CN218485988U

CN218485988U - Reaction device

Info

Publication number: CN218485988U
Application number: CN202222792059.1U
Authority: CN
Inventors: 张维; 郑苏江; 汤艳; 曲巍
Original assignee: Technical Institute of Physics and Chemistry of CAS
Current assignee: Technical Institute of Physics and Chemistry of CAS
Priority date: 2022-10-21
Filing date: 2022-10-21
Publication date: 2023-02-17
Anticipated expiration: 2032-10-21

Abstract

The embodiment of the application discloses reaction unit includes: at least one reaction container capable of rotating along the axial direction, wherein the reaction container is used for containing reaction materials; a gas supply system for providing humidified air to the reaction material in the reaction vessel; a processing system for processing the useless gas generated in the inner cavity of the reaction container; the processing system comprises: the condensing device is communicated with the inner cavity of the reaction container through a first pipeline; the condensing device is used for condensing the useless gas to generate condensed water and secondary gas; the condensed water flows back to the inner cavity of the reaction vessel through the first pipeline; the exhaust device is communicated with the condensing device through a second pipeline and used for receiving secondary gas, and the exhaust device is used for monitoring the concentration and the flow rate of the secondary gas and exhausting the secondary gas to the outside; one end of the first pipeline communicated with the condensing device is communicated with one end of the second pipeline communicated with the condensing device through a condensing pipe.

Description

Reaction device

Technical Field

The application relates to the technical field of material reaction, more specifically, the application relates to a reaction unit.

Background

In the environmental protection field, the degradation performance of the environmental protection material under the action of microorganisms and the influence of the generated degradation products on the microorganisms need to be researched; in the field of soil remediation, the conversion capability of microorganisms on organic matters and inorganic matters in soil needs to be researched; there is also a need in the field of microbial fermentation to study the effect of media on the fermentation capacity of microorganisms. The microorganism can degrade synthetic polymer materials, natural polymer materials, and mixtures of synthetic polymer materials and natural polymer materials, such as PLA, PBAT, PCL, and PGLA in synthetic polymer materials, and cellulose, lignin, starch, and protein in natural polymer materials.

In these research processes, it is often necessary to study the reaction conditions, such as temperature, humidity, oxygen concentration, etc., required by the reaction materials (which may be a mixture of microorganisms and environmentally friendly materials, a mixture of microorganisms and soil, a mixture of culture medium and microorganisms, etc.), and also to study the reaction properties of the reaction materials, such as the amount of carbon dioxide produced.

However, in the prior art, when the reaction conditions and the reaction performance of the reaction materials are studied, the reaction materials are mainly stirred by a vertical device and a stirring paddle so as to be uniformly mixed with moisture, oxygen and the like, and because the moisture and the materials are gathered together under the action of gravity, when the components of the reaction materials are complex, the reaction materials are easy to harden, and even if the stirring paddle is used for stirring, the reaction materials cannot be sufficiently mixed with the moisture and the oxygen, so that the reaction conditions of the reaction materials are not uniform; in addition, the vertical stirring paddle is easy to crack the reaction materials into powder, so that the vent pipeline is blocked, the reaction environment of the reaction materials cannot be kept consistent, and the difficulty is brought to the research on the reaction performance of the reaction materials.

Therefore, in order to overcome the defects of the prior art, a reaction device needs to be provided.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a reaction unit and application method thereof to solve at least one among the above-mentioned technical problem.

In order to achieve at least one of the above purposes, the following technical scheme is adopted in the application:

the present application provides a reaction apparatus comprising:

at least one reaction vessel capable of rotating along the axial direction of the reaction vessel, wherein the reaction vessel is used for containing reaction materials;

a gas supply system for providing humidified air to the reaction mass in the reaction vessel;

a processing system for processing the waste gas generated in the inner cavity of the reaction container;

the processing system comprises: the condensation device is communicated with the inner cavity of the reaction container through a first pipeline; the condensing device is used for condensing the useless gas to generate condensed water and secondary gas; the condensed water flows back to the inner cavity of the reaction container through a first pipeline;

the exhaust device is communicated with the condensing device through a second pipeline and used for receiving secondary gas, and the exhaust device is used for monitoring the concentration and the flow rate of the secondary gas and exhausting the secondary gas to the outside;

and one end of the first pipeline communicated with the condensing device is communicated with one end of the second pipeline communicated with the condensing device through a condensing pipe.

