RU2669428C2 - Cyclic air filtration system circuit in the afcs of the gas-turbine unit (variants) - Google Patents

Abstract

FIELD: machine building.SUBSTANCE: invention relates to machine building and can be used in power engineering, gas, oil and other industries as a filtration system for an air filtering and conditioning system (AFCS) for purifying air supplied to gas turbine and compressor units (GTU) in the amount of 20,000 m/h to 3,000,000 m/h. When using the first version of the circuit of the air filtration system in the cyclic air AFCS in the GTU, located inside the AFCS air duct and containing a block of filters installed along the flow of incoming air into two rows parallel to each other, while the second row of the filter block has a channel in the central area, the outer ends of the first row of the filter block are connected to the inner ends of the second row of the filter unit by means of airtight barriers extending into the channel of the central area, while air passage channels are formed when installing the filtration system in the duct between the walls of the air duct and the outer ends of the first row of the filter block, and the outer ends of the second row of the filter block are connected to the walls of the air duct. When using the second version of the circuit of the air filtration system in the cyclic air AFCS in the GTU, located inside the AFCS air duct and containing a block of filters installed along the flow of incoming air in the form of a wedge, while the widened end of the wedge is connected to the walls of the air duct.EFFECT: technical result of the invention is the production of a compact filtration system with increased incoming air filtration efficiency by placing the filtration system inside the empty space of the air duct and increasing the area of the cleaning surface.2 cl, 8 dwg

Description

The present invention relates to the field of mechanical engineering and can be used in the energy, gas, oil and other industries as a filtration system for a complex air-cleaning device (KVOU) for treating air supplied to gas turbine and compressor units (GTU) in the amount of 20 thousand m ³ / h to 3 million m ³ / h.

The design of the filtration systems used in KVOU is given increased attention, since the reliability of GTU operation and the cost of operating the KVOU depend on the quality cleaning of the incoming atmospheric air, as well as the dimensions of the KVOU.

Typical constructions of KVOU (for example, RF patent No. 866667, 09/10/2009, RF patent No. 2587511, 06/20/2016, RF patent No. 2344302, 01/20/2009) are large-sized metal structures (weight in tens and stony tons ), the basis of which is an air filtration system, as a rule, multi-stage, to ensure the operation of which KVOU can be equipped with weather canopies, drop eliminators, an anti-icing system that ensures the operation of the filtration system during periods of high humidity and atmospheric temperature fluctuations of about 0 ° C (see Fig. 1).

After KVOU, the purified air enters the duct, in which, in the immediate vicinity of the air inlet to the gas turbine, a silencer is located, which reduces the sound pressure level generated by the gas turbine. The cross section of the duct in which the silencer is located corresponds to the maximum optimal speed for the silencers and is in the range from 7 to 10 m / s (see Fig. 2).

The disadvantages of all these typical designs KVOU are large dimensions KVOU and, as a consequence, their high metal consumption. At the same time, the additional metal consumption of the KVOU is caused by the need to manufacture the specified additional air duct, which is a fairly dimensional and empty channel. The metal consumption of this duct is from 70 to 120% of the metal content of the KVOU, which requires the cost of its manufacture.

The solution to this problem is to use the empty space of the duct due to the placement of an air filtration system inside it.

KVOU designs are known (RF patent No. 2550131, 05/10/2015, RF patent No. 2172417, 08/20/2001, Japan patent No. 2016113924, 06/23/2016), according to which the air filtration system is placed inside the duct space.

These solutions allow you to get a compact design KVOU, which reduces the metal consumption KVOU and the cost of its operation.

However, in this case, it is also necessary to use a highly efficient circuit of the air filtration system.

A known filtration scheme (Chinese patent No. 104500229, 04/08/2015) located inside the KVOU duct and having a three-stage air purification system containing a coarse filter, purification filters, a high-efficiency filter, a filter layer between the driven roller and the drive roller for moving it .

The effectiveness of the filtration system is primarily ensured by the area of the cleaning surface through which the contaminated air passes. This design due to the movement of the filter layer allows you to control the degree of contamination and constantly maintain it in a cleaned state. However, the required filtering surface area is provided due to the complex design of the filters in the presence of a drive and rollers, which can lead to jamming of the system, untimely cleaning and malfunctions of the CVOU, which indicates the insufficient efficiency of the considered filtering system.

A known KVOU filtration system scheme (Chinese patent No. 105156213, December 16, 2015), adopted as the closest analogue to the claimed solution according to the KVOU air filtration system scheme, located inside the KVOU duct and containing a multi-stage filter, a coarse filter, sequentially installed, three additional filters, fine filters, while all of these filters are located tightly to each other with the formation of one row, and the height of each of the filters is equal to the height of the duct.

