RU2567956C2 - Different-temperature condensation chamber - Google Patents

Abstract

FIELD: process engineering.

SUBSTANCE: invention relates to dust precipitation equipment. Different-pressure condensation chamber with rectangular-section gas channel comprises lower bottom, upper bottom, cold and hot channel walls with means providing for temperature difference at outer surfaces of said walls. Upper and lower bottoms are connected by side walls to make closed chamber. Said walls are furnished with connectors to allow feeding working body into pipelines and mounting meters therein. Duct side walls are composed of parts, flexible jointed, to perform angular and radial displacement both inside and outside of said gas duct. Note here that said duct is composed of top, bottom and lateral walls. Rib is fitted at the chamber centre to divide it into two parts. Note also that said rib is fitted along chamber lengthwise axis, mainly, parallel therewith and with shift to stage hot sidewall for x = (0.1…0.3)X, where X is rib shift to hot sidewall, X is channel width.

EFFECT: higher gas purity.

8 cl, 2 dwg

Description

The invention relates to equipment for dust collection and can be used in any sector of the economy where the capture of highly dispersed aerosols from the air duct is required, in particular in the food industry.

A known installation containing an intake air humidifier, a compressor, a compressed air humidifier, a heater, a multi-temperature condensation chamber with a gas path of mainly rectangular cross-section, connected in series with each other, while the condensation chamber path is made with a length to height ratio of more than 20, one of its longitudinal walls made with the possibility of radial movement, and the output of the gas path of the multi-temperature condensation chamber is connected to a moisture separator, p those working on the principle of a Venturi pipe (RF patent No. 2323033, IPC: B01D 47/05).

The main disadvantage of the known condensation chamber is that the design of the cold and hot walls does not allow changing the geometry of the path depending on the operating conditions of the chamber, which leads to significant energy losses.

Known multi-temperature condensation chamber with a gas path of predominantly rectangular cross-section, containing a lower bottom, upper bottom, cold and hot side walls of the tract with devices to ensure the temperature difference of their outer surfaces, while the upper and lower bottoms are interconnected along the peripheral part using side walls with the formation of a closed cavity in the walls of which the connectors are made to provide the possibility of supplying into the cavity of the pipelines of the working fluid and measuring instruments the shackle walls of the tract are made up of several movably interconnected parts having the possibility of angular and radial movements both in and out of the gas path, while the path is formed by the upper, lower bottoms and side walls of the tract (RF patent No. 2476256, IPC: B01D 47 / 05, - prototype).

The specified multi-temperature condensation chamber operates as follows.

The cleaned air enters the compressor, where it is compressed to the specified parameters. From the compressor, the compressed cleaned air is supplied to a compressed air humidifier and then to the heater, where it is given the required humidity and temperature. Next, the compressed air produced by the compressor, passed through a compressed air humidifier and heater, is supplied to a different-temperature chamber, in which water vapor condenses on condensation nuclei, for example, mechanical impurities, gas ions, and spontaneously formed nuclei on the surface and grow to drop sizes.

The different temperature organization of the condensation process in the channel contributes to the shift of the condensation zone from the cold wall to the flow core and at the same time allows it to expand along the cross section of the path. Under such temperature conditions, the bulk of the condensate is not released on the cold wall in the form of a film, but in the flow core, because the first condensation conditions are created there.

The main disadvantage of this chamber is the insufficiently high degree of flow purification associated with the insufficiently high level of turbulization and mixing of the vapor-air flow.

The technical task of the invention is to eliminate these drawbacks and create an installation for air purification, the use of which will allow for more complete separation of condensate and solids from the gas stream to be cleaned.

The solution to this problem is achieved due to the fact that in the proposed multi-temperature condensation chamber with a gas path of predominantly rectangular cross-section, comprising a lower bottom, upper bottom, cold and hot side walls of the tract with devices for ensuring the temperature difference of their outer surfaces, while the upper and lower bottoms are connected between each other along the peripheral part using the side walls with the formation of a closed cavity in the walls of which the connectors are made to provide the possibility of supply in the morning of the cavity of the pipelines of the working fluid and measuring instruments, the side walls of the tract are made up of several movably interconnected parts having the possibility of angular and radial movements both inside and outside the gas path, while the path is formed by the upper, lower bottoms and side walls of the path, according to the invention, a rib is installed in the central part of the chamber, by means of which the chamber cavity is divided into two parts, said rib being configured to communicate parts of the chamber cavity s between each other, while the specified edge is installed along the longitudinal axis of the camera, mainly parallel to it, with an offset x = (0.1 ... 0.3) X from the longitudinal axis of the tract from the longitudinal axis, where x is the offset distance ribs in the direction of the hot side wall, X is the width of the channel.