Optionally, the gas supply system comprises: an air collection device for collecting the outside air;

at least one gas controller in communication with the air collection device to receive air output by the air collection device; the gas controller is used for controlling the quantity of output air;

and the gas humidifier is used for humidifying the air output by the gas controller to form humid air, and the humid air is transmitted to the inner cavity of the reaction container through a third pipeline.

Optionally, the air collection device comprises: the air machine is used for collecting outside air and compressing the outside air to form compressed air;

a gas buffer to receive and decompress compressed air in the air motor;

the gas buffer delivers decompressed air to the gas controller.

Optionally, the gas humidifier comprises: the tank body is used for containing liquid, the tank body is communicated with the gas controller through a vent pipe, and the vent pipe extends to be below the liquid level;

the tank body is communicated with the inner cavity of the reaction container through the third pipeline, and the third pipeline extends into the tank body and is positioned above the liquid level.

Optionally, the gas humidifier further comprises: a heater for heating the liquid;

a temperature sensor to measure temperature;

and the temperature controller is electrically connected with the temperature sensor and the heater respectively.

Optionally, the exhaust means comprises:

the gas switcher is communicated with the condensing device through a second pipeline and is used for receiving secondary gas;

a flow detector for receiving the secondary gas output by the gas switch and for detecting the flow rate of the secondary gas;

and the concentration detector is used for receiving the secondary gas output by the flow detector and detecting the concentration of the secondary gas, and the secondary gas is discharged to the outside through the concentration detector.

Optionally, the inner cavity of the reaction vessel is provided with two partitions along the axial direction thereof;

the separator divides the inner cavity into an upper cavity, a main cavity and a lower cavity;

the separator comprises a plurality of through holes;

the main cavity is used for containing reaction materials, the first pipeline is communicated with the upper cavity, and the third pipeline is communicated with the lower cavity.

Optionally, the reaction apparatus further comprises:

a first temperature control box for containing the reaction vessel; and

a second temperature control box for containing the exhaust device.

Optionally, the temperature of the first temperature control box is 25-60 ℃;

the temperature of the condensing device is 1-20 ℃. Optionally, the reaction apparatus further comprises:

the driving device is used for driving the reaction container to rotate; and

a support frame for supporting the reaction vessel.

The beneficial effect of this application is as follows:

in view of the problems in the prior art, the present application provides a reaction apparatus, wherein the useless gas generated in the inner cavity of the reaction vessel is condensed by a condenser tube in the condensing apparatus, 80% to 90% of the moisture in the waste gas can be condensed, the formed condensed water flows back to the inner cavity of the reaction vessel through a first pipeline, so as to realize secondary utilization of the moisture in the waste gas, provide part of the moisture for the reaction material, avoid frequent water addition in the reaction cavity, and avoid the problem that the humidity and the reaction environment of the reaction material are not uniform due to frequent water addition, the moisture in the secondary gas exhausted to the outside through the exhaust apparatus, and the moisture and oxygen consumed during the reaction of the reaction material are supplemented by a gas supply system, which can provide gas flow for the inner cavity of the reaction vessel, avoid the gas flow change due to the change of the bulk density of the material and the microorganism reaction medium, and the humid air provided by the gas supply system can also provide moisture for the reaction material, avoid the reactor being dried at high temperature, and can also provide necessary components, such as oxygen, for the reactor. The exhaust device can monitor the concentration and flow rate of the secondary gas, and the amount of each gas component contained in the secondary gas generated by the reaction material in unit time can be calculated through the concentration and flow rate, so that the reaction performance and the growth condition of the reaction material can be calculated. By rotating the reaction vessel, the reaction vessel rotates intermittently, so that the reaction materials in the reaction vessel are uniformly mixed with the condensed water which flows back to the inner cavity of the reaction vessel and the humid air which is input into the inner cavity by the gas supply system, and each particle of the reaction materials can absorb nutrient components such as water and oxygen, thereby ensuring the air permeability and the humidity uniformity of the reaction materials; in addition, compare with the mode that adopts stirring rake stirring reaction material among the prior art, the shearing force between the reaction material has been reduced greatly to the rotatory mode of reaction vessel, has effectively avoided using the stirring rake to split into the powder with the reaction material so that the reaction condition of reaction material changes.

