RU145900U1 - AIR CLEANING DEVICE (OPTIONS) - Google Patents

Abstract

1. The air purification device, characterized in that it contains a final filter, hermetically connected to the pre-filter, on which the dehumidifier is installed, while the pre-filter and the final filter are filters with mini-pleated bags and channels for air inlet and outlet moreover, the design and size of the channels for the exit of air from the pre-filter matches the size and design of the channels for the entry of air into the filter .2. The device according to claim 1, characterized in that the dehumidifier is a cover that is installed on the housing of the pre-filter. 3. The device according to claim 1, characterized in that the filters of classes F6-F9 are used as the filter for final cleaning, and filters of the class G3-F5.4 are used as the preliminary filter. An air purification device, characterized in that it contains a final filter, hermetically connected to the pre-filter, while the pre-filter and the final filter are filters with mini-pleated bags and channels for air inlet and outlet, the design and size of the channels for the air outlet from the pre-filter matches the size and design of the channels for air inlet to the final filter. 5. The device according to claim 4, characterized in that the filters of classes E10-H14 are used as the final filter, and filters of the F6-F9 class are used as the preliminary filter.

Description

The utility model is intended for cleaning air from dust and aerosols and can be used in air-cleaning devices of gas turbine units (GTU), compressor stations, other technological air intake devices, as well as in ventilation and air conditioning systems.

The following devices are known in the art for air purification.

So, from the description of the patent of the Russian Federation No. 2333786 (published on September 20, 2008), a filtering system is known which comprises a design of a filtering medium made of a flexible permeable material having opposite first and second ends and a plurality of corrugations, each of which has a first end part adjacent to the first end of the structure, and the second end part adjacent to the second end of the structure, while some corrugations are open at the first end part and closed at the second end part, and the other corrugations are closed at the first end part and open At the second end part, creating the surface of the flow inlet and the surface of the flow outlet, the gas flow under pressure is supplied to the filter medium through the surface of the flow outlet, and the gas flow is rotated at an angle of less than 80 degrees, introducing the flow into the surface. The filter element contains the first and second structures of the filter medium.

A filter block is also known, which includes two filtering and cleaning elements located in the block body in the form of layers filled with dust filtering material, sorbents, absorbers. The block is made collapsible, consisting of two separate housings, each of which consists of gas-tight side walls, gas-permeable inlet and outlet walls, frontally located in relation to the direction of flow of the cleaned air, of which filter material is placed in the block body in the first body of the air flow in the form of corrugated filter paper. At least two layers are placed in the second block casing, one of which is filled with a sorbent from coal and / or its modifications, and the second layer is filled with an absorber made of potassium permanganate, and / or calcium, and / or barium. Between the absorber, sorbent and gas-permeable walls, cushioning material is placed. The frontal dimensions of the walls of the first housing are larger than the corresponding dimensions of the walls of the second housing. On the side walls of the first casing, protrusions in the form of plates are placed on opposite sides, facing the flow of cleaned air for attaching the first casing to the ecosystem casing and the protrusions are pulled together by a rigid jumper located above the filter material, and a gasket is placed between the casing (patent of the Russian Federation No. 2336929 , published October 27, 2008).

The closest analogue to both versions of the patented solution is a combined filtration system, which includes a finishing filter with mini-pleated bags and an additional housing placed on it for installing 2 preliminary filters: a pocket-type preliminary filter and a dehumidifier, which is made in the form of a flat plate ( patent for utility model of the Russian Federation No. 79802, published on January 20, 2009).

The disadvantages of the known device are the low surface area of the filter surface of the pocket-type pre-filter, which, with the overall dimensions of the housing 595 × 595 × 400 mm, is about 2.5 m ² , and also requires the installation of a pocket-type pre-filter and a production trap and installation on the filter final cleaning of the additional housing.

The use of an additional housing for the pre-filter leads to an increase in the cost of the filtration system, and the low filter surface of the pre-filter leads to its replacement after six months, requiring also a forced shutdown of the gas turbine installation. At the same time, the resource of the finishing filter with mini-pleated bags is at least 1 year, which does not require stopping the gas turbine unit during this year.

The technical result of the patented solution is to increase the resource of the air purification device by increasing the filter surface of the pre-filter, reducing aerodynamic drag, reducing operating costs associated with the purchase and two-time replacement of pre-filters during the year and ensuring the smooth operation of gas turbine units in which the devices are used air purification.

The claimed technical result is achieved due to the design of the air purification device, characterized, according to the first embodiment, in that it contains a final filter, hermetically connected to the pre-filter, on which is installed ("put on") a moisture separator, while the pre-filter and the final filter purifications are filters with mini-pleated bags and channels for entering and exiting the air flow, the design and size of the channels for air leaving the filter before final cleaning coincides with the size and design of the channels for air inlet into the filter of final cleaning.

The dehumidifier is a cover made of foamed polyurethane foam with open pores or other desiccant material.

The claimed technical result is achieved due to the design of the air purification device, characterized, according to the second embodiment, in that it contains a finishing filter sealed to the pre-filter, while the pre-filter and the final filter are filters with mini-pleated bags with channels for the inlet and outlet of the air stream, and the design and size of the channels for the exit of air from the pre-filter matches the size and the design of the channels for entering air into the filter for finishing cleaning.

In the first embodiment, filters of classes F6-F9 can be used as a filter for final cleaning, and filters of class G3-F5 (according to GOST-R-779-EN-2007) can be used as a preliminary filter.

In the second embodiment, filters of class E10-H14 can be used as a filter for final cleaning, and filters of classes F6-F9 as pre-filters.

