RU229719U1 - AIR TREATMENT APPARATUS - Google Patents

Abstract

The utility model relates to air treatment devices intended to bring air to the required parameters (conditioning). An air treatment device is disclosed, having an elongated housing, in which the following are arranged in sequence: an air intake zone, a preheating zone containing a means for heating the air, a filtration zone containing a means for filtering the air, a cooling zone containing a means for cooling the air, a drip collection zone containing a means for catching the drops, a heating zone containing a means for heating the air. In this case, the drip collection zone contains means for removing moisture, including an intermediate means for removing moisture and a lower means for removing moisture. The intermediate means for removing moisture is located at a distance H8a from the upper wall of the housing, equal to 0.3-0.7 of the height of the housing H5 in the drip collection zone. The lower moisture removal means is located at a distance H8b from the upper wall of the housing, equal to more than 0.8 of the height of the housing H5 in the drip collection zone. The technical result of the utility model is to increase the efficiency of the process of reducing the relative humidity of the air with low metal consumption of the device.

Description

Field of technology

The utility model relates to air treatment devices intended to bring air to the required parameters (conditioning). The air treatment unit is placed in lines supplying air to process equipment in various chemical industries, including the nitrogen industry, requiring the achievement of a certain quality of the air used.

Prior art

Air handling units known from the prior art comprise a metal housing (e.g., aluminum, steel), inside which an air heating unit is located (e.g., by feeding steam inside the heat exchanger pipes), an air filtration unit (may contain 1, 2, 3 or more sections), a cooling unit (e.g., by transferring heat to a less hot medium passing through the heat exchanger pipes, the cooling unit may contain 1, 2, 3 or more sections), pipes and branches/collectors for the discharged medium, a droplet separator and an additional air heating unit (e.g., by feeding steam inside the heat exchanger pipes). The filtration unit may additionally contain service sections intended for servicing the elements included in the installation. The droplet separator may contain several sections, the first may be made in the form of a three-dimensional wire mesh ensuring the merging of moisture droplets on the material of the filter element, and the second section is a labyrinth-type droplet collector (labyrinth demister). The body can be fitted with panels that provide heat retention, for example, made of stone wool with a density of less than 100 kg/ ^m3 .

The devices used are usually used to prepare large volumes of air, and their height usually exceeds several meters. In this case, water flowing from the top of the drip collectors is subject to secondary splash entrainment. In addition, the use of a metal labyrinth demister increases the metal consumption, increases the weight of the product, and complicates the installation and replacement process. Due to several service sections, the dimensions of the unit increase. In addition, metal structures are subject to corrosion.

That is, the disadvantage of known solutions is the low efficiency of air treatment with high metal consumption of the device.

The closest analogue can be chosen to be the patent for utility model RU138119, published on 27.02.2014, which discloses an air treatment apparatus including a supporting metal structure with heat exchange sections containing finned pipes located horizontally, additionally contains a confuser in the form of a truncated pyramid connected to a separator located in the opening of the outlet section of the air duct, installed at an angle of 90° and hermetically connected to each other, wherein the heat exchange section is equipped with a branch pipe and a collector for feeding liquid ammonia into the pipe space and a branch pipe and a collector for the outlet of a vapor-liquid mixture and is inserted into the air duct, above the heat exchange section there is a fence installed on the supporting metal structure, and also contains branches for water drainage located in the lower part of the air duct.

The disadvantage of the known solution is also the low efficiency of air processing with high time costs for process stops and high metal consumption of the device. The presence of at least two 90° air turns that change the direction of the air increases the aerodynamic resistance of the device. In addition, the known solution does not provide sufficient air cooling, which leads to low air drying efficiency and low drip collection efficiency.

Disclosure of a utility model

The objective and technical result of this utility model is to increase the efficiency of the process of reducing the relative humidity of the air with low metal consumption of the device.

To solve the problem and achieve the technical result, an air treatment device is proposed, which has an elongated body in which the following are located in sequence:

air intake zone,

a preheating zone containing means for preheating air,

a filtration zone containing air filtration means,

a cooling zone containing means for cooling air,

a drip collection zone containing a means for collecting drips,

a heating zone containing means for heating air, characterized in that

the drip collection zone contains moisture removal means, including an intermediate moisture removal means and a lower moisture removal means,

wherein the intermediate means for removing moisture is located at a distance H8a from the upper wall of the housing, equal to 0.3-0.7 of the height of the housing H5 in the drip collection zone,

and the lower means for removing moisture is located at a distance H8b from the upper wall of the housing, equal to more than 0.8 of the height of the housing H5 in the drip collection zone,

The sequential arrangement of air intake, preheating, filtration, cooling, drip collection, and heating zones in an elongated housing allows for increased efficiency of the process of reducing relative air humidity with low metal consumption of the device due to the fact that the air sequentially passes through all the stages necessary to reduce the relative air humidity, while there are no sharp bends in the air movement that create aerodynamic resistance and increase the metal consumption of the device.

