increasing the reaction rate, and significantly reducing The waste produced by chemical reactions has the advantages of harming the environment; lignin is the second organic matter after cellulose on the earth, and it is also the only non-petroleum resource that can provide renewable aryl compounds in nature. Microwave radiation technology carries out a series of chemical modifications such as hydroxymethylation and sulfonation on lignin, the main component of pulping black liquor, to prepare lignin-based ceramic additive LST, which not only improves the fluidity of ceramic slurry, ceramic production The strength of the blank has been greatly improved.

However, there is no microwave radiation-induced preparation equipment for lignin-based composite ceramic additives in the existing ceramic technology. Based on this, we designed a microwave-radiation-induced preparation system for lignin-based composite ceramic additives.

Contents of the invention

The object of the present invention is to provide a microwave radiation-induced preparation system for lignin-based composite ceramic additives, so as to solve the above-mentioned problems in the background technology.

In order to achieve the above object, the present invention provides the following technical solution: a microwave radiation induction preparation system for lignin-based composite ceramic additives, including a device main body load-bearing platform, characterized in that: the device main body load-bearing platform is fixedly connected to the main control box of the device The fixed block, the fixed block of the main control box of the device is fixedly connected to the main body of the device, the main body of the device is fixedly connected to the limit fixed block of the raw material insertion tube, and the fixed block of the raw material insertion tube is fixed to the fixed position of the raw material insertion tube The connecting pipe is connected, the raw material insertion tube is fixedly connected, the connecting tube is fixedly connected, the raw material insertion tube is fixedly connected, and the gasket is fixed, and the raw material insertion tube is fixedly connected. The temporary storage warehouse is fixedly connected to the raw material conveying forcible device, and the raw material conveying forcible device is fixedly connected with a device main body fixer, and the device main body fixer is fixedly connected with the protective layer of the device main body, and the device main body fixer is fixedly connected with the microwave radiation reaction chamber , the microwave radiation reaction chamber is fixedly connected to the raw material warehouse, the raw material warehouse is fixedly connected to the fixed block of the raw material delivery pipe, the fixed block of the raw material delivery pipe is fixedly connected to the raw material delivery pipe, and the raw material delivery pipe is fixedly connected to the raw material delivery dripper, The microwave radiation reaction chamber is fixedly connected to the reaction table, the reaction table is connected to the microwave radiation control connection block, the microwave radiation control connection block is fixedly connected to the control box connection block, and the control box connection block is fixed to the control box of the main body of the device Connection, the main control box of the device is fixedly connected to the load-bearing platform of the main control box of the device, the load-bearing platform of the main control box of the device is fixedly connected to the fixed block of the shock absorber, and the fixed block of the shock absorber is fixedly connected to the built-in limit fixed block of the shock absorber Built-in limit fixing block, the built-in limit fixing block of the shock absorber is fixedly connected to the main body of the shock absorber, the main body of the shock absorber is fixedly connected to the limit fixing rod of the shock absorber, and the limit fixing rod of the shock absorber The anti-vibration sensor fixed rod is fixedly connected, the anti-vibration sensor fixed rod is connected with the anti-vibration sensor, and the anti-vibration sensor is fixedly connected with the built-in limit fixed block of the anti-vibration device.

Further, the built-in surface of the main chassis of the device is fixedly connected to the front end of the material insertion tube limiting and fixing block, and the rear surface of the material insertion tube limiting and fixing block is fixedly connected to the material insertion tube The front face of the tube is fixedly connected.

Further, the rear outer surface of the raw material insertion pipe fixedly connected to the fixed gasket of the pipe is closely attached to the front outer surface of the raw material temporary storage bin, and the rear side surface of the raw material temporary storage bin is fixedly connected to the strong pressure of raw material delivery. the outer side of the device.

Further, the upper outer surface of the raw material bin is fixedly connected to the lower side of the raw material delivery pipe fixing block, and the upper side of the raw material delivery pipe fixing block is fixedly connected to the lower end surface of the raw material delivery pipe.

Further, the lower inner surface of the main control box of the device is fixedly connected to the upper side of the bearing platform of the main control box of the device, and the outer surface of the upper side of the bearing platform of the main control box of the device is fixedly connected to the lower end of the shock absorber fixing block .

