RU226299U1 - Air handling unit - Google Patents

Abstract

The utility model relates to the field of thermal power engineering, namely to heat exchangers, in particular to the design of complete air treatment units used in the production of mineral fertilizers. The air treatment unit consists of a frame metal structure with heat and mass transfer sections interconnected, while contains a preheating section in the form of a steam heater; section of two-stage filtration of atmospheric air; cooling section, presented in the form of a three-section direct boiling evaporator, tubular coil type with a flat fin. The evaporator sections are connected by refrigerant inlet and outlet manifolds; a section for separating drip moisture, which is a two-stage separator, with the first stage made of a coalescent panel in the form of a three-dimensional wire mesh, and the second stage a labyrinth-type demister; heating section, made in the form of a steam heater, and the frames of the sections are made of specially shaped aluminum profiles, connected to each other by corners, and the side and top walls of the sections are sheathed with heat-insulating panels filled with stone wool with a density of less than 100 kg/m³. The technical problem is to increase the efficiency of air treatment in the production of mineral fertilizers. The technical result is aimed at ensuring the ability to maintain air temperature during the production of mineral fertilizers year-round in a given range - lowering the temperature in summer and increasing in winter, while the quality of air treatment meets the requirements of class G4.

Description

Technical field

The utility model relates to the field of thermal power engineering, namely to heat exchangers, in particular to the design of complete air treatment units used in the production of mineral fertilizers.

State of the art

There are known devices for cooling and heating atmospheric air used in the production of ammonium nitrate developed by GIAP, in particular used in projects of the AS-72 type. However, these developments were never actually used due to low efficiency.

The closest in technical essence and the achieved result is an air-cooling apparatus, including a supporting metal structure with heat exchange sections containing finned pipes located horizontally, characterized in that it 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°, hermetically connected to each other, while the heat exchange section is equipped with a pipe and a manifold for supplying liquid ammonia to the pipe space and a pipe and a manifold for exiting the vapor-liquid mixture and inserted into the air duct; a fence is located on top of the heat exchange section, mounted on a supporting metal structure , and also contains pipes for water drainage located in the lower part of the air duct (RU patent No. 138119, published on April 27, 2014).

The disadvantages of the closest analogue are the impossibility of working in winter, which significantly complicates maintaining the required parameters of both temperature and relative air humidity.

Disclosure of the essence of the utility model

The technical problem is to increase the efficiency of air treatment in the production of mineral fertilizers.

The technical result is aimed at ensuring the ability to maintain air temperature during the production of mineral fertilizers year-round in a given range - lowering the temperature in summer and increasing in winter, while the quality of air treatment meets the requirements of class G4.

The technical result is achieved by the fact that the air treatment unit consists of a frame metal structure with heat and mass transfer sections interconnected, while contains a preheating section in the form of a steam heater; section of two-stage filtration of atmospheric air; cooling section, presented in the form of a three-section direct boiling evaporator, tubular coil type with a flat fin. The evaporator sections are connected by refrigerant inlet and outlet manifolds; a section for separating drip moisture, which is a two-stage separator, with the first stage made of a coalescent panel in the form of a three-dimensional wire mesh, and the second stage a labyrinth-type demister; heating section, made in the form of a steam heater, and the frames of the sections are made of specially shaped aluminum profiles connected to each other by corners, and the side and top walls of the sections are sheathed with heat-insulating panels filled with stone wool with a density of less than 100 kg/m³.

Description of drawings

In fig. 1 shows a general view of the air treatment unit, where:

1. Preheating section.

2. First filtration section.

3. Second filtration section.

4. Air cooling section.

5. Section for separating drip moisture.

6. Additional heating section.

Implementation of a utility model

The air treatment unit (ATU) is used to bring atmospheric air to the required conditions and is located on the suction part of the fans supplying atmospheric air to the process equipment.

Atmospheric air entering the granulation stage of the finished product is processed (in granulation towers or granulation drums, depending on the production technology).

The claimed utility model contains a frame-type body, lined with easily removable heat-insulating panels filled with stone wool with a density of at least 100 kg/ ^m3 and covered with a stainless steel sheet (not shown)

The frame of each section of the BOV is made of specially shaped aluminum profiles connected to each other by corners. Profile material – aluminum alloy AD-31. The panel covering is made of corrosion-resistant steel AISI304. All junctions of the panels and frame are additionally sealed using chemical-resistant sealant.