The presence of moisture removal means in the drip collection zone, including an intermediate moisture removal means and a lower moisture removal means, as well as the placement of these means at the specified distances, makes it possible to increase the efficiency of the process of reducing the relative humidity of the air with a low metal content of the device due to the fact that secondary liquid splash entrainment is reduced (all drops are collected in the intermediate and lower moisture removal means) and there is no need for additional devices that compensate for liquid splash entrainment.

The said zones are equipped with any means known from the state of the art that allow the corresponding function to be implemented. Preferred embodiments of the means are given below.

A moisture drainage device is a structure that allows for the collection and drainage of moisture, such as a structure containing a container connected to pipes, a tray, a collector and/or special metal structures with liquid drainage using pipes.

In a preferred embodiment, the intermediate means for removing moisture is located at a distance H8a from the upper wall of the housing, equal to 0.4-0.6 of the height of the housing H5 in the drip collection zone,

The placement of moisture removal devices at the specified distances allows for an additional increase in the efficiency of the process of reducing the relative humidity of the air with a low metal content of the device due to the fact that secondary splash entrainment is additionally reduced (all drops are collected in the intermediate and lower moisture removal devices) and there is no need for additional devices compensating for splash entrainment.

In a more preferred embodiment, the intermediate moisture removal means is designed to combine the removed moisture flow with the moisture flow collected in the lower moisture removal means.

Combining the discharged moisture flow with the moisture flow collected in the lower moisture removal means allows for an additional increase in the efficiency of the process of reducing the relative humidity of the air with a low metal content of the device due to the fact that secondary splash entrainment is additionally reduced (all drops are collected in the intermediate and lower moisture removal means) and there is no need for additional devices compensating for splash entrainment.

In a more preferred embodiment, the angle of inclination α of the lower wall of the housing between the droplet collection zone and the heating zone towards the droplet collection zone is 1-45°, preferably 5-25°, more preferably 10-20°.

The presence of a slope of the lower wall of the housing between the drip-collection zone and the heating zone towards the drip-collection zone allows for an additional increase in the efficiency of the process of reducing the relative humidity of the air with a low metal content of the device due to the fact that the separated moisture flows down the lower wall of the housing towards the drip-collection zone by gravity, and there is no need for additional devices for capturing moisture. Thus, a partial return of the carried-away drops is ensured and the efficiency of removing moisture from the air is increased.

In a more preferred embodiment, the air filtration means includes a first filter unit and a second filter unit connected to each other,

and the first block is equipped with folding windows containing filters,

Moreover, the hinged windows are designed to provide access through them to the filters of the second block.

The declared device can use one filter, however, the presence of two filter blocks with access to the second block through the hinged windows of the first block allows for an additional increase in the efficiency of the process of reducing the relative humidity of the air with a low metal content of the device due to the fact that two blocks allow for better separation of mechanical impurities and water droplets contained in the air, and the hinged windows allow for a reduction in the dimensions (metal content) of the device by eliminating an additional service area.

In a more preferred embodiment, the air cooling means has a moisture removal means configured to combine the removed moisture flow with the moisture flow removed from the drip collection zone.

Combining the discharged moisture flows allows for an additional increase in the efficiency of the process of reducing the relative humidity of the air with a low metal content of the device due to the fact that secondary splash entrainment of liquid is additionally reduced and there is no need for additional devices to compensate for splash entrainment.

In a more preferred embodiment, the drip collecting means comprises a mesh drip collector.

The mesh drip collector allows for the enlargement of drops and facilitates their flow into moisture removal means, which allows for an additional increase in the efficiency of the process of reducing the relative humidity of the air with a low metal content of the device due to the fact that secondary splash entrainment of liquid is additionally reduced.

In a more preferred embodiment, the means for collecting droplets includes a labyrinth-type droplet collector.

The labyrinth type drip collector, by changing the direction of droplet movement, allows the smallest drops to be collected into larger ones and directed to moisture removal devices, which allows for an additional increase in the efficiency of the process of reducing the relative humidity of the air with low metal consumption of the device due to the fact that secondary splash entrainment of liquid is additionally reduced.

In a more preferred embodiment, the means for collecting drips includes a mesh drip collector and a labyrinth-type drip collector.