The lower value of this ratio was chosen on the basis that with a further decrease in it, part of the working contaminated stream immediately falls into the hot zone, where condensation enlargement of impurity particles does not occur, respectively, this part of the stream will reach a saturation state much later and here the impurity particles will not have time to leave flow during the installation.

The upper value of this ratio was chosen on the basis that with a further increase in the speed of the convection process in the cold zone, due to the different temperature of the channel walls, the positive effect of swirling the working flow also decreases, in order to intensify heat and mass transfer processes.

In the embodiment, gaps are made between the specified rib and the bottoms, while the size of each said gap is δ = (0.1 ... 0.3) h, where δ is the gap between the upper / lower bottoms and the rib, h is the height of the path formed upper and lower bottoms.

The lower value of the indicated ratio was chosen based on the fact that with a further decrease in the gap less than the indicated one, the convection process speed increases significantly near the cold wall, but stagnant non-working zones are observed in the cold zone near the rib, which worsens the process of volume condensation in the cold zone and, accordingly, adversely affects the quality of cleaning.

The upper value of the specified ratio is chosen on the basis that with a further increase in the gap greater than the indicated value, a sharp decrease in the volume of the cold zone occurs, which negatively affects the stability of the condensation process and, as a consequence, the quality of gas stream cleaning.

In the embodiment, through channels are made in the rib, by means of which the said chamber cavities communicate with each other, while the total area of the channels is s = (0.25 ... 0.4) S, where s is the total area of the through channels, S is the area of the longitudinal section of the tract at the installation site of the ribs.

The lower value of the indicated ratio was chosen on the basis that with a further decrease in the total channel area less than the indicated one, the positive effect of thermal diffusion on the process of enlargement of impurity particles becomes negligible and does not contribute to the intensification of the process of condensation purification of gas flows.

The upper value of the specified ratio is selected on the basis that with a further increase in the total area of the channels greater than the specified one, the stable circulation of the gas stream is destroyed as a result of convection due to its intense transverse motion as a result of thermal diffusion. As a result, the mixing of the layers of the gas stream deteriorates and the condensation process is less intense.

In an embodiment, the rib dividing the chamber cavity into two parts is profiled, with a cross section in the form of alternating protrusions and depressions.

In an embodiment, the entrance wall of the tract is movable.

In an embodiment, the cold wall is made in the form of a hollow body with fittings for supplying and discharging the working fluid.

In an embodiment, the hot wall is made in the form of a hollow body with fittings for supplying and discharging the working fluid.

In an embodiment, the hot wall is made in the form of a plate with an electric heating element placed on its surface.

The invention is illustrated by drawings, in which Fig. 1 shows a multi-temperature condensation chamber in a perspective view with a path tapering in the inlet part, in Fig. 2 - a multi-temperature condensation chamber in a perspective view with a path expanding in an inlet part.

Different temperature condensation chamber 1 contains a lower bottom 2, upper bottom 3, cold 4 and hot 5 side walls of the tract. The upper 3 and lower 2 bottoms are interconnected along the peripheral part by means of side walls 6 with the formation of a closed cavity 7, the walls of which are made of connectors 8 to allow the supply of the working fluid and measuring instruments into the cavity of the pipelines 9. The side walls 4 and 5 of the tract are made up of several movably interconnected parts 10 and 11, respectively, with the possibility of angular and radial movements both in and out of the gas path 12, while the path 12 is formed by the upper 3, lower 2 bottoms and side walls tract 4 and 5. In the Central part of the chamber 1, along its longitudinal axis, mainly parallel to it, a rib 13 is installed that separates the chamber cavity into two parts 14 and 15, while these parts of the chamber cavity communicate with each other.

In the embodiment, between the rib 13 and the bottoms 2 and 3, gaps 16 and 17 are made, respectively.

In an embodiment, through channels 18 are made in rib 13.

The proposed multi-temperature condensation chamber operates as follows.

The cleaned air enters the compressor, where it is compressed to the specified parameters.

From the compressor, the compressed cleaned air is supplied to a compressed air humidifier and then to the heater, where it is given the required humidity and temperature.

Next, the compressed air produced by the compressor, passed through a compressed air humidifier and heater, is supplied to a different-temperature chamber, in which water vapor condenses on condensation nuclei, for example, mechanical impurities, gas ions, and spontaneously formed nuclei on the surface and grow to drop sizes.

The different temperature organization of the condensation process in the channel contributes to the shift of the condensation zone from the cold wall to the flow core and at the same time allows it to expand along the cross section of the path. Under such temperature conditions, the bulk of the condensate is not released on the cold wall in the form of a film, but in the flow core, because the first condensation conditions are created there. This leads to a more efficient camera.