Further, the rear position of the shock absorber main body is fixedly connected to the front surface of the shock absorber limit fixing rod, and the rear surface of the shock absorber limit fixing rod is fixedly connected to the front side of the shock absorber sensor fixing rod.

Compared with the prior art, the beneficial effect of the present invention is that the microwave radiation induction preparation system of the lignin-based composite ceramic additive can be equipped with independent raw material temporary storage bins of the lignin-based composite ceramic additive inside the device. The device can ensure the production quality of the product when producing lignin-based composite ceramic additives, and avoid the lack of product quality caused by mutual pollution of raw materials. At the same time, the shockproof device installed at the bottom of the device ensures the safety of the device during operation.

Description of drawings

Fig. 1 is the structural representation of this scheme front section;

Fig. 2 is the structural schematic diagram enlarged at place A in Fig. 1 of this scheme;

Fig. 3 is a schematic structural diagram enlarged at B in Fig. 1 of this scheme.

In the figure: 1. The load-bearing platform of the main body of the device, 2. The fixed block of the main control box of the device, 3. The fixed connection pipe of the raw material insertion tube, 4. The limit and fixed block of the raw material insertion tube, 5. The main body chassis of the device, 6. The temporary storage warehouse for raw materials, 7. The main body of the device Fixer, 8 microwave radiation reaction chamber, 9 shock absorber main body, 10 shock absorber sensor, 11 shock absorber sensor fixing rod, 12 shock absorber limit fixing rod, 13 device main control box bearing platform, 14 control box connection block, 15 microwave radiation control connection block, 16 main control box of the device, 17 shock absorber fixing block, 18 shock absorber built-in limit fixing block, 19 raw material delivery pipe, 20 raw material delivery pressure device, 21 raw material delivery dripper, 22 reaction table, 23 Raw material conveying pipe fixing block, 24 raw material warehouse, 25 raw material insertion pipe fixed connection pipe fixing gasket, 26 device main protective layer.

Detailed ways

The following will clearly and completely describe the technical solutions in the embodiments of the present invention with reference to the accompanying drawings in the embodiments of the present invention. Obviously, the described embodiments are only some, not all, embodiments of the present invention. Based on the embodiments of the present invention, all other embodiments obtained by persons of ordinary skill in the art without making creative efforts belong to the protection scope of the present invention.

Please refer to Figures 1-3, the present invention provides a technical solution: a microwave radiation induction preparation system for lignin-based composite ceramic additives, including a device main body load-bearing platform 1, characterized in that: the device main body load-bearing platform 1 is fixedly connected There is a fixed block 2 of the main control box of the device, and the fixed block 2 of the main control box of the device is fixedly connected to the main body chassis 5 of the device, and the main body chassis 5 of the device is fixedly connected to the fixed block 4 of the raw material insertion tube limit, and the raw material is inserted into the tube limit The position fixing block 4 is fixedly connected with the fixed connection pipe 3 of the raw material insertion pipe, the fixed connection pipe 3 of the raw material insertion pipe is fixedly connected with the fixed gasket 25 of the raw material insertion pipe fixed connection pipe, and the fixed connection pipe of the raw material insertion pipe is fixed The gasket 25 is closely attached to the raw material temporary storage bin 6, and the raw material temporary storage bin 6 is fixedly connected to the raw material conveying forcible device 20, and the raw material conveying forcible device 20 is fixedly connected to the device main body holder 7, and the device main body holder 7. The protective layer 26 of the main body of the device is fixedly connected. The main body holder 7 of the device is fixedly connected with the microwave radiation reaction chamber 8, and the microwave radiation reaction chamber 8 is fixedly connected with the raw material bin 24. Block 23, the raw material delivery pipe fixing block 23 is fixedly connected to the raw material delivery pipe 19, the raw material delivery pipe 19 is fixedly connected to the raw material delivery dripper 21, the microwave radiation reaction chamber 8 is fixedly connected to the reaction table 22, and the reaction table 22 Connect with the microwave radiation control connection block 15, the microwave radiation control connection block 15 is fixedly connected with the control box connection block 14, the control box connection block 14 is fixedly connected with the device main body control box 16, and the device main body control box 16 is fixed The main control box load-bearing platform 13 of the connecting device, the main control box load-bearing platform 13 of the device is fixedly connected with the shock absorber fixed block 17, and the shock absorber fixed block 17 is fixedly connected with the built-in limit fixed block of the shock absorber 18. The built-in limit fixed block of the shock absorber is fixedly connected to the shock absorber main body 9, the shock absorber main body 9 is fixedly connected to the shock absorber limit fixed rod 12, and the shock absorber limit fixed rod 12 is fixedly connected to the anti-vibration sensor fixed rod 11, the anti-vibration sensor fixed rod 11 is connected to the anti-vibration sensor 10, and the anti-vibration sensor 10 is fixedly connected to the built-in limit fixed block 18 of the anti-vibration device.