A mesh drip collector allows for the enlargement of drops and facilitates their flow into moisture removal means, and a labyrinth-type drip collector, by changing the direction of droplet movement, allows for the smallest drops to be collected into larger ones and directed into moisture removal means, which allows for an additional increase in the efficiency of the process of reducing the relative humidity of the air with low metal consumption of the device due to the fact that secondary splash entrainment of liquid is additionally reduced and there is no need for additional devices that compensate for splash entrainment.

In a more preferred embodiment, the labyrinth-type drip collector comprises plates located at a distance H11 equal to 25-36 mm from each other, and the width of the labyrinth-type drip collector is L11 equal to 115-250 mm.

Placing the plates at the specified distance from each other and making the drip collector of the specified width allows for the efficient collection of the smallest drops into larger ones and directing them to the moisture removal means, which allows for an additional increase in the efficiency of the process of reducing the relative humidity of the air with a low metal content of the device due to the fact that secondary splash entrainment of liquid is additionally reduced and there is no need for additional devices compensating for splash entrainment.

In a more preferred embodiment, the labyrinth type drip collector contains burred plates.

The burr is an element bent away from the main surface of the plate. The use of plates with burrs allows catching drops that can fly out of the drip collector and directing them to moisture removal means, which allows for an additional increase in the efficiency of the process of reducing the relative humidity of the air with low metal consumption of the device due to the fact that secondary splash entrainment of liquid is additionally reduced and there is no need for additional devices that compensate for splash entrainment.

In a more preferred embodiment, the labyrinth type drip collector consists of two modules located one above the other.

The implementation of a labyrinth-type drip collector from two modules located one above the other allows for an additional increase in the efficiency of the process of reducing the relative humidity of the air with low metal consumption of the device.

In a more preferred embodiment, the air heating means includes a section of horizontal finned heat exchange tubes.

The use of a section of horizontal heat exchange finned tubes in the air heating device allows for an additional increase in the efficiency of the process of reducing the relative humidity of the air with a low metal content of the device, due to the fact that the efficiency of air heating increases and the required temperature for reducing the relative humidity of the air is achieved with smaller dimensions of the device.

In a more preferred embodiment, the air heating means includes a section of vertical finned heat exchange tubes.

The use of a section of vertical heat exchange finned tubes in the air heating device allows for an additional increase in the efficiency of the process of reducing the relative humidity of the air with a low metal content of the device, due to the fact that the efficiency of air heating increases and the required temperature for reducing the relative humidity of the air is achieved with smaller dimensions of the device.

In a more preferred embodiment, the air cooling means comprises a section of heat exchange finned tubes with a finning coefficient of 9 to 23.

The use of finned tubes with the specified finning coefficient allows for an additional increase in the efficiency of the process of reducing the relative humidity of the air with a low metal content of the device, due to the fact that the efficiency of air heating increases and the required temperature for reducing the relative humidity of the air is achieved with smaller dimensions of the device.

In a more preferred embodiment, the air heating means comprises a section of heat exchange finned tubes with a finning coefficient of 9 to 23.

The use of finned tubes with the specified finning coefficient allows for an additional increase in the efficiency of the process of reducing the relative humidity of the air with a low metal content of the device, due to the fact that the efficiency of air heating increases and the required temperature for reducing the relative humidity of the air is achieved with smaller dimensions of the device.

In a more preferred embodiment, the air cooling means includes an ammonia evaporator with vertically oriented tubes.

The use of an ammonia evaporator with vertically oriented pipes in an air cooling device allows for an additional increase in the efficiency of the process of reducing the relative humidity of the air with a low metal content of the device, due to the fact that the efficiency of air cooling increases and the required temperature for reducing the relative humidity of the air is achieved with smaller dimensions of the device.

In a more preferred embodiment, the air cooling means includes an ammonia evaporator with horizontally oriented tubes.

The use of an ammonia evaporator with vertically oriented pipes in an air cooling device allows for an additional increase in the efficiency of the process of reducing the relative humidity of the air with a low metal content of the device, due to the fact that the efficiency of air cooling increases and the required temperature for reducing the relative humidity of the air is achieved with smaller dimensions of the device.

In a more preferred embodiment, the air heating means includes a section of heat exchange pipes in which a heat carrier with a temperature above 50°C can be used.

The use of a heat carrier with a temperature above 50°C allows for an additional increase in the efficiency of the process of reducing the relative humidity of the air with a low metal content of the device, due to the fact that the efficiency of air heating increases and the required temperature for reducing the relative humidity of the air is achieved with smaller dimensions of the device.

