RU109275U1 - GAS-AIR FLOW NORMALIZATION UNIT - Google Patents

Abstract

 1. The normalization of the gas-air flow, characterized in that it contains a housing on which are placed a flange for supplying a gas-air flow, a flange for outputting a gas-air flow, an axis is installed in the housing that is transverse to the direction of movement of the gas-air flow and is connected to rotation drive, at least three plates parallel to each other are mounted on the axis, means for supplying fluid to the housing and controlled means for withdrawing fluid from the housing are located on the housing, a spacing is arranged in the lower part of the housing A controlled means of changing the temperature of a liquid is born. ! 2. The block according to claim 1, characterized in that the plates are made of a material with high thermal conductivity. ! 3. The block according to claim 2, characterized in that the plates are made of aluminum alloy. ! 4. The block according to claim 2, characterized in that the plates are made of a polymer composite containing a powdered metal filler. ! 5. The block according to claim 1, characterized in that the plates are made in the form of disks. ! 6. The block according to claim 1, characterized in that it further comprises means for measuring and maintaining the liquid level in the housing. ! 7. The block according to claim 6, characterized in that the liquid measuring means in the housing is configured to open / close the liquid supplying means to the housing and the liquid withdrawing means from the housing. ! 8. The block according to claim 1, characterized in that it further comprises means for mechanically cleaning the surface of the plates. ! 9. The block according to claim 1, characterized in that it further comprises means for sterilizing the internal volume of the housing. ! 10. The block according to claim 1, characterized in that it further comprises a temperature measuring means

Description

The technical solution relates to the field of conditioning of gas-air mixtures, preferably gas-air mixtures, arriving for biological treatment, and can be used as a unit for preliminary processing of gas-air mixtures, arriving for microbiological cleaning and deodorization.

Within the framework of this technical solution, the term “normalization” as applied to a gas-air flow will mean bringing the temperature and humidity of the initial gas-air flow to predetermined values while simultaneously giving the initial gas-air flow a laminar flow pattern.

Known (RU, patent 2363896) apparatus for heat-humidity treatment of air containing a mixing chamber, a heater and an irrigation unit. Known apparatus consists of two steps. The first stage is a multifunctional apparatus with oncoming swirling flows and is designed to remove dust from the recirculated air coming from the room and having a positive temperature, as well as to humidify the air. The first stage includes a housing with a container for collecting liquid, in which a pump with a filter is located to recirculate the liquid through the pipeline and supply it to the irrigation unit, which is made in the form of at least two circular tubular collectors with uniformly distributed on the inner surface centrifugal nozzles. The specified pipeline for recirculating liquids contains a control valve mixer for connecting to a water supply system through a pipe to a source of chilled water from the refrigeration machine. The lower inlet pipe is located in the lower part of the housing, and the upper inlet pipe is in the upper part. In the nozzles, respectively, the lower tangential twist and the upper tangential twist are installed. An exhaust pipe connects the first stage of the device with the second stage of the device, designed to mix the air flows coming from the first stage with the flow of external air. The second stage of the device is made in the form of a heat and mass transfer apparatus for mixing and includes an inlet pipe of the mixing chamber, a centrifugal mixing chamber, a diffuser, a confuser, a spinner, and an outlet pipe.

A disadvantage of the known apparatus, designed to bring the characteristics of the gas-air (mixture of air and water vapor) flow to predetermined values, is its structural complexity, as well as the impossibility of laminating the gas-air flow.

Also known (RU, patent 2264844) is an inertial inertial dust collector containing a slotted nozzle for supplying a gas stream located at an angle to the horizontal axis, oriented downward tangentially to a convex curved surface located adjacent to the upper part of the nozzle. The developed dust collector is additionally equipped with disks partially immersed in a liquid used to precipitate coarse dust, located opposite the nozzle longitudinally with respect to the gas flow, allowing them to rotate in countercurrent and to deposit fine dust on the wetted surface.

Although during the operation of the known device, in addition to dust separation, some humidification of the air occurs, the known device is not suitable for changing the temperature of the cleaned air, as well as for imparting a laminar flow to the stream.

