CN214051604U - Heating device for producing nano methoxy acrylate bactericide - Google Patents

Abstract

The utility model discloses a heating device for production of nanometer methoxy acrylate bactericides, which relates to the technical field of bactericides and comprises a reaction kettle, wherein a discharge pipe is arranged at the bottom of the reaction kettle, a cover plate is arranged at the upper port of the reaction kettle, a stirring structure is arranged on the cover plate, and a heating structure is also arranged on the reaction kettle; the heating structure comprises a plurality of heating pipes penetrating through a cover plate and a cover body arranged on the outer wall of the reaction kettle, the cover body and the outer wall of the reaction kettle form a heating chamber, one end of each heating pipe penetrates through the cover plate, the other end of each heating pipe penetrates through the bottom of the reaction kettle, each heating pipe extends into the heating chamber, the heating chamber is connected with the air inlet end of the air heater, the inner wall of the reaction kettle is further provided with a temperature sensor, the part of each heating pipe extending into the reaction kettle is S-shaped, and the discharge pipe penetrates through the heating chamber; the utility model has the advantages of convenient use, high heating efficiency, high uniformity and the like.

Description

Heating device for producing nano methoxy acrylate bactericide

Technical Field

The utility model relates to a technical field of germicide, in particular to a heating device for production of nanometer type methoxy acrylic ester germicide.

Background

Biocides, also known as biocides, bactericidal algicides, microbicides, and the like, generally refer to chemical agents that are effective in controlling or killing microorganisms, bacteria, fungi, and algae, in aqueous systems. Internationally, it is a general term for agents for controlling various types of pathogenic microorganisms.

The preparation of germicide is usually gone on in reation kettle, and reation kettle is in the in-process of production preparation germicide, and one of them step is to reation kettle heating, and current heating methods mainly heats through reation kettle's bottom, and the heat distributes to reation kettle inside gradually, but this kind of heating methods's efficiency is lower, and it is inhomogeneous to heat, leads to the product result of use of production poor.

SUMMERY OF THE UTILITY MODEL

The utility model aims to solve the technical problem that a heating device for be used for nanometer type methoxy acrylic ester germicide production is provided for solve the problem that the reation kettle of producing germicide among the prior art of description in the background art heating is inhomogeneous, inefficiency.

In order to achieve the above object, the present invention provides the following technical solutions: a heating device for producing a nano methoxy acrylate bactericide comprises a reaction kettle, wherein a discharge pipe is arranged at the bottom of the reaction kettle, a cover plate is arranged at the upper port of the reaction kettle, a stirring structure is arranged on the cover plate, and a heating structure is also arranged on the reaction kettle; the heating structure includes a plurality of heating pipes that run through the apron and set up in the cover body of reation kettle outer wall, the cover body forms a heating chamber with reation kettle 'S outer wall, the one end of heating pipe runs through apron, the bottom that the other end runs through reation kettle, in the heating pipe stretches into the heating chamber, the heating chamber is connected with the air inlet end of air heater, reation kettle' S inner wall still is provided with temperature sensor, the part that the heating pipe stretched into reation kettle is the S type, the discharging pipe runs through the heating chamber.

Preferably: the inner wall of the reaction kettle is provided with a plurality of positioning rings, and the positioning rings are connected with the heating pipe.

Preferably: the stirring structure is including setting up the speed reducer on the apron, the outer wall of speed reducer is provided with servo motor, servo motor's output shaft and the input shaft of speed reducer, the output shaft and the dwang of speed reducer are connected, be provided with a plurality of puddlers on the dwang.

Preferably: the heating pipe runs through the one end of apron and is connected with the gas outlet cover, the inner wall of gas outlet cover is provided with the one deck filter screen.

Preferably: the fixed cover of outer wall of dwang is equipped with and connects the hopper, connect to be provided with a plurality of discharge openings that run through this hang plate on the hang plate of hopper, and the inlet pipe is just to connecing the hopper.

