RU82279U1 - PNEUMATIC DEVICE AND CYCLON FILTER FOR IT - Google Patents

Abstract

1. Pneumatic device containing a channel (channels) for supplying air with a strainer, a working unit with a ventilation channel (channels), an output channel (channels) for venting air to an actuator (devices), characterized in that it is additionally in a channel (channels) for supplying air after the mesh filter is installed a cyclone filter (CF), containing an inlet nozzle, a working chamber with a ventilation hole and an outlet nozzle, and the diameter of the inlet nozzle of the CF is 1 ... 4 of the diameter of the nozzle passing through during critical operation air flow equal to the flow rate through the corresponding channel for supplying air to the working unit. ! 2. The pneumatic device according to claim 1, characterized in that the ventilation hole of the filter is connected by a channel to one of the ventilation channels of the working unit. ! 3. The pneumatic device according to claim 2, characterized in that the channel connecting the CF vent to one of the ventilation channels of the working unit is made with a diameter of 1 ... 10 of the diameter of the vent. ! 4. A cyclone filter containing a working chamber, in the upper cylindrical part of which there is an inlet nozzle tangential to the side wall of the working chamber, the outlet nozzle is located along the axis of the cylindrical chamber in its upper part, the lower part of the working chamber is conical, and in the lower part a cone has a ventilation hole, characterized in that the diameter of the CF ventilation hole is 0.025 ... 0.5 of the diameter of the inlet nozzle, and the outlet nozzle is made with a diameter equal to 1 ... 10 of the diameter of the inlet nozzle. ! 5. The cyclone filter according to claim 4, characterized in that the height of the cylindrical part is working

Description

The proposed devices relate to pneumatic automation and can be used in automatic control systems (CAP) of gas turbine engines (GTE).

The closest technical solution (prototype) is an air bypass regulator from an auxiliary power unit compressor (see RF certificate for utility model RF No. 50265, class F04D 27/00, 2005), comprising a housing with two air supply channels to the working unit, including a divider of the absolute pressure value connected to the first air supply channel (with pressure Р _К - full pressure at the inlet to the flowmeter, for example, a Venturi pipe), a jet comparison element, the first inlet nozzle of which is connected to the value divider absolute pressure, and the second inlet nozzle is connected to the second air supply channel (with pressure P _VENT - static pressure in the measured section of the flow meter, for example, Venturi pipes), an amplifier having input channels connected to the output channels of the comparison element, and output channels serving for connection with control channels of the actuator - air bypass valve. A bypass throttle is made in the body of the air bypass regulator from the APU compressor, the inlet of which is connected to the first air supply channel, and the output to the second air supply channel.

The input channels R _K and R _{VENT of the} air bypass regulator from the APU compressor contain strainers for filtering the incoming air.

The disadvantage of the prototype is the susceptibility of the parts of the air bypass regulator from the compressor of the auxiliary power unit to erosion wear, since input filters with a mesh cell of 0.2 × 0.2 mm are usually used there, as a result of which dust particles up to 0.2 mm in size are not delayed by these mesh filters. These dust particles, falling into the internal cavity of the regulator,

pass through the channels of the inkjet elements and as a result of prolonged operation at high temperatures (up to 600 ° C) there is a change in the size and shape of the inkjet elements (erosion wear).

Additionally, it can be noted that this type of strainers cannot be used, for example, to pressurize gasostatic bearings, due to the small size of the working clearances of gasostatic bearings - about 0.05 mm, and a decrease in the mesh size of the mesh filter leads to a significant increase in the weight and dimensions of the device, especially when high temperatures of working air.

The use of only strainers prevents further miniaturization of the nozzles and inkjet elements operating at high temperatures.

The technical result, the achievement of which this utility model is directed, is to eliminate the erosion wear of the parts of the working unit and reduce the likelihood (possibility) of its clogging.

To achieve the specified technical result in a pneumatic device containing a channel (channels) for supplying air with a strainer, a working unit with a ventilation channel (channels), a channel (channels) for venting air to an actuator (devices), in addition, additionally to the channel (channels) ) the air inlet after the strainer is installed cyclone filter (CF).