Brief description of the drawings

The drawings are presented for a better understanding of the utility model, however, it will be obvious to a specialist in this field of technology that the disclosed utility model is not limited to the variant presented in them.

Fig. 1 shows a schematic representation of the claimed apparatus for preparing air with vertical orientation of the cooling pipes.

Fig. 2 shows a schematic representation of the claimed apparatus for preparing air with horizontal orientation of the cooling pipes.

Fig. 3 shows a schematic representation of a frame with filters from the filtration zone.

Fig. 4 shows a schematic representation of the shape of the drip collector plates (shape - zigzag, material - metal).

Fig. 5 shows a schematic representation of the shape of the drip collector plates (shape - wave, material - metal).

Fig. 6 shows a schematic representation of the shape of the drip collector plates (shape - arc with burrs, material - polypropylene).

Variants of implementation of the utility model.

The best option for implementation

The described examples of the implementation of the utility model are given solely for illustrative purposes. It will be obvious to a specialist that other implementation options are possible without changing the essence of the utility model.

Fig. 1 shows a schematic representation of the claimed apparatus for preparing air with a vertical orientation of the cooler pipes, Fig. 2 shows a schematic representation of the claimed apparatus for preparing air with a horizontal orientation of the cooler pipes.

The air preparation device includes an elongated body, inside which there are:

air intake zone 1,

preheating zone 2,

filtration zone 3,

cooling zone 4,

drip collection zone 5,

heating zone 6.

An oblong body means that the length of the body is greater than its width, and it is oriented mostly along its length without sharp bends.

After the heating zone 6 there is an outlet 9 for processed air.

Air intake zone 1 contains an air intake grille.

Preheating zone 2 contains a tubular heat exchanger through the tubes of which heated steam passes.

Filtration zone 3 ensures the separation of mechanical impurities from the air.

Filtration zone 3 contains mesh filter 3a and pocket filter 3b, placed in common frame 33 (see Fig. 3). Pocket filters 3b are placed in their mounting cells and are pressed by folding mounting cells of mesh filter 3a. Pocket filters are installed so that pockets are located vertically.

The filter mounting cells are provided with rubber seals along the perimeter of the plane of contact between the filters and their mounting cells. The planes of contact between the folding mounting cells and pocket filters are also provided with rubber seals. The frame design 33 is designed for a pressure drop of at least 875 Pa. The frame must be fastened to the housing beams from the air inlet side with bolts through a rubber gasket.

Filters have a purification class from G1 to G4.

Cooling zone 4 includes a means for cooling air (heat exchanger) containing a section of heat-exchange finned tubes with a finning coefficient from 9 to 23. The said tubes are part of an ammonia evaporator with vertical or horizontal tube orientation. Each section of the ammonia evaporator in the cooling zone has a separate device for collecting and removing condensed moisture.

Finned tubes are made of carbon or stainless steel, and fins are made of carbon steel, stainless steel or aluminum.

In the embodiment shown in Fig. 1, the cooling zone 4 contains two zones 4a and 4b containing vertically oriented heat exchanger tubes.

In the embodiment shown in Fig. 2, cooling zone 4 contains three zones 4a, 4b, 4c, containing horizontally oriented heat exchanger tubes.

In the lower part of the cooling zone 4 there is a means 7 for removing moisture.

The drip collecting zone 5 contains means 8 for removing moisture, including an intermediate means 8a for removing moisture and a lower means 8b for removing moisture.

The intermediate means 8a for removing moisture is located at a distance H8a from the upper wall of the housing.

The lower means 8b for removing moisture is located at a distance H8b from the upper wall of the housing,

The intermediate means 8a for removing moisture is designed with the possibility of combining the removed moisture flow with the moisture flow collected in the lower means 8b for removing moisture.

The drip collection zone 5 contains a mesh drip collector 5a and a labyrinth-type drip collector 5b, consisting of two modules 5b ₁ and 5b ₂ , located one above the other. The mesh drip collector 5a ensures the enlargement of moisture droplets, and the labyrinth-type drip collector 5b allows changing the air direction for additional enlargement of droplets and their collection in the moisture removal means 8.

The labyrinth-type drip collector 5b may contain drip collector plates 11 in the form of a zigzag (Fig. 4), in the form of a wave (Fig. 5), in the form of arcs with burrs 11a (Fig. 6).

The width of the labyrinth type drip collector 5b is L11, the distance between the plates 11 is H11.

Mesh, blade, honeycomb and fibrous drip collectors made of polypropylene, polyvinyl chloride or other types of plastic can be used.