Preferably: and the stirring rod and the S-shaped bent position of the heating pipe are alternated.

Preferably: the outer wall of reation kettle is provided with the electric cabinet, be provided with industrial computer and control panel on the electric cabinet, the industrial computer respectively with control panel, servo motor, air heater, temperature sensor electric connection.

The beneficial effect of adopting above technical scheme is:

according to the heating device, the rotating rod is driven to rotate and the stirring rod is driven to rotate through the matching of the arranged servo motor and the speed reducer, materials in the reaction kettle are stirred through the stirring rod, hot air is injected into the heating chamber through the arranged hot air blower, then the hot air heats the materials in the reaction kettle through the heating pipe, and the heating pipe is S-shaped, so that the heating pipe can uniformly and fully heat the materials in the reaction kettle;

impurities can be prevented from entering the heating pipe through the arranged gas outlet cover and the filter screen;

connect the hopper through setting up and can make the inlet pipe introduce the material that connects in the hopper and can follow the rotation that connects the hopper and scatter about connecting the discharge opening that sets up on connecing the hopper for the interpolation of material is more even.

Drawings

Fig. 1 is a schematic structural diagram of a heating device for producing a nano-type methoxy acrylate bactericide of the present invention.

Wherein: the device comprises a reaction kettle 10, a discharge pipe 11, a cover plate 20, a feed pipe 21, a stirring structure 30, a speed reducer 31, a servo motor 32, a rotating rod 33, a stirring rod 34, a heating structure 40, a heating pipe 41, a cover body 42, a heating chamber 43, a hot air blower 44, a temperature sensor 45, a positioning ring 46, an air outlet cover 47, a filter screen 48, a receiving hopper 50, a discharge hole 51 and an electric cabinet 60.

Detailed Description

Preferred embodiments of the present invention will be described in detail below with reference to the accompanying drawings.

In the embodiment, as shown in fig. 1, in the embodiment, a heating device for producing a nano methoxy acrylate bactericide comprises a reaction kettle 10, a discharge pipe 11 is arranged at the bottom of the reaction kettle 10, a cover plate 20 is arranged at an upper port of the reaction kettle 10, a stirring structure 30 is arranged on the cover plate 20, and a heating structure 40 is further arranged on the reaction kettle 10; heating structure 40 includes a plurality of heating pipes 41 that run through apron 20 and sets up in the cover body 42 of reation kettle 10 outer wall, the cover body 42 forms a heating chamber 43 with reation kettle 10 ' S outer wall, the bottom that apron 20, the other end run through reation kettle 10 are run through to heating pipe 41 ' S one end, heating pipe 41 stretches into in the heating chamber 43, heating chamber 43 is connected with air heater 44 ' S air inlet end, reation kettle 10 ' S inner wall still is provided with temperature sensor 45, heating pipe 41 stretches into reation kettle 10 ' S part is the S type, discharging pipe 11 runs through heating chamber 43.

Preferably: the inner wall of the reaction kettle 10 is provided with a plurality of positioning rings 46, and the positioning rings 46 are connected with the heating pipe 41.

Preferably: stirring structure 30 is including setting up speed reducer 31 on apron 20, the outer wall of speed reducer 32 is provided with servo motor 32, servo motor 32's output shaft and speed reducer 31's input shaft, speed reducer 31's output shaft and dwang 33 are connected, be provided with a plurality of puddlers 34 on the dwang 33.

Preferably: one end of the heating pipe 41 penetrating through the cover plate 20 is connected with an air outlet cover 47, and the inner wall of the air outlet cover 47 is provided with a layer of filter screen 48.

Preferably: the fixed cover of outer wall of dwang 33 is equipped with and connects hopper 50, connect and be provided with a plurality of discharge openings 51 that run through this communications clinostatism on the communications clinostatism of hopper 50, and inlet pipe 21 is just to connecing hopper 50.

Preferably: the stirring rod 34 alternates with the S-bend position of the heating tube 41.