Drawings

The following describes embodiments of the present invention in further detail with reference to the accompanying drawings.

Fig. 1 shows a schematic view of the overall structure of a reaction apparatus in one embodiment of the present application.

Fig. 2 shows a schematic diagram of the overall structure of a reaction vessel of the reaction apparatus in one embodiment of the present application.

Fig. 3 shows a schematic diagram of the overall structure of the reaction vessel of the reaction apparatus in one embodiment of the present application.

Detailed Description

In the following description, for purposes of explanation, numerous specific details are set forth in order to provide a thorough understanding of one or more embodiments. It may be evident, however, that such embodiment(s) may be practiced without these specific details.

In the description of the present application, it should be noted that the terms "upper", "lower", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, which are only for convenience in describing the present application and simplifying the description, and do not indicate or imply that the referred device or element must have a specific orientation, be constructed in a specific orientation, and operate, and thus, should not be construed as limiting the present application. Unless expressly stated or limited otherwise, the terms "mounted," "connected," and "connected" are intended to be inclusive and mean, for example, that they may be fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present application can be understood by those of ordinary skill in the art as appropriate.

It is further noted that, in the description of the present application, relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrases "comprising a," "8230," "8230," or "comprising" does not exclude the presence of additional like elements in a process, method, article, or apparatus that comprises the element.

To solve the problems in the prior art, an embodiment of the present application provides a reaction apparatus, as shown in fig. 1 to 3, including: the reaction container 1 can be horizontally placed or obliquely placed, the inclination angle of the reaction container 1 is not more than 30 degrees, the length of the reaction container 1 in the axial direction is 10-50 cm, and the diameter of the longitudinal section is 10-30 cm, the reaction container 1 is used for containing reaction materials, the reaction materials can be microorganisms and a culture medium, the microorganisms grow under the action of the culture medium, and can also be a mixture of the microorganisms and an environment-friendly material, or a mixture of the microorganisms and soil; a gas supply system 2 for supplying humid air to the reaction material in the reaction vessel 1; a processing system for processing the useless gas generated in the inner cavity of the reaction container 1; the useless gas comprises gas generated by the reaction materials in the inner cavity and redundant humid air supplied by the gas supply system; the processing system comprises: the condensing device 3 is communicated with the inner cavity of the reaction vessel 1 through a first pipeline 5; conveying the useless gas to a condensing device 3 through a first pipeline 5, wherein the condensing device 3 is used for condensing the useless gas to generate condensed water and secondary gas, and the components of the secondary gas are mainly carbon dioxide and oxygen; of course, the condensing device 3 may also be located above the reaction vessel 1, and the condensed water flows back to the inner cavity of the reaction vessel 1 through the first pipeline 5; the exhaust device 4 is communicated with the condensing device 3 through a second pipeline 6 and is used for receiving the secondary gas, and the exhaust device 4 is used for monitoring the concentration and the flow rate of the secondary gas and exhausting the secondary gas to the outside; the one end that first pipeline 5 and condensing equipment 3 communicate with pass through condenser pipe 31 intercommunication between the one end that second pipeline 6 and condensing equipment 3 communicate, condensing equipment 3 includes condenser pipe 31, and condenser pipe 31 can be stainless steel pipe, and length is 0.4 meters to 0.6 meters.