The separation of the cavity of the chamber 1 by means of the rib 13 into two cavities 14 and 15 leads to the expansion of the condensation zone, where coarsening and removal of impurity particles from the working stream takes place. Also, when installing the rib 13, the convection process observed in the cross section of the channel increases due to the side walls having different temperatures. This leads to mixing of the layers of the gas stream and, accordingly, the intensification of heat and mass transfer processes when cleaning the working stream from aerosol impurities. This has a positive effect on the degree of purification and the lead time of this process.

Passing through the formed condensation zone in a different temperature channel, the aerosol particles contained in the cleaned air stream are ready-made condensation centers, which affects the efficiency of the entire installation. In this zone, gaseous and liquid impurities present in the air stream condense and settle on the surface of the present centers, thereby weighting them to the size of droplets, which then settle to the bottom of the channel.

The presence of gaps between the ribs and the walls of the chamber and the through channels in the rib allows flows from one chamber to flow freely into another, depending on the temperature conditions of the walls and ribs.

Due to the fact that the parts of the walls of the multi-temperature chamber are made with the possibility of radial movement, the required conditions for the passage of the cleaned flow through the gas path of the multi-temperature chamber by changing the area of the passage section of the tract and obtaining its desired configuration are provided.

Due to the fact that the upper 2 and lower 1 bottoms are interconnected along the peripheral part using the side walls 6 with the formation of a closed cavity, increased pressure is created in the tract and in the specified closed cavity, which leads to an improvement in the conditions for condensate separation.

Due to the initial part of the walls being hotter than the other parts, there is a significant decrease in the input of metastable supersaturation, and, accordingly, the zone of stable supersaturation, uniform in cross section both along and across the flow, increases.

One part of the condensate is trapped in the chamber, and the remaining part is trapped in the water separator located behind it. The kit, consisting of humidifiers and a heater, allows you to change the humidity and temperature of the air flow over a wide range.

The tests carried out by the authors and the applicant of a full-sized air purification installation confirmed the correctness of the design and technological solutions.

Using the proposed technical solution will allow for a more complete separation of condensate and mechanical impurities from the gas stream subjected to purification, with less energy.

Claims (8)

1. A multi-temperature condensation chamber with a gas path of predominantly rectangular cross-section, comprising a lower bottom, upper bottom, cold and hot side walls of the tract with devices for ensuring the temperature difference of their outer surfaces, while the upper and lower bottoms are interconnected peripherally by side walls with the formation of a closed cavity, in the walls of which the connectors are made to provide the possibility of supplying into the cavity of the pipelines of the working fluid and measuring instruments, lateral path ducts are made up of several movably interconnected parts having the possibility of angular and radial movements both in and out of the gas path, while the path is formed by the upper, lower bottoms and side walls of the path, characterized in that a rib is installed in the central part of the chamber by means of which the chamber cavity is divided into two parts, said rib being configured to communicate parts of the chamber cavity to each other, said rib being installed along the longitudinal axis the camera, mainly parallel to it, with an offset towards the hot side wall of the tract from the longitudinal axis by a distance x = (0.1-0.3) X, where x is the offset distance of the ribs towards the side of the hot side wall, X is the channel width. 2. The multi-temperature condensation chamber according to claim 1, characterized in that there are gaps between the specified rib and the bottoms, while the size of each said gap is δ = (0.1-0.3) h, where δ is the gap between the upper / lower bottoms and rib, h is the height of the path formed by the upper and lower bottoms. 3. The multi-temperature condensation chamber according to claim 1, characterized in that there are through channels in the rib through which said chamber cavities communicate with each other, and the total channel area is s = (0.25-0.4) S, where s is the total area of the through channels, S is the area of the longitudinal section of the tract at the location of the rib. 4. The multi-temperature condensation chamber according to claim 1, characterized in that the rib dividing the chamber cavity into two parts is shaped, with a cross section in the form of alternating protrusions and depressions. 5. The multi-temperature condensation chamber according to claim 1, characterized in that the entrance wall of the path is movable. 6. The multi-temperature condensation chamber according to claim 1, characterized in that the cold wall is made in the form of a hollow body with fittings for supplying and discharging the working fluid. 7. The multi-temperature condensation chamber according to claim 1, characterized in that the hot wall is made in the form of a hollow body with fittings for supplying and discharging the working fluid. 8. The multi-temperature condensation chamber according to claim 1, characterized in that the hot wall is made in the form of a plate with an electric heating element placed on its surface.

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