As shown in Figure 2, the built-in surface of the main body chassis 5 of the device is fixedly connected to the front end of the material insertion tube limiting and fixing block 4, and the rear surface of the material insertion tube limiting and fixing block 4 is fixed to the front end of the material insertion tube. The fixed connection of the front surface of the raw material insertion tube fixed connection tube 3 is beneficial to effectively limit the position of the raw material insertion tube and can effectively fix the mechanical energy of the insertion tube, and can effectively transport the raw material and control the upper surface. The connecting pipe placed in the raw material is reasonably fixed; the outer surface of the rear position of the fixed gasket 25 of the raw material insertion pipe and the fixing gasket 25 is closely attached to the front outer surface of the raw material temporary storage bin 6, and the raw material temporary storage bin 6 The rear surface of the rear side is fixedly connected to the outer surface of the raw material conveying pressurizer 20, which is conducive to protecting the connecting pipe, preventing the connecting pipe from being worn during use, and can effectively pressurize the raw materials inside the device.

As shown in Figure 3, the upper outer surface of the raw material bin 24 is fixedly connected to the lower side of the raw material delivery pipe fixing block 23, and the upper side of the raw material delivery pipe fixing block 23 is fixedly connected to the lower end surface of the raw material delivery pipe 19. , it is beneficial to effectively fix the raw material delivery pipe, strengthen the reaction, and also reduce accidents during the operation of the delivery pipe.

As shown in Figure 3, the lower side inner surface of the main control box 16 of the device is fixedly connected to the upper side of the main control box bearing platform 13 of the device, and the outer surface of the upper side of the main control box bearing platform 13 of the device is connected with the shock absorber fixing block. The lower end of 17 is fixedly connected, which is conducive to effectively supporting the control box of the main body of the device, and can prevent the vibration of the device during operation from causing damage to the operation of the device, ensuring the safety of the device; the main body of the shock absorber 9 The rear position of the rear position is fixedly connected to the front end surface of the shock absorber limit fixed rod 12, and the rear surface of the described shock absorber limit fixed rod 12 is fixedly connected to the front side of the shock absorber sensor fixed rod 11, which is beneficial to the shock absorber of the main body of the device. Effective protection, capable of reasonably fixing the built-in shock absorber sensor of the device.

Working principle: When the lignin-based composite ceramic additive microwave radiation induction preparation system is in use, first fix the device main body load-bearing platform 1 in the required use area and then turn on the power to start using, and the lignin-based composite The raw materials of the type ceramic additive are respectively poured into the four independent raw material temporary storage bins 6 built in the device from the raw material insertion tube limit fixed block 4, and the raw materials enter the raw material insertion tube fixed connection tube from the raw material insertion tube limit fixed block 4 3. After passing through the raw material insertion tube to fix the connecting tube 3, enter the raw material insertion tube and fix the connecting tube fixed gasket 25 to the raw material temporary storage warehouse 6 for temporary storage. When the control box 16 of the main body of the device starts to start, according to the order of raw material addition, the raw material Sequentially from the raw material temporary storage bin 6 through the raw material delivery pressure device 20, and then squeezed from the raw material delivery pressure device 20 to the raw material warehouse 24, and then drop directly from the raw material delivery dripper 21 to the reaction table 22 through the raw material delivery pipe 19 to react. After completion, just open the device and take out the product. The above is the process of the preparation system of the lignin-based composite ceramic additive microwave radiation induction.

Although the embodiments of the present invention have been shown and described, those skilled in the art can understand that various changes, modifications and substitutions can be made to these embodiments without departing from the principle and spirit of the present invention. and modifications, the scope of the invention is defined by the appended claims and their equivalents.