In the above embodiment of the present application, the useless gas generated in the inner cavity of the reaction vessel 1 is condensed by the condenser pipe 31 in the condensing device 3, and 80% to 90% of moisture in the waste gas can be condensed, and the formed condensed water flows back to the inner cavity of the reaction vessel 1 through the first pipe 5, so as to realize secondary utilization of the moisture in the waste gas, provide part of moisture for the reaction material, avoid frequent water addition in the reaction cavity, and avoid the problem of non-uniform humidity and reaction environment of the reaction material due to frequent water addition, the moisture in the secondary gas exhausted to the outside through the exhaust device 4, and the moisture and oxygen consumed during the reaction of the reaction material are supplemented by the gas supply system 2, the gas supply system 2 can provide gas flow for the inner cavity of the reaction vessel 1, avoid the gas flow change due to the change of the bulk density of the material and the microorganism reaction medium, and the humid air provided by the gas supply system 2 can also provide moisture for the reaction material, avoid the reactor being dried due to high temperature, and can also provide necessary components, such as oxygen, for the reactor. The exhaust device 4 can monitor the concentration and flow rate of the secondary gas, and the amount of each gas component contained in the secondary gas generated by the reaction material in unit time can be calculated through the concentration and flow rate, so that the reaction performance and the growth condition of the reaction material can be estimated. By rotating the reaction container 1, the reaction container 1 rotates intermittently, so that the reaction materials in the reaction container are uniformly mixed with the condensed water which flows back to the inner cavity of the reaction container 1 and the humid air which is input into the inner cavity by the gas supply system 2, and each particle of the reaction materials can absorb nutrient components such as water and oxygen, thereby ensuring the air permeability and the humidity uniformity of the reaction materials; in addition, compare with the mode that adopts stirring rake stirring reaction material among the prior art, the shearing force between the reaction material has been reduced greatly to the rotatory mode of reaction vessel 1, has effectively avoided using the stirring rake to split into the powder with the reaction material so that the reaction condition of reaction material changes.

In one implementation, the exhaust device 4 includes: a gas switch 41 communicating with the condensing means 3 through a second pipe 6 to receive the secondary gas; a flow rate detector 42 for receiving the secondary gas outputted from the gas switching device 41 and detecting a flow rate of the secondary gas; the concentration detector 43 for receiving the secondary gas output from the flow rate detector 42 and detecting the concentration of the secondary gas discharges the secondary gas to the outside through the concentration detector 43. The concentration detector 43 can detect, for example, the concentration of carbon dioxide and the concentration of oxygen in the secondary gas, and the amount of carbon dioxide and oxygen generated in a unit time can be calculated from the concentrations and flow rates, each reaction vessel 1 and the gas switcher 41 are connected in sequence through the first pipeline 5, the condenser pipe 31 and the second pipeline 6, therefore, the gas switcher 41 is connected with a plurality of second pipelines 6, and if the exhaust device 4 wants to monitor the concentration and flow rate of the secondary gas generated by a certain reaction vessel 1, the corresponding second pipeline 6 can be switched by the gas switcher 41 to communicate with the flow rate detector 42, so as to detect the flow rate and concentration of the secondary gas generated by the reaction material in the reaction vessel 1.

In one implementation, the gas supply system 2 comprises: an air collection device 21 for collecting the outside air; at least one gas controller 22 in communication with the air collection device 21 to receive air output by the air collection device 21; the gas controller 22 is used for controlling the amount of output air; and at least one gas humidifier communicated with the gas controller 22 and used for humidifying the air output by the gas controller 22 to form humid air, and the humid air is transmitted to the inner cavity of the reaction vessel 1 through a third pipeline 7. The number of the gas controllers 22, the number of the gas humidifiers and the number of the reaction containers 1 are equal and are in one-to-one correspondence; the air collecting device 21 supplies the collected outside air to the gas controller 22, and the gas controller 22 controls the air supplied to the corresponding gas humidifier according to the reaction environment required for the reaction material in the corresponding reaction vessel 1, for example, the amount of the required oxygen and moisture, and the gas humidifier transfers the formed humidified air to the inner chamber of the corresponding reaction vessel 1 through the third line 7.

Specifically, the air collection device 21 includes: an air machine 211 for collecting the external air and compressing it to form compressed air, so that more air can be collected and stored in the air machine 211 to satisfy the reaction environment required for the reaction material in each reaction vessel 1; a gas buffer 212 for receiving and decompressing the compressed air in the air motor 211, the gas buffer 212 transmitting the decompressed air to the gas controller 22. The gas buffer 212 comprises a pressure reducing valve, and the compressed air is decompressed through the pressure reducing valve to reduce the original density of the air, so that the air conveyed to the gas humidifier can carry more water molecules after being humidified, and the moisture required by the reaction materials is met; if the compressed air is not decompressed, the moisture content of the humidified air introduced into the reaction vessel 1 is low even if the air is humidified by the gas humidifier because the density of the air is high, and the reaction environment of the reaction materials cannot be satisfied.