Distinctive features, namely, the installation of an additional air supply in the channel (s) after the strainer of the cyclone filter containing an inlet nozzle, a working chamber with a ventilation hole and an outlet nozzle, the diameter of the inlet nozzle of the filter being equal to 1 ... 4 the diameter of the nozzle passing through In the critical expiration mode, an air flow rate equal to the flow rate through the corresponding air supply channel to the working unit allows the air entering the pneumatic device to be cleaned of dust and, therefore, to reduce (eliminate) erosion nny wear pneumatic device working unit parts.

The ventilation opening of the cyclone filter may be connected by a channel to one of the ventilation channels of the working unit,

The channel connecting the ventilation hole of the CF with one of the ventilation channels of the working unit, for example, can be made with a diameter of 1 ... 10 of the diameter of the ventilation hole.

The discharge of dust particles into the ventilation ducts is designed to prevent the emission of dust into the atmosphere in unnecessary places and the deposition of dust layers on the outer surface of the pneumatic device.

Known devices are air cleaning systems of tractor engines in which cyclone filters are installed in the air supply channel to prevent wear of components and parts

[cm. Dyakov R.A. Air cleaning in diesel engines. L., "Mechanical Engineering" (Leningrad. Department) 1975. P. 82, table 26, sizes of cyclones].

The closest technical solution (prototype) is a cyclone filter included in the air cleaner of the tractor engine SMD-14. The cyclone filter contains a working chamber with a diameter D, an inlet nozzle (cross section of which is an oval of size h × b), made tangentially in the upper part of the working chamber, and an outlet nozzle D ₂ made on a common axis with the working chamber.

The working chamber is made in the upper part of the cylindrical with a length of H, and in the lower part is conical, of a length of H ₁ , and a ventilation hole D _{1 is} made in the lower part of the cone. The entrance to the output nozzle is located inside the working chamber at a depth of H ₂ .

The disadvantage of this cyclone filter when used in pneumatic devices operating at elevated working air pressures (2 ... 50 ata) is the increased air consumption in the drainage, due to the relatively large diameter of the ventilation hole D ₁ , equal to 0.50 ... 0 , 87 of the inner diameter D of the cyclone filter.

The technical result, the solution of which is claimed by the claimed cyclone filter, is the elimination of erosion wear of parts of pneumatic devices, achieved by efficient cleaning of the incoming air flow from dust with a small air flow into the drainage. The proposed cyclone filter contains a working chamber, in the upper cylindrical part of which there is an inlet nozzle that is tangential to the side wall of the working chamber, the outlet nozzle is located along the axis of the cylindrical chamber in its upper part, and its lower part is conical, and in the lower part of the cone air vent.

Distinctive features, namely, the diameter of the CF ventilation hole, made equal to 0.025 ... 0.5 of the diameter of the inlet nozzle, and the output nozzle - with a diameter equal to 1 ... 10 of the diameter of the inlet nozzle, allow efficient cleaning of the air stream entering the CF from dust at a low air flow rate into the CF vent.

The height of the cylindrical part of the working chamber of the CF can be equal to 1 ... 10 of the diameter of the inlet nozzle.

The diameter of the cylindrical part of the working chamber of the CF can be equal to 4 ... 16 of the diameter of the inlet nozzle.

The entrance to the output nozzle of the CF can be located inside the working chamber, at a distance from the upper part (surface) of the working chamber not less than 0.2 of the diameter of the inlet nozzle.

The upper part (surface) of the working chamber of the CF can be made conical with a blunt cone angle directed inside the working chamber.

The axis of the inlet nozzle CF can be directed tangentially to the surface of the cylinder of the cylindrical part of the working chamber and is located at an angle to the axis of the cylinder (with the direction towards the ventilation hole).

The upper part (surface) of the cylindrical part of the working chamber of the CF can be made along a helical line with a step equal to 1 ± 0.5 of the diameter of the inlet nozzle.

The air supply channels to the inlet nozzle and from the output nozzle of the filter can be equal to 1 ... 10 of the corresponding diameter of the inlet or outlet nozzle.

Tests of the inventive pneumatic device with a cyclone filter with the optimal of the above parameters showed that the cleaning efficiency of the incoming dusty air stream is at least 98% with a minimum air flow into the ventilation hole (the total pressure loss on the CF does not exceed 1%).