Heating zone 6 contains a means for heating air, a heat exchanger, through the pipes of which heated steam with a temperature above 50°C passes. The heat exchanger contains a section of horizontal or vertical heat exchange finned pipes with a finning coefficient from 9 to 23.

The height of the housing in the drip collection zone 5 is equal to H5, the height of the housing in the heating zone 6 is equal to H6.

The angle of inclination of the lower wall of the housing between the droplet collection zone 5 and the heating zone 6 is equal to a.

The air preparation device works as follows.

Air is supplied to air intake zone 1, then it is heated in preheating zone 2, cleaned of mechanical impurities in filtration zone 3, cooled in cooling zone 4, droplet moisture is removed in droplet collection zone 5, and heated in heating zone 6, while from the heating zone the moisture separated from the air flows down slope 10 into droplet collection zone 5. After heating zone 6, the treated air enters through outlet 9 for treated air.

The test results of the declared device are presented in the Table below.

Thus, the claimed device ensured an increase in the efficiency of the process of reducing the relative humidity of the air with low metal consumption of the device.

Claims (19)

1. An air treatment device having an elongated body in which an air intake zone, a preheating zone containing means for heating the air, a filtration zone containing means for filtering the air, a cooling zone containing means for cooling the air, a drip collection zone containing means for catching the droplets, a heating zone containing means for heating the air are arranged in series, characterized in that the drip collection zone contains means for removing moisture, including an intermediate means for removing moisture and a lower means for removing moisture, wherein the intermediate means for removing moisture is located at a distance H8a from the upper wall of the body equal to 0.3-0.7 of the height of the body H5 in the drip collection zone, and the lower means for removing moisture is located at a distance H8b from the upper wall of the body equal to more than 0.8 of the height of the body H5 in the drip collection zone. 2. The apparatus according to item 1, characterized in that the intermediate means for removing moisture is located at a distance H8a from the upper wall of the housing, equal to 0.4-0.6 of the height of the housing H5 in the drip collection zone. 3. The apparatus according to item 1, characterized in that the intermediate means for removing moisture is designed with the possibility of combining the removed flow of moisture with the flow of moisture collected in the lower means for removing moisture. 4. The apparatus according to claim 1, characterized in that the angle of inclination α of the lower wall of the housing between the droplet collection zone and the heating zone towards the droplet collection zone is 1-45°, preferably 5-25°, more preferably 10-20°. 5. The apparatus according to claim 1, characterized in that the air filtration means includes a first block with filters and a second block with filters connected to each other, wherein the first block is equipped with hinged windows containing filters, wherein the hinged windows are designed with the possibility of providing access through them to the filters of the second block. 6. The apparatus according to item 1, characterized in that the means for cooling the air has a means for removing moisture, designed with the possibility of combining the removed flow of moisture with the flow of moisture removed from the drip collection zone. 7. The apparatus according to item 1, characterized in that the means for capturing drops includes a mesh drip collector. 8. The apparatus according to item 1, characterized in that the means for capturing droplets includes a labyrinth-type drip collector. 9. The apparatus according to item 1, characterized in that the means for capturing droplets includes a mesh drip collector and a labyrinth-type drip collector. 10. The apparatus according to item 8 or 9, characterized in that the labyrinth-type drip collector contains plates located at a distance H11 equal to 25-36 mm from each other, and the width of the labyrinth-type drip collector is L11 equal to 115-250 mm. 11. The apparatus according to item 8 or 9, characterized in that the labyrinth-type drip collector contains plates with burrs. 12. The apparatus according to item 8 or 9, characterized in that the labyrinth-type drip collector consists of two modules located one above the other. 13. The apparatus according to item 1, characterized in that the means for heating the air includes a section of horizontal finned heat exchange tubes. 14. The apparatus according to item 1, characterized in that the means for heating the air includes a section of vertical finned heat exchange tubes. 15. The apparatus according to item 1, characterized in that the means for cooling the air contains a section of heat-exchange finned tubes with a finning coefficient from 9 to 23. 16. The apparatus according to item 1, characterized in that the means for heating the air contains a section of heat-exchange finned tubes with a finning coefficient from 9 to 23. 17. The apparatus according to item 1, characterized in that the means for cooling the air includes an ammonia evaporator with vertically oriented tubes. 18. The apparatus according to item 1, characterized in that the means for cooling the air includes an ammonia evaporator with horizontally oriented tubes. 19. The apparatus according to paragraph 1, characterized in that the means for heating the air includes a section of heat exchange pipes in which a heat carrier with a temperature above 50 °C can be used.