Further, the gas humidifier includes: a tank 231 for containing liquid, which may be water, the tank 231 is communicated with the gas controller 22 through a vent pipe 232, the vent pipe 232 extends to below the liquid level 233, so that decompressed air can enter the liquid, so that decompressed air can be washed, and the first humidification is performed, when the tank moves to above the liquid level 233, because the water vapor is above the liquid level 233, the first humidified air is mixed with the water vapor to humidify the tank for the second time, and a final humidified air is formed, and the third pipeline 7 extends to the tank 231 and is located above the liquid level 233, so that the humidified air is conveyed into the reaction container 1 through the third pipeline 7. Here, the humidity of the finally formed humid air may reach 50% to 99% by the first humidification and the second humidification. In practical applications, the tank 231 includes a water inlet (not shown) through which the liquid is injected into the tank 231 when the amount of the liquid therein is less than a predetermined volume.

In a specific example, the gas humidifier further comprises: a heater (not shown) for heating the liquid; a temperature sensor (not shown) for measuring temperature; and a temperature controller (not shown) electrically connected to the temperature sensor and the heater, respectively. The heater heats liquid, the temperature sensor measures the temperature of the liquid and transmits the measured temperature of the liquid to the temperature controller, the temperature controller controls the heater to continue heating the liquid according to the received temperature information of the temperature sensor, when the temperature of the liquid reaches a preset temperature, the temperature controller controls the heater to stop heating the liquid, and when the temperature of the liquid is lower than the preset temperature, the temperature controller controls the heater to heat the liquid.

In a specific embodiment, the inner cavity of the reaction vessel 1 is provided with two partitions along the axial direction thereof, which may be made of stainless steel, and the partitions divide the inner cavity into an upper cavity 13, a main cavity 14 and a lower cavity 15; the partition comprises a plurality of through holes 111, the aperture of each through hole 111 is small, for example, the diameter of each through hole 111 can be 0.1 mm to 5 mm, so that reaction material particles can be prevented from entering the upper cavity 13 or the lower cavity 15; the main cavity 14 is used for containing reaction materials, the first pipeline 5 penetrates through the upper cavity 13, and the third pipeline 7 penetrates through the lower cavity 15. Specifically, the separator includes: baffle 11 along the axial direction setting of reaction vessel 1, through-hole 111 sets up on baffle 11, by two curb plates 16 that the both sides border orientation of baffle 11 formed of deviating from the direction extension of main cavity 14, two curb plates 16 are fixed with the inner wall connection of inner chamber. The arrangement of the through holes 111 on the partition plate 11 can not only prevent the reaction materials from entering the upper cavity 13 or the lower cavity 15, thereby avoiding blocking the port of the first pipeline 5 and the port of the third pipeline 7, but also can enable the humid air conveyed by the first pipeline 5 to enter the main cavity 14 through the through holes 111 on the partition plate 11 more uniformly; when reaction vessel 1 irrotational, go up cavity 13 and cavity 15 down and be relative setting in vertical direction, unnecessary moisture can gather cavity 15 down in the reaction inner chamber, when reaction vessel 1 is rotatory, the moisture that lies in cavity 15 down passes through-hole 111 on the baffle 11 and gets into in the main cavity 14, thereby make reaction material and the moisture homogeneous mixing in the main cavity 14, so that every granule of reaction material can both absorb sufficient moisture, effectively avoided causing the inhomogeneous phenomenon of reaction material humidity because of the moisture gathering.

In practical application, the reaction vessel 1 rotates intermittently, namely rotates 180 degrees clockwise and rotates 180 degrees counterclockwise, so that the reaction vessel 1 can return to the initial state, and the first pipeline 5 and the third pipeline 7 cannot be damaged due to rotation; the intermittent time can be set, and when the set time is reached, the reaction vessel 1 rotates once, namely, rotates 180 degrees clockwise and then rotates 180 degrees counterclockwise.