Known (RU, patent 2090246) is the design of a bioreactor for cleaning air from toxic, harmful and unpleasantly smelling volatile substances, containing a housing, inside of which there are supporting shelves with a biocatalyst placed on the path of the cleaned air, a system for maintaining the activity of the biocatalyst, ducts for supplying subject to cleaning and removal of purified air. As a biocatalyst, a polymeric carrier of a voluminous porous structure with immobilized cells of microorganisms adapted to the corresponding pollutants was used, while the system for maintaining the activity of the biocatalyst is equipped with a system for regenerating the properties of the circulating aqueous solution of mineral salts necessary to maintain normal functioning of the microorganisms included in the composition of the biocatalyst. At the inlet of the bioreactor, a pre-treatment unit for the gas-air mixture to be processed is installed, consisting, as a rule, of a shelf reinforced in the main or in a separate container with a filler placed on it (gravel or pieces of slag) and a water spray system above the layer of this filler. The temperature of the water sprayed in the pre-treatment unit of the gas-air mixture to moisturize the latter is controlled in order to obtain the desired characteristics (temperature and humidity) of the gas-air mixture supplied to the biologically active filter layer.

The known device is also not suitable for a significant change in the temperature of the cleaned air, as well as imparting laminar motion to the air flow.

The applicant has not identified a source of information in which a device would be disclosed that would simultaneously control the temperature, humidity and degree of ordering (lamination) of the gas-air flow.

The technical problem solved by the developed design of the installation for normalizing the flows of gas-air mixtures is to create a device that simultaneously provides temperature, humidity and the degree of ordering (lamination) of the gas-air flow.

The technical result obtained by the implementation of the developed design of the installation for normalizing the flows of gas-air mixtures consists in improving the quality of their processing, preferably when passing through microbiological cleaning and deodorizing plants.

To achieve the specified technical result, it is proposed to use a gas-air flow normalization unit. The specified block contains a housing on which there is a gas-air flow supply flange, a gas-air flow outlet flange, an axis is installed in the housing that is transverse to the direction of gas-air flow movement and connected to the rotation drive, at least three plates are mounted on the axis, located parallel to each other, on the body there is a means for supplying liquid to the body and a controlled means for withdrawing liquid from the body, in the lower part of the body there is a means for changing the temperature of the liquid .

Preferably, the housing is made of a material with low thermal conductivity, which reduces the loss of thermal energy. The inlet and outlet gas-air flow connection flanges can be of any type providing a tight connection. The number of plates and their size depend on the operating conditions of the unit - the flow rate of the cleaned gas-air stream, temperature and humidity levels of the gas-air stream at the inlet of the block. The gap between the plates also depends on the operating conditions of the unit. Means of input and output of fluid from the housing are configured to maintain a fluid level in the housing above the level of the means for changing the fluid temperature, but below the lower levels of entry and exit of the gas-air flow in the housing. The means for changing the temperature, depending on the application conditions of the developed unit, can heat or cool the gas-air flow by heating or cooling the liquid in the housing.

Preferably, the plates are made of a material with high thermal conductivity. This provides a sufficiently fast heat exchange between the plates and the liquid filling at least the lower part of the housing, and between the plates and the gas-air flow passing through the housing.

Mostly the plates are made of aluminum alloy. This is a fairly corrosion-resistant material, with high heat-conducting characteristics and low specific gravity, which allows the use of plates of a significant volume, but of a small mass, which reduces the inertia of the plate system. The plates may also be made of a polymer composite containing a powdered metal filler. Such material is close in its physical characteristics to aluminum alloys.

Preferably, disc shaped plates are used. Their surface, depending on the conditions of use, may have a smooth or corrugated surface. The edges of the plates can be made both flat and serrated.

Typically, the unit further comprises means for measuring and maintaining the liquid level in the housing. For this, any type of level gauge can be used, made with the possibility of opening / closing the means for supplying liquid to the housing and means for removing liquid from the housing.