Claims (6)

1. The utility model provides a lignin base compound ceramic additive microwave radiation induction preparation system, includes device main part bearing platform (1), its characterized in that: the device is characterized in that a device main body bearing platform (1) is fixedly connected with a device main control box fixing block (2), the device main body bearing platform (1) is fixedly connected with a device main control box fixing block (2) and a device main body case (5), the device main body case (5) is fixedly connected with a raw material imbedding tube fixing block (4), the raw material imbedding tube fixing block (4) is fixed and connected with a raw material imbedding tube fixing connecting tube (3), the raw material imbedding tube fixing connecting tube fixing gasket (25) is tightly attached to a raw material imbedding tube fixing gasket (6), the raw material imbedding tube fixing gasket (25) is fixedly connected with a raw material temporary storage bin (6), the raw material temporary storage bin (6) is fixedly connected with a raw material conveying strong pressure device (20), the raw material is conveyed to a strong pressure device main body fixer (20) and fixedly connected with a device main body fixer (7), the device main body fixer (7) is fixedly connected with a device main body protective layer (26), the device main body fixer (7) is fixedly connected with a microwave radiation reaction bin (8), the microwave radiation reaction bin (8) is fixedly connected with a raw material conveying tube (23) and a raw material conveying tube (19) is connected with a raw material radiation reaction bin (19) and a raw material conveying tube (19), the reaction platform (22) is connected with a microwave radiation control connecting block (15), the microwave radiation control connecting block (15) is fixedly connected with a control box connecting block (14), the control box connecting block (14) is fixedly connected with a device main body control box (16), the device main body control box (16) is fixedly connected with a main control box bearing platform (13), the device main control box bearing platform (13) is fixedly connected with a shock absorber fixing block (17), the shock absorber fixing block (17) is fixedly connected with a shock absorber built-in limiting fixing block shock absorber (18), the shock absorber built-in limiting fixing block shock absorber is fixedly connected with a shock absorber main body (9), the shock absorber main body (9) is fixedly connected with a shock absorber limiting fixing rod (12), the shock absorber limiting fixing rod (12) is fixedly connected with a shock absorber sensor fixing rod (11), the shock absorber sensor fixing rod (11) is connected with a shock absorber sensor (10), and the shock absorber sensor (10) is fixedly connected with a shock absorber built-in limiting fixing block (18).

2. The microwave radiation induction preparation system for the lignin-based composite ceramic additive according to claim 1, wherein: the device is characterized in that the surface of a built-in surface of the device main case (5) is fixedly connected with the front end of the raw material inlet pipe limiting fixing block (4), and the surface of a rear position of the raw material inlet pipe limiting fixing block (4) is fixedly connected with the front surface of the raw material inlet pipe fixing connecting pipe (3).

3. The microwave radiation induction preparation system of the lignin-based composite ceramic additive according to claim 1, wherein: the outer surface of the rear position of the raw material placing pipe fixed connecting pipe fixing gasket (25) is tightly attached to the outer side face of the front position of the raw material temporary storage bin (6), and the outer side face of the rear side face of the raw material temporary storage bin (6) is fixedly connected with the outer side face of the raw material conveying booster (20).

4. The microwave radiation induction preparation system of the lignin-based composite ceramic additive according to claim 1, wherein: the downside of the upside external surface fixed connection raw materials conveyer pipe fixed block (23) in raw materials storehouse (24), the lower terminal surface of the last side fixed connection raw materials conveyer pipe (19) of raw materials conveyer pipe fixed block (23).

5. The microwave radiation induction preparation system of the lignin-based composite ceramic additive according to claim 1, wherein: the lower inner surface of the device main body control box (16) is fixedly connected with the upper side surface of the device main control box bearing table (13), and the outer surface of the upper side surface of the device main control box bearing table (13) is fixedly connected with the lower end of the shock absorber fixing block (17).

6. The microwave radiation induction preparation system of the lignin-based composite ceramic additive according to claim 1, wherein: the rear position of the shock absorber main body (9) is fixedly connected with the front end surface of a shock absorber limiting fixing rod (12), and the rear surface of the shock absorber limiting fixing rod (12) is fixedly connected with the front side surface of a shock absorber sensor fixing rod (11).

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