In this case, the filtering surface area is insufficient to ensure complete purification of the incoming air, and the installed filters must have a significant thickness that will allow dust particles to be retained, which increases the dimensions of the filtration system. Also, this scheme requires frequent replacement of filters due to their rapid contamination. Untimely replacement of filters can lead to a decrease in the efficiency of gas turbine engines and a decrease in the reliability of the operation of the HVAC in general.

The technical result of the invention is to obtain a compact filtration system with increased efficiency of cleaning the incoming air by placing the filtration system inside the empty space of the duct and increasing the area of the cleaning surface.

The technical result is achieved by using the first version of the circuit of the air filtration system in KVOU of cyclic air in a gas turbine, located inside the KVOU duct and containing a block of filters installed in the direction of incoming air in two rows parallel to each other, while the second row of the filter block has a channel in the central region, the outer ends of the first row of the filter block through airtight partitions are connected to the inner ends of the second row of the filter block overlooking the channel of the central areas, and when you install a filtration system circuit in the duct between the walls of the duct and the outer ends of the first row of the filter block, channels are formed for the passage of air, and the outer ends of the second row of the filter block are connected to the walls of the duct.

The technical result is also achieved by using the second variant of the air filtration system in the CVO of cyclic air in a gas turbine located inside the CVOU duct and containing a block of filters installed along the incoming air in the form of a wedge, while the expanded end of the wedge is connected to the walls of the air duct.

The filter block of the first and second variants of filtering system circuits can be represented by coarse filters (CSF) and fine filters (PTO) installed together.

The filter block according to the second version of the filtration system circuit can be installed in front of the gas turbine, more specifically in the immediate vicinity of the inlet of the gas turbine.

Parallel arrangement of CSF and PTO filters in two rows, the presence of a channel at the second row of the filter block in the central region, connection through the airtight partitions of the outer ends of the first row of the filter block with the inner ends of the second row of the filter block extending into the channel in the central region, the presence of channels along the walls air ducts allow you to get channels for separation and effective cleaning of the incoming air, namely: part of the air flow passes through the first row of the filter block, then through the channel in the center tral area of the second row block of filters and enters the gas turbine and the second part air stream surrounds the first row and the filter unit is cleaned in the second row of the filter unit. The indicated solution according to the first version of the filtration system scheme allows increasing the filtration area without increasing the dimensions of the living section of the duct (the cross-sectional area of the duct through which the incoming air passes) and, as a result, obtain a compact filtration system with increased cleaning efficiency. Moreover, the placement of the claimed first variant of the filtration system scheme in the KVOU duct allows to significantly reduce its dimensions and metal consumption, which reduces the cost of the KVOU and reduces the area for its placement.

The placement of filters FGO and FTO according to the second option in the form of a wedge in the duct so that the widened end of the wedge is connected to the walls of the duct allows you to get two extended channels for the passage of incoming air located along the walls of the duct, which also allows you to increase the filtration area without increasing the size of the living cross-section of the duct and eventually get a compact filtration system with increased cleaning efficiency. At the same time, all the elements of the air compressor unit are located in the duct in front of the silencer in the immediate vicinity of the inlet of the gas turbine unit, which significantly reduces the metal consumption and dimensions of the air compressor unit, and therefore its cost and saves space for its placement.

In FIG. 1 and FIG. 2 shows the designs of typical CVOs.

In FIG. 3a is a side view of a CVO with the claimed first embodiment of a filtration system diagram; FIG. 3b is a top view of a CVO with the claimed first embodiment of a filtration system diagram; FIG. 3c is a general view of the CVO with the claimed first embodiment of a filtration system scheme.

In FIG. 4a is a side view of a CVO with the claimed second embodiment of a filtration system diagram; FIG. 4b is a plan view of a CVO with the claimed second embodiment of a filtration system diagram; FIG. 4c is a general view of a CVO with the claimed second embodiment of a filtration system scheme.

The typical design of the CVOI (Fig. 1) contains a weather canopy 1, an anti-icing system for heating the air 2, a filter-dehumidifier 3, a coarse filter (CSF) 4, a fine filter (PTO) 5, a confuser 6, a drainage system 7.

From FIG. 1 shows that the filtering system KVOU requires a significant place for the placement of filters CSF and PTO.

The overall dimensions of the KVOU cross section are determined by the performance of the filters FGO 4 and FTO 5 and, as a rule, are proportional to the linear air velocity through the filters 2.5-2.7 m / s, which requires significant dimensions for their placement.

From FIG. Figure 2 shows that the typical KVOU circuit requires the manufacture of an additional duct 8 for transporting the cleaned air to the KVOU to the inlet flange 9 of the gas turbine unit.