The block may further comprise means for mechanically cleaning the surface of the plates. During operation, a layer of microorganisms may appear on the surface of the plates, preventing the transfer of heat from the plates to the gas-air flow. In addition, a layer of dust particles from a passing gas-air stream may adhere to the plates.

The block may additionally contain means for sterilizing the internal volume of the housing, preventing the development of cultures of microorganisms on the surface of the plates and the inner surface of the housing. For this purpose, any type of sterilization agent can be used that can fit inside the case.

To more accurately maintain the characteristics of the outgoing gas-air flow, the unit may further comprise means for measuring the temperature of the liquid. In this case, it is preferable that said means for measuring the temperature of the liquid be adapted to control the means for heating the liquid.

The means used to change the temperature of the liquid may be any. In various embodiments, the temperature changing means may be a heating element, steam pipe, hot water pipe, thick film resistor, or any type of refrigerator.

All these tools using an external source of electrical energy (axis rotation drive, means for supplying liquid to the case, controlled means for removing liquid from the case, controlled means for changing the temperature of the liquid, means for measuring and maintaining the liquid level in the case, means for measuring the temperature of the liquid) are connected to the source electric current, and, preferably, the connection is made through a control unit made on the basis of a microprocessor.

In the basic version, the developed block can be used as follows.

The block is placed between the source of the gas-air mixture (in particular, the ventilation outlet from the production room) and the microbiological purification means of the gas-air mixture. By means of flanges located on the housing, the unit is connected to the ventilation line. Fill the bottom of the housing with liquid, preferably water. Include a means of changing the temperature of the water. After the liquid reaches the required temperature, the drive rotates the plates and the supply of the treated gas-air mixture. During the passage of the processed gas-air mixture through the housing with rotatable plates, the gas-air flow is normalized.

Claims (16)

1. The normalization of the gas-air flow, characterized in that it contains a housing on which are placed a flange for supplying a gas-air flow, a flange for outputting a gas-air flow, an axis is installed in the housing that is transverse to the direction of movement of the gas-air flow and is connected to rotation drive, at least three plates parallel to each other are mounted on the axis, means for supplying fluid to the housing and controlled means for withdrawing fluid from the housing are located on the housing, a spacing is arranged in the lower part of the housing A controlled means of changing the temperature of a liquid is born. 2. The block according to claim 1, characterized in that the plates are made of a material with high thermal conductivity. 3. The block according to claim 2, characterized in that the plates are made of aluminum alloy. 4. The block according to claim 2, characterized in that the plates are made of a polymer composite containing a powdered metal filler. 5. The block according to claim 1, characterized in that the plates are made in the form of disks. 6. The block according to claim 1, characterized in that it further comprises means for measuring and maintaining the liquid level in the housing. 7. The block according to claim 6, characterized in that the liquid measuring means in the housing is configured to open / close the liquid supplying means to the housing and the liquid withdrawing means from the housing. 8. The block according to claim 1, characterized in that it further comprises means for mechanically cleaning the surface of the plates. 9. The block according to claim 1, characterized in that it further comprises means for sterilizing the internal volume of the housing. 10. The block according to claim 1, characterized in that it further comprises means for measuring the temperature of the liquid. 11. The block according to claim 1, characterized in that the means for changing the temperature of the liquid is a heater. 12. The block according to claim 1, characterized in that it further comprises means for measuring the temperature of the liquid, configured to control the heating element. 13. The block according to claim 1, characterized in that the means for changing the temperature of the liquid is a steam line. 14. The block according to claim 1, characterized in that it further comprises means for measuring the temperature of the liquid, while the means for changing the temperature of the liquid is a steam line, and the means for measuring the temperature of the liquid is configured to control the steam line. 15. The block according to claim 1, characterized in that the means for changing the temperature of the liquid is a refrigerator. 16. The block according to claim 1, characterized in that it further comprises means for measuring the temperature of the liquid, and a refrigerator is used as a means for changing the temperature of the liquid, while the means for measuring the temperature of the liquid is adapted to control the refrigerator.