In a specific embodiment, the reaction apparatus further comprises: a first temperature control box for holding the reaction vessel 1; and a second temperature control box for housing the exhaust means 4. When the reaction container 1 is provided with a plurality of reaction containers, the reaction containers 1 are all positioned in a first temperature control box, so that the temperature in the reaction containers 1 reaches the temperature required by the reaction of the reaction materials, and particularly, the temperature of the first temperature control box is 25-60 ℃, and is preferably 58 ℃; the temperature of the condensing means 3 is 1 to 20 c, preferably 5 c, so that the temperature of the exhaust gas transferred from the reaction vessel 1 to the condensing means 3 can be rapidly lowered to form condensed water; since the concentration detector 43 is sensitive to temperature, and the temperature is too low to cause drift, the temperature of the secondary gas output by the condensing device 3 needs to be raised, and the whole exhaust device 4 is placed in the second temperature control box, so that the gas switch 41, the flow rate detector 42 and the concentration detector 43 are always kept at a higher temperature than the condensing device 3, so that the temperature of the secondary gas input into the exhaust device 4 can be raised when the secondary gas passes through the gas switch 41 and the flow rate detector 42, and the concentration of the secondary gas can be detected when the secondary gas flows to the concentration detector 43. If the temperature of the exhaust device 4 is lower than the temperature of the secondary gas discharged from the condensing device 3, the secondary gas entering the exhaust device 4 will condense on the gas switching device 41, the flow rate detector 42 and the concentration detector 43, thereby affecting the detection accuracy; specifically, the temperature of the second temperature control box is 20 to 50 ℃, and the concentration detector 43 may be an infrared detector or a laser detector, which may be selected according to the composition of the detection gas.

In a specific example, a temperature detector (not shown) is further disposed on the inner sidewall of the reaction vessel 1 for detecting the temperature in the inner cavity of the reaction vessel 1. Because the reaction materials in the reaction container need to consume and release energy during reaction, the difference between the temperature in the inner cavity of the reaction container 1 and the temperature in the first temperature control box can be caused, and the temperature in the first temperature control box can be controlled according to the temperature of the inner cavity of the reaction container 1 detected by the temperature detector.

In one embodiment, as shown in fig. 2 to 3, the reaction apparatus further comprises: a driving device for driving the reaction container 1 to rotate; and a support frame 9 for supporting the reaction vessel 1. The drive device includes: a driving motor 81, and a driving member 82 connected to the driving motor 81; the reaction vessel 1 is in a cylindrical structure and can be made of high boron glass; the reaction vessel 1 includes a rotating part 12 connected to a driving member 82; when the driving motor 81 drives the driving member 82 to rotate, the driving member 82 drives the rotating part 12 to rotate; specifically, the rotating portion 12 includes two first blocking surfaces 121 and two second blocking surfaces (not shown in the figure) which are oppositely arranged, when the reaction vessel 1 does not rotate, the first blocking surfaces 121 are located at the lower position, that is, contact with the driving member 82, after the reaction vessel 1 rotates clockwise 180 degrees, the second blocking surfaces rotate to the lower position, that is, block the driving member 82 from continuing to rotate, then, the reaction vessel 1 rotates counterclockwise 180 degrees, at this time, the first blocking surfaces 121 return to the original position, that is, located at the lower position, block the driving member 82 from continuing to rotate, and the driving motor 81 stops working.

In a specific example, as shown in fig. 2 to 3, the driving member 82 may be a roller with a large friction force, and the rotating portion 12 includes a rotating surface 123 with a circular arc shape between the first stopping surface 121 and the second stopping surface, and also has a friction force, and when the driving member 82 rotates, the rotating surface 123 is driven to rotate by the friction force between the roller and the rotating surface 123. In another embodiment, the driving member 82 may also be a gear, and the first stopping surface 121 and the second stopping surface of the rotating portion 12 include a semicircular toothed ring engaged with the gear, and when the driving member 82 rotates, the gear drives the toothed ring to rotate.