As can be seen from FIG. 2, a silencer 10 is installed at the end of the duct 8, the overall dimensions of which correspond to the cross section of the duct and are determined by the optimal speed for the silencer 10 from 7 to 10 m / s.

The metal consumption of this duct is from 70 to 120% of the metal content of the KVOU, which also requires the cost of its manufacture.

According to FIG. 3a, 3b, 3c, the KVOU design contains weather canopies 11, an air duct 12, inside of which there is an anti-icing system 13, a filter-dehumidifier 14, a diagram of the air filtration system according to the first embodiment, comprising a filter unit 15 consisting of coarse filters (CSF) and fine filters, cleaning (PF), which are installed in two parallel rows, and the first row 16 of the filters has channels 17 and 18 for the passage of incoming air along the walls of the duct 12, and the second row 19 of filters has a channel 20 for air passage ha in the central area of the duct 12. The outer ends of the first row 16 of the filter unit 15 are connected with internal vertical ends of the second row 19, 15 of the filter unit 21 by partitions.

According to FIG. 4a, 4b, 4c, the KVOU design contains weather canopies 22, an air duct 23, inside of which there is an anti-icing system 24, a filter-moisture trap 25, a diagram of an air filtration system according to the second embodiment, comprising a filter unit 26, consisting of coarse filters (CSF) and fine filters (PF), which are installed along the incoming air in the form of a wedge 27, while the extended end of the wedge 28 is connected to the walls of the duct 23. The filtering scheme according to the second embodiment can be placed in front of a silencer 29 in the immediate vicinity of the inlet of the gas turbine (not shown).

Air purification in KVOU, which contains the first version of the scheme of the air filtration system, is as follows (Fig. 3A-3B).

When air is taken from the atmosphere, after passing through the weather peaks 11, it enters directly into the air duct 12, where it passes through the de-icing system 13 and the filter-dehumidifier 14 and then enters the filter unit 15 of the inventive filtration system circuit. In this case, one part of the flow of incoming air passes through the first row 16 of the filter block 15 and then moves through the channel 20 located in the central region of the second row 19 of the filter block 15. The second part of the flow of incoming air passes through the channels 17 and 18 in the first row 16 of the filter block 15, due to the presence of airtight partitions 20 connecting the outer ends of the first row 16 of the filter block 15 and the inner ends of the second row 19 of the filter block 15, envelops the first row 16 of the filter block 15 and then passes through the second row 19 of the fil block ters 15. After that, the cleaned air enters the muffler 21 and reaches the gas turbine compressor (not shown).

Air purification in KVOU, which contains the second version of the scheme of the air filtration system, is as follows (Fig. 4A-4B).

When air is taken from the atmosphere, after passing the weather peaks 22, it enters directly into the duct 23, where it passes through the anti-icing system 24 and the filter-moisture trap 25, which is wedge-shaped. The incoming air passes along the walls of the duct 23 and then through the gradually expanding sides of the wedge 27 formed by the filter unit 26. After that, the cleaned air enters the silencer 29 and the inlet of the compressor of the gas turbine (not shown).

An advantage of the invention according to the first embodiment is the compact arrangement of the CSF and PTO filters in parallel in the cross section of the KVOU duct, which allows to increase the filtration area, reduce the overall dimensions and increase the throughput of the KVOU. This, in turn, leads to a reduction in the size of the CVC and a decrease in metal consumption by 20-30%. The application of the invention also allows to increase the velocity of the incoming air in the cross section of the CVO to 4-5 m / s.

The placement according to the second variant of all the elements of the air-conditioning unit inside the duct in front of the muffler, in close proximity to the inlet of the gas turbine unit, allows to reduce the metal consumption of the air-discharge unit by 70-100% and significantly save the cost of its manufacture and placement. The application of the invention allows to increase the air velocity in the cross section of the CVO to a value of 7-10 m / s, corresponding to the optimal speed for the operation of the muffler.

Claims (2)

1. The air filtration system, characterized in that it is arranged to be located inside the air duct of a complex air cleaning device KVOU and contains a filter unit, where the filters are installed in the direction of travel in two rows parallel to each other, each filter consisting of coarse filters and fine filters purification of PTO installed together, the first row of filters has channels for the passage of incoming air along the walls of the duct, and the second row of filters has a channel for passage of air ear in the central area of the duct, and the outer ends of the first row of the filter unit are connected to the inner ends of the second row of vertical filter unit by means of airtight walls. 2. An air filtration system, characterized in that it is arranged to be arranged inside the air duct of a complex air cleaning device KVOU and contains a filter unit consisting of coarse filters and fine filters installed together along the direction of incoming air in the form of a wedge, with an extended end the wedge connects to the walls of the duct.

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