The proposed utility model is illustrated by drawings, where Fig. 1 shows a diagram of a pneumatic device with a cyclone filter at the inlet. Figure 2 shows another diagram of a pneumatic device with a cyclone filter, the ventilation opening of which is connected by a channel to one of the ventilation channels of the jet unit. The design of the cyclone filter for air purification is presented in Fig.3.

The pneumatic device (see Figure 1) contains channels 1 and 2 of the air supply (with pressures P _VENT and P _K from the variable differential flow meter, for example, a Venturi pipe or another type that measures the air flow taken from the compressor) to the working unit 3, for example, containing an inkjet block (a comparison element with one or more inkjet amplifiers and / or other elements) with ventilation channels 4, output channels 5 for venting air to the control channels of the actuators. Strainers 6 are installed in front of the working block 3 in the air supply channels 1 and 2. In the air supply channel 2 (with pressure Рквд) after the strainer 6 there is a cyclone filter 7 (CF) containing an inlet nozzle, a working chamber with a ventilation hole and an outlet nozzle moreover, the diameter of the inlet nozzle of the CF is 1 ... 4 of the diameter of the nozzle passing an air flow equal to the flow rate through the corresponding channel for supplying air to the working unit at the critical expiration mode. The entrance to the CF 7 is connected to the air supply channel 2, the exit to the entrance to the working unit 3, and the ventilation hole is in communication with the atmosphere.

The pneumatic device can be made in such a way (see Figure 2) that the ventilation hole of the CF 7 by channel 8 is connected to one of the ventilation channels 4 of the working unit 3, and the channel 8 can be made with a diameter of 1 ... 10 of the diameter of the CF ventilation hole .

The cyclone filter (see Figure 3) will hold the working chamber 9, in the upper cylindrical part of which there is an inlet nozzle 10 made tangentially to the side wall of the working chamber 9, the outlet nozzle 11 is located along the axis of the cylindrical chamber in its upper part, the lower part of the working chamber 9 is made conical, and a ventilation hole 12 is made in the lower part of the cone. The diameter of the ventilation hole 12 is 0.025 ... 0.5 of the diameter of the inlet nozzle 10, and the output nozzle 11 is made with a diameter equal to 1 ... 10 of the diameter of the inlet nozzle 10.

The height of the cylindrical part of the working chamber 9 of the cyclone filter can be equal to 1 ... 10 of the diameter of the inlet nozzle 10.

The diameter of the cylindrical part of the working chamber 9 may be equal to 4 ... 16 of the diameter of the inlet nozzle 10.

The entrance to the output nozzle 11 may be located inside the working chamber 9 at a distance from the upper part (surface) of the working chamber not less than 0.2 diameter of the inlet nozzle 10.

The upper part (surface) of the working chamber 9 can be made conical with a blunt cone angle directed inside the working chamber.

The axis of the inlet nozzle 10 can be directed tangentially to the cylinder surface of the cylindrical part of the working chamber 9 and is located at an angle to the axis of the cylinder (with the direction toward the vent 12).

The upper part (surface) of the cylindrical part of the working chamber 9 can be made along a helical line with a step equal to 1 ± 0.5 of the diameter of the inlet nozzle 10.

The channels for supplying air to the inlet nozzle 10 and the channels for exhausting air from the outlet nozzle 11 may be 1 ... 10 of the corresponding diameter of the inlet nozzle 10 or the outlet nozzle 11.

The inlet nozzle 10 and the outlet nozzle 11 from the outer part can be threaded for ease of connection of the air channels.

The operation of the cyclone filter (see Figure 3) is as follows. Through the inlet nozzle 10, dusty air tangentially enters the cylindrical part of the working chamber 9 of the cyclone filter. When moving around the circumference of the cylindrical part of the working chamber 9, the air flow is twisted, and dust particles are pressed by centrifugal force of the stream against the inner walls of the working chamber 9. The newly entering air stream shifts the particles of dust moving around the circle from the cylindrical part to the conical part of the working chamber 9 of the CF, and, continuing to rotate, they move along the generatrices of the cone to the ventilation hole 12, through which they leave the cyclone filter. The purified air enters the outlet nozzle 11 located on the axis of the CF.