Next, the solution is illustrated by reference to the figures, which depict the following.

The figure 1 is a General view of the air purification device disassembled (first option);

Figure 2 is a diagram of an air purification device (first option);

Figure 3 is a cross section of an air purification device (first option);

In figure 4 is a General view of the device for air purification disassembled (second option);

Figure 5 is a diagram of an air purification device (second option).

The air purification device comprises a pre-filter 1, a final filter 2 and a moisture separator 3, while the pre-filter 1 and the final filter 2 are filters with mini-pleated bags and channels (Fig. 3) for input 4 and output 5 of the air stream from pre-filter, channels 6 for the entrance of the air flow from the pre-filter into the final filter. The finish filter 2 is hermetically connected to the pre-filter 1, on which the moisture separator 3 is installed. The design and size of the channels 5 for the air outlet from the pre-filter coincides with the dimensions and the design of the channels 4 for the air inlet 2 to the final filter.

In the FIG. 1-3 embodiment of the device for air purification, it is preferable to use a filter of class F6-F9 as a filter for final cleaning 2, and a filter of class G3-F5 (according to GOST-R-779-EN-2007) as a pre-filter.

Finishing filter 2 is installed in an existing opening of the design of an air-cleaning device of a gas turbine installation (not shown). Without additional supporting and supporting elements, close to it (hermetically without a gap), a pre-filter 1 is attached in some known way (for example, by means of a pressure plate).

On the pre-filter 1 is worn and fixed by any known method (for example, using a clamp), the moisture separator 3, in particular, made of foamed open-cell polyurethane foam, made in the form of a cover. The dehumidifier is pressed and additionally held on the pre-filter housing due to the incoming and passing air flow.

At the same time, the dimensions and design of the channels 5 (see Fig. 3) for the air to exit from the pre-filter should be the same as the channels 4 for air to enter the final filter, i.e. channels 6 for air inlet to the finish filter should be a continuation of the channels for air exit from the pre-filter, thereby providing air inlet to the finish filter without additional resistance associated with the aerodynamic resistance of the incoming air flow when separately installed or installed with a clearance of the pre-filter finish filter.

Tests conducted in the laboratory showed a decrease in resistance when using the patented device design by 35-40 Pa or about 40% of the resistance of the pre-filter when installing the finish filter and pre-filter closely compared to their separate installation.

The design of the pre-filter with mini-pleated bags eliminates the need for an additional housing for its placement, and with dimensions smaller (592 × 592 × 292) mm than the considered analogue, the housing size 595 × 595 × 400 mm in the pre-filter is located about 5 m ² filter surfaces.

The specified surface with comparable dimensions can reduce the initial aerodynamic drag. A twofold increase in the filtering surface allows to increase the service life of the pre-filter by more than two times, i.e., at least a year, which becomes comparable with the service life of the finish filter and will allow uninterrupted operation of the gas turbine unit cleaning system during the year.

Placing a moisture trap pre-filter in the form of a “cover” on the filter housing allows you to increase its filter surface by 30% compared to the analog with somewhat smaller overall dimensions in depth (312 mm, and the analog 400 mm) and reduce its aerodynamic drag.

When using the design according to the second embodiment of the air purification device, it is preferable to use filters of class E10 to E14 as final filters. At the same time, filter materials of classes F6 to F9 are used in pre-filters.

With the indicated scheme, according to the existing cleaning practice, the finish filters and pre-filters in the air cleaning devices of gas turbine units are installed separately on separate supporting and installation structures, while the aerodynamic resistance of such an air purification system is equal to the sum of the aerodynamic drags of each of the stages.

The advantage of the proposed air purification system for finishing filters (class E10-E14) and pre-filters (class F6-F9) is a decrease in resistance of 35-40 Pa or about 40% of the resistance of the pre-filter when they are separately installed or installed with a gap .

The total decrease in the resistance of the filters for finishing and preliminary cleaning when installing close to each other (without a gap) is ensured by the fact that the air purified in the preliminary filter, leaving the corresponding channel, immediately enters the channel of the same size in the finishing filter, which eliminates energy loss ( creation of additional aerodynamic drag) associated with the inlet of the air stream running onto the filter for final cleaning.

The economic effect of the proposed technical solution is to reduce the aerodynamic resistance of the air purification system in the air cleaning devices of gas turbine plants. A decrease in resistance by 100 Pa increases the gas turbine power by 0.15%, and the absence of the need to replace pre-filters during the year and the need to stop (to replace the pre-filter) reduces operating costs during the operation of gas turbine units. The absence of a housing for installing a pre-filter reduces the cost of the air purification system compared to its counterpart.

Claims (5)

1. The air purification device, characterized in that it contains a final filter, hermetically connected to the pre-filter, on which the dehumidifier is installed, while the pre-filter and the final filter are filters with mini-pleated bags and channels for air inlet and outlet moreover, the design and size of the channels for the exit of air from the pre-filter matches the size and design of the channels for the entry of air into the filter . 2. The device according to claim 1, characterized in that the dehumidifier is a cover that is installed on the housing of the pre-filter. 3. The device according to claim 1, characterized in that the filters of classes F6-F9 are used as the filter for finishing, and the filters of class G3-F5 are used as the preliminary filter. 4. An air purification device, characterized in that it contains a final filter, tightly connected to the pre-filter, while the pre-filter and the final filter are filters with mini-pleated bags and channels for air inlet and outlet, the design and size channels for the exit of air from the pre-filter matches the size and design of the channels for air inlet to the finish filter. 5. The device according to claim 4, characterized in that the filters of classes E10-H14 are used as the filter for finishing, and filters of the class F6-F9 are used as the preliminary filter.