The air treatment unit has several service sections designed to service the elements included in the installation. Entrance doors include fittings, without the use of plastic elements.

Each technological section is installed on a separate frame made of bent sections made of corrosion-resistant steel AISI304 with a thickness of at least 3.0 mm. All sections are connected to each other using special clamps outside the installation, as well as additional ties inside the frames. This ensures that the blocks fit together as closely as possible and that there are no unwanted air leaks from the outside during operation of the unit.

At the entrance to the air treatment unit, a preheating section 1 (steam heater) is installed to ensure the incoming air temperature is +5°C to prevent the formation of ice on the coarse filter in winter. The heat exchanger, as well as all its fastening elements, are made of corrosion-resistant steel AISI304.

To clean the atmospheric air entering the air treatment unit, a two-section filtration unit is provided. The first section 2 (coarse filter) performs the function of a pre-filter and is equipped with filter elements of purification class G2 in accordance with GOST R EN 779-2014. These filters are made of stainless mesh in several layers. These filters are regenerable and can be cleaned with a cleaning solution when dirty. The second section 3 (fine filter) is a pocket type with replaceable filter elements of cleaning class G4.

Cooling section 4 is presented in the form of a three-section direct boiling evaporator and is intended for the actual cooling of the air and condensation of moisture contained in the atmospheric air.

The evaporator sections are a coil-type heat exchanger with a flat fin, connected via a pump circuit. Cooling of the air in the evaporator occurs due to the transfer of heat to boiling ammonia, supplied to the evaporator from the enterprise networks, as a rule, and returned there or to the technological cycle of fertilizer production, at the neutralization stage.

The temperature of the cooled air at the outlet of the section is +7°C with a relative humidity close to 100%. The evaporator units include trays made of corrosion-resistant steel for collecting and draining condensate.

After the cooling section, the air enters the drip moisture separation section 5.

The drip moisture separation section is a two-stage Meshpad+Tide Van separator made of AISI 304L stainless steel. The first stage of Meshpad is a coalescent panel made in the form of a three-dimensional wire mesh. The second stage of the Tide Van is a labyrinth-type demister. The efficiency of the droplet moisture separation section allows you to separate 99% of droplets no larger than 5 microns in size with a pressure loss of no more than 200 Pa. The drip separation section, as well as the intermediate service section following it, are also equipped with trays for collecting condensate.

Next, the processed air enters the additional heating section 6 (steam heater), to reduce the relative humidity of the air, in other words, to increase the absorption capacity of the air. The air is heated to a temperature of +18°C. In this case, a relative humidity value of no more than 50% is achieved. Heating occurs due to the heat of condensation of saturated water vapor. The heat exchanger, as well as all its fastening elements, are made of corrosion-resistant steel AISI304.

To protect against precipitation, the unit is equipped with a roof of a special design made of corrosion-resistant steel AISI304.

Thus, the claimed utility model provides the ability to maintain specified air conditions during the production of mineral fertilizers year-round in a given range:

1. Maintaining temperature within 18 +/- 1°C;

a) heating of atmospheric air in the winter season from an initial temperature of 45°C to 18°C;

b) reducing air temperature due to cooling (from an initial 35°C to 6°C) in the summer season;

2. Maintaining relative air humidity - no more than 50%. It is provided by heating the cooled air from the initial 6°C to 18°C, while the relative humidity is reduced from the initial 99% to the required values - no more than 50%.

3. Maintaining air quality according to cleanliness, class G4 requirements, is ensured by two-stage filtration.

Claims (5)

1. An air processing unit containing a housing with air cooling and droplet moisture separation sections installed inside it, a two-section filtration unit, as well as a pipe and manifold for supplying liquid ammonia to the pipe space and a pipe and manifold for exiting the vapor-liquid mixture, characterized in that the housing contains heat-insulating panels designed to be dismantled, sections of preliminary and additional heating in the form of steam heaters are additionally installed inside the housing; in addition, the air cooling section is made in the form of a three-section direct boiling evaporator, and the drip moisture separation section is a two-stage separator, with the first stage made of a coalescent panel in the form of a three-dimensional wire mesh, and the second stage a labyrinth-type demister, with these sections being interconnected fixing elements and seal. 2 . An air treatment unit according to claim 1, characterized in that the heat-insulating panels are filled with stone wool with a density of less than 100 kg/m³.