In a specific embodiment, the reaction vessel 1 further comprises a feed inlet through which the reaction material is placed into the inner cavity or taken out of the inner cavity; the first and

third pipelines

5, 7 extend through the second side into the upper and

lower chambers

13, 15, respectively.

In a specific embodiment, the reaction apparatus provided herein further comprises a control system comprising a temperature controller in the gas humidifier; a temperature detector arranged in the inner cavity of the reaction container 1 is connected with a control system; the control system may control the temperatures of the first temperature control tank (not shown in the drawings), the second temperature control tank (not shown in the drawings), and the condensing device 3, control the operation state of the driving motor 81 for driving the reaction vessel 1, control the amount of humid air and the humidity of humid air transferred to the reaction vessel 1 by the gas supply system 2, and the amount and temperature of liquid in the tank 231; the operation of the gas switcher 41 in the exhaust device 4 is controlled so that the flow rate detectors 42 can communicate with the corresponding second pipes 6.

In practical application, the operation time of the reaction device provided by the application is 10-180 days, the temperature of the inner cavity of the reaction container 1 is 25-60 ℃ and the humidity is 70-99% in the operation process, and the reaction container 1 is intermittently rotated by the driving device.

The embodiment of the present application further provides a method for using the reaction device, including: placing the reaction materials into the inner cavity of the reaction container 1; specifically, the reaction material is put into the inner cavity of the reaction vessel 1 through the feed inlet. Providing humid air to the reaction mass in the reaction vessel 1 through a gas supply system 2; specifically, the gas supply system is communicated with the inner cavity of the reaction vessel 1 through the third pipe 7 to deliver the humid air into the inner cavity. The useless gas generated in the reaction container 1 is transmitted to a condensing device 3 through a first pipeline 5, and is condensed to generate condensed water and secondary gas; the condensed water flows back to the inner cavity of the reaction container 1 through a first pipeline 5, and the secondary gas is transmitted to an exhaust device through a second pipeline 6; the concentration and flow rate of the secondary gas are monitored by the exhaust device 4, and the secondary gas is exhausted to the outside. The details of the reaction vessel 1, the condensing unit 3 and the exhaust unit 4 in the processing system, and the gas supply system 2 correspond to the above-mentioned embodiments of the reaction apparatus, and the detailed implementation process is not described herein again.

Obviously, the above embodiments of the present invention are only examples for clearly illustrating the present invention, and are not intended to limit the embodiments of the present invention, and it is obvious for those skilled in the art to make other variations or changes based on the above descriptions, and all the embodiments cannot be exhausted here, and all the obvious variations or changes that belong to the technical solutions of the present invention are still in the protection scope of the present invention.

Claims

1. A reaction apparatus, comprising:

2. The reactor apparatus according to claim 1,

the gas supply system includes: an air collection device for collecting the outside air;

3. The reactor apparatus according to claim 2,

the air collection device includes: the air machine is used for collecting outside air and compressing the outside air to form compressed air;

a gas buffer to receive and decompress compressed air in the air motor;

the gas buffer delivers decompressed air to the gas controller.

4. The reactor apparatus according to claim 2,

the gas humidifier includes: the tank body is used for containing liquid and is communicated with the gas controller through a vent pipe, and the vent pipe extends to a position below the liquid level;

5. The reactor apparatus according to claim 4,

the gas humidifier further comprises: a heater for heating the liquid;

a temperature sensor to measure temperature;

6. The reactor apparatus according to claim 1,

the exhaust apparatus includes:

a flow detector for receiving the secondary gas outputted from the gas switching device and detecting the flow rate of the secondary gas;

7. The reactor apparatus according to claim 2,

the inner cavity of the reaction container is provided with two separators along the axial direction;

the separator comprises a plurality of through holes;

8. The reactor apparatus according to claim 1,

the reaction apparatus further comprises:

a first temperature control box for holding the reaction vessel; and

a second temperature control box for containing the exhaust device.

9. The reactor apparatus according to claim 1,

the reaction apparatus further comprises:

the driving device is used for driving the reaction container to rotate; and

a support frame for supporting the reaction vessel.