Presented pneumatic device (see Figure 1) works as follows. Air with pressures, for example, P _VENT and P _K passes through the supply channels 1 and 2, through the mesh filters 6 (mesh cell 0.2 × 0.2 mm), where dust is separated more than 0.2 mm, then air with pressure P _K passes through a cyclone filter 7, where dust particles of less than 0.2 mm are separated from the air stream. The separated dust is discharged through the ventilation hole 12 into the atmosphere, and the cleaned air passes into the working unit 3 (jet unit), where an output signal is generated on the comparison element and on the amplifiers, for example, of the jet type and / or other elements, which is supplied through the output channels 5 into control channels of actuators (for example, air bypass valve, pneumatic cylinder, gas-static bearing). As a result, the actuators move in accordance with a given function. Part of the exhaust air is released into the atmosphere through the ventilation channels 4 of the working unit 3.

The operation of the pneumatic device shown in FIG. 2 is characterized in that the dust separated in the cyclone filter 7 does not exit through the ventilation hole into the atmosphere as in FIG. 1, but through channel 8 passes into one of the ventilation channels 4 of the working unit 3. Air outlet from the working block 3 can be performed structurally integrated (centralized).

Thus, the use of this cyclone filter in pneumatic devices makes it possible to remove at least 98% of dust particles from the air with an allowable air flow into the drainage and reduce the erosion wear of parts, ensuring their operation without clogging, as a result of which a significant increase in reliability and an increase in resource can be obtained pneumatic devices.

Claims (11)

1. Pneumatic device containing a channel (channels) for supplying air with a strainer, a working unit with a ventilation channel (channels), an output channel (channels) for venting air to an actuator (devices), characterized in that it is additionally in a channel (channels) for supplying air after the mesh filter is installed a cyclone filter (CF), containing an inlet nozzle, a working chamber with a ventilation hole and an outlet nozzle, and the diameter of the inlet nozzle of the CF is 1 ... 4 of the diameter of the nozzle passing through during critical operation air flow equal to the flow rate through the corresponding channel for supplying air to the working unit. 2. The pneumatic device according to claim 1, characterized in that the ventilation hole of the filter is connected by a channel to one of the ventilation channels of the working unit. 3. The pneumatic device according to claim 2, characterized in that the channel connecting the CF vent to one of the ventilation channels of the working unit is made with a diameter of 1 ... 10 of the diameter of the vent. 4. A cyclone filter containing a working chamber, in the upper cylindrical part of which there is an inlet nozzle tangential to the side wall of the working chamber, the outlet nozzle is located along the axis of the cylindrical chamber in its upper part, the lower part of the working chamber is conical, and in the lower part a cone has a ventilation hole, characterized in that the diameter of the CF ventilation hole is 0.025 ... 0.5 of the diameter of the inlet nozzle, and the outlet nozzle is made with a diameter equal to 1 ... 10 of the diameter of the inlet nozzle. 5. The cyclone filter according to claim 4, characterized in that the height of the cylindrical part of the working chamber is 1 ... 10 of the diameter of the inlet nozzle. 6. The cyclone filter according to claim 4, characterized in that the diameter of the cylindrical part of the working chamber is 4 ... 16 of the diameter of the inlet nozzle. 7. The cyclone filter according to claim 4, characterized in that the entrance to the output nozzle is located inside the working chamber at a distance from the upper part (surface) of the working chamber of at least 0.2 of the diameter of the inlet nozzle. 8. The cyclone filter according to claim 4, characterized in that the upper part (surface) of the working chamber is conical with a blunt cone angle directed inside the working chamber. 9. The cyclone filter according to claim 4, characterized in that the axis of the inlet nozzle is directed tangentially to the surface of the cylinder of the cylindrical part of the working chamber and is located at an angle to the axis of the cylinder (with the direction toward the vent). 10. The cyclone filter according to claim 4, characterized in that the upper part (surface) of the cylindrical part of the working chamber is made along a helical line with a step equal to 1 ± 0.5 of the diameter of the inlet nozzle. 11. The cyclone filter according to claim 4, characterized in that the air supply channels to the inlet nozzle and from the outlet nozzle are 1 ... 10 of the corresponding diameter of the inlet or outlet nozzle.