Preferably: the outer wall of reaction kettle 10 is provided with electric cabinet 60, be provided with industrial computer and control panel on the electric cabinet 60, the industrial computer respectively with control panel, servo motor 32, air heater 44, temperature sensor 45 electric connection.

The specific implementation manner of this embodiment:

when the reactor is used, the servo motor 32 is started firstly, the servo motor 32 drives the rotating rod 33 to rotate through the speed reducer 31, the rotating rod 33 drives the stirring rod 34 and the receiving hopper 50 to rotate, then raw materials are injected into the reactor 10 through the feeding pipe 21 and enter the receiving hopper 50, the receiving hopper 50 rotates to discharge the raw materials from the discharge hole 51 on the receiving hopper 50, the raw materials can be scattered, the raw materials can enter the reactor 10 more uniformly, then the hot air blower 44 is started, the hot air blower 44 injects hot air into the heating chamber 43, then the hot air enters the heating pipe 41, the materials in the reactor 10 are heated through the heating pipe 41, the outer wall of the reactor 10 can be heated through the heating chamber 43, and heat energy can be quickly transferred to the materials in the reactor 10;

the filter screen 48 is provided to block dust from entering the heating pipe 41.

The foregoing is only a preferred embodiment of the present invention, and it should be noted that, for those skilled in the art, many modifications and improvements can be made without departing from the inventive concept, and all of them belong to the protection scope of the present invention.

Claims (7)

1. A heating device for production of nanometer methoxy acrylate bactericides comprises a reaction kettle and is characterized in that: a discharge pipe is arranged at the bottom of the reaction kettle, a cover plate is arranged at the upper port of the reaction kettle, a stirring structure is arranged on the cover plate, and a heating structure is also arranged on the reaction kettle; the heating structure includes a plurality of heating pipes that run through the apron and set up in the cover body of reation kettle outer wall, the cover body forms a heating chamber with reation kettle 'S outer wall, the one end of heating pipe runs through apron, the bottom that the other end runs through reation kettle, in the heating pipe stretches into the heating chamber, the heating chamber is connected with the air inlet end of air heater, reation kettle' S inner wall still is provided with temperature sensor, the part that the heating pipe stretched into reation kettle is the S type, the discharging pipe runs through the heating chamber.

2. The heating device for producing the nano methoxy acrylate bactericide as claimed in claim 1, wherein a plurality of positioning rings are arranged on the inner wall of the reaction kettle, and the positioning rings are connected with the heating pipe.

3. The heating device for producing the nano methoxy acrylate bactericide as claimed in claim 2, wherein the stirring structure comprises a speed reducer arranged on the cover plate, a servo motor is arranged on the outer wall of the speed reducer, the output shaft of the servo motor is connected with the input shaft of the speed reducer, the output shaft of the speed reducer is connected with a rotating rod, and a plurality of stirring rods are arranged on the rotating rod.

4. The heating device for producing the nano methoxy acrylate bactericide as claimed in claim 3, wherein the stirring rod and the heating pipe are alternated at the S-bend position.

5. The heating device for producing the nano-methoxy acrylate fungicide according to claim 4, wherein the outer wall of said rotating rod is fixedly sleeved with a receiving hopper, the inclined wall of said receiving hopper is provided with a plurality of discharging holes penetrating through the inclined wall, and the feeding pipe is opposite to the receiving hopper.

6. The heating device for producing the nano methoxy acrylate bactericide as claimed in claim 5, wherein one end of the heating tube penetrating through the cover plate is connected with the gas outlet cover, and the inner wall of the gas outlet cover is provided with a layer of filter screen.

7. The heating device for producing the nano methoxy acrylate bactericide as claimed in claim 6, wherein an electric cabinet is arranged on the outer wall of the reaction kettle, an industrial personal computer and a control panel are arranged on the electric cabinet, and the industrial personal computer is respectively and electrically connected with the control panel, the servo motor, the air heater and the temperature sensor.

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