SU1154582A1 - Apparatus for sampling aerosol - Google Patents

Abstract

1. DEVICE FOR THE SELECTION OF AEROSOL SAMPLES, containing an intake conical tip, an aerosol suction device, an actuator for changing the O110 of the inlet nozzle inlet section, an aerosol flow velocity sensor and a tracking system that couples the sensor to the actuator, so that, in order to increase the efficiency of monitoring the content of suspended particles in the air by providing isokinetic selection in any aerosol velocity range, the intake tip is made of the elastic plate, and an actuator device is provided for reciprocating movement of the intake nozzle. 2. The device according to claim 1, wherein the actuator for changing the area of the inlet section of the intake tip is made in the form of coaxial directions ф ф г, т g, attached by KOHuaNei alone to the intake tip, and in other ways for returning -available movement of the tip, equipped with a reversible servo motor, connected to the flow velocity sensor through the tracking system, and the device for reciprocating movement of the tip is completed in the form of a cam transmission or transmission Int-nut and is connected to the servomotor. 3. The device according to n.f, which is based on the fact that the device for the suction of aerosol is made in the form of a fan with an air flow regulator. 4. Device on PP. 1 and 3, which is different in that the control valve 4 SP 00 b9 l torus of air flow is made in the form of a washer installed in the inlet channel of the fan, in the opening of which there is a sub-quinine cone installed at the top of the fan.

Description

t 1 The invention relates to a sampling technique by sucking gas containing suspended particles and can be used to monitor the state of the air, as well as in industrial installations to control the amount of dust. A device for determining the content of dust in air is known, comprising a housing with an intake tip in the form of a horizontal cylindrical tube attached to a wind vane that establishes it against the wind, a filter, an electrically driven fan, an air flow meter, a flow regulator, a sensor wind speed, convergence of the L1J electric drive. A disadvantage of the device is the inability to ensure isokineticity at high petri speeds. A device for sampling aerosols is known, it contains an intake conic tip, an aerosol suction device (aspirator), an actuator for changing the area of the inlet nozzle, an aerosol flow velocity sensor, and a tracking system 2. The disadvantage of the device is insufficient monitoring of suspended particles in the air, as well as the provision of isokinetic sampling in any range of wind speeds. The purpose of the invention is to increase the efficiency of controlling the content of suspended particles in the air by providing isokinetic selection in any aerosol velocity range. This goal is achieved by the fact that in an aerosol sampling device containing a cone intake, an aerosol suction device, an operating mechanism for changing the inlet nozzle inlet area, an aerosol flow velocity sensor, and a tracking system, the connecting sensor with the actuator The fur of the bottom, the intake tip is made of an elastic plate, and the execution plate. the mechanism is equipped with a device for reciprocating the displacement of the intake tip. The actuator is designed as coaxial guides, g, attached at one end to the intake tip, and others at the device for reciprocating movement of the tip, equipped with a reversible servo motor connected to the flow velocity sensor through the following system, and the device for reciprocating movement of the tip is made in the form of a cam transmission and a screw-nut transmission and is connected with a servomotor. The device for suction of aerosol is made in the form of a washer installed in the inlet channel of the ventilator, in the opening of which there is a p-shaped cone, installed with its tip towards the ventilator. Figure 1 shows the device, a general view, - Fig. 2 is a diagram of the device; in fig. 3 - a conical tip. The device comprises a body 1, part 2 of which is rotatable around a vertical axis and is provided with a conical split inlet tip 3 made of an elastic flexible plate rolled up in the form of a truncated cone. The pivot part 2 has a removable cover 4. At the pivot part 2 on the crown mattes 3 a wind direction sensor 6 is installed in the form of a wind vane and a wind speed sensor 7 (impeller). In case 1, a fan 8 with an electric drive 9 is located. In the inlet pipe 10, an automatic flow regulator is installed in the form of a washer 11, in the opening of which a spring-loaded cone 12 is located, which is directed downstream by the fan (to the fan 8). Holes 13 are made in the lower part of the body. The air is released. The housing 1 is fixed on the telescopic mast 14. The rotary part 2 carries an outer conical guide 15, which covers the intake tip 3, and coaxially to them inside the tip 3 there is an annular on. Kitz b in the form of a tube. To the base of the tip 3 are attached the gates 17, which by means of the transfer screw-nut 18 and the worm gear 19 are connected to the reversible servo motor 20, which serves for reciprocating movement of the ferrule 3 in the guides 15 and 16. The servo motor 20 is connected to the output trace system 21, to the input of which is connected the electrical output of the sensor 7 of the wind speed - Krishchatka. On the axis of the impeller 7, a cam can be strengthened, for 1 contact at each revolution, or an electric generator, so small as to allow the impeller 7 to rotate it at a speed of 0.5 m / s. Amplifier is provided for amplifying the sensor signal in the tracking system 21. The following system 21 is made in the form of a bridge circuit, and the circuit of which includes a servomotor 20. At the exit of the tip 3, a suspended particle separator is installed in the form of a ring filter 22, which is fixed on the grid 23, and this grid covers the rollers to 24 and 25. The driving roller 25 is mounted in the center of rotation of the rotary part 2 and connected by a worm 26 and a gear 2 gears with a shaft of a servomotor 28 which is mounted on a fixed housing 1. Concentric with a roller 25 a gear 29 is installed, which is connected to a shaft with a worm xcm 30 reverse servo motor 28. The gear 29 is bonded to the turning part 2 and can turn the latter. Transmissions 26 and 27 are designed so that with one full rotation of part 2, the ring filter 22 extends completely before the exit of the tip 3, for its entire length. The grid 23 is adjacent to the inlet of the swiveling nozzle 30, the exit of which is connected to the inlet pipe 10. The nozzle 30 is fastened to the turning part 2 and always follows the tip 3. A lever 31 is located on the vertical shaft of the wind vane 6 and is located along the contacts 32 and 33 spaced in horizontal plane at a given angular distance to me, and a 1/4 part of a circle. Contacts 32 and 33, as well as lever 31, are connected to the input of the following 24 system 34, which is connected to a reversing servo motor 28, which this tracking system can use to start up to one side or another depending on which of the contacts ( 33 or 34) closes the lever 31, rotating together in the fly-gun 6. In the inlet pipe 10, a meter 35 of intake air volume is installed, which is a screwed-on impeller with its rev counter, according to the number of which the vessel is about the volume stretched by the fan 8 of air. For powering the units described, the instrument is supplied with a DC source 36 in the form of a battery or rectifier connected to an AC network. The current source is located in the container at the base of the telescopic mast 14, input 37 is provided in the housing 1 to connect it to the device. The device operates as follows. The telescopic mast with the device is installed in the place where air samples containing suspended particles need to be taken. To install the ring filter 22 on the grid 23, open the cap 4, the Ring filter 22 has labels, corresponding to the BeTCTBjnoupie directions to the north, south, east and west and to the intermediate directions. This filter is fixed on the grid 23 so that opposite to the tip 3 there is a section of the filter corresponding to the current direction of the tip 3 (for example, the north-west one). After that, the lid is closed, the device is raised on a telescopic rod to a predetermined height, and the device is powered up ... Fan 8 begins to suck air through tip 3 with a predetermined constant flow rate, which is maintained automatically by both the speed of the fan, driven by the electric motor, and the air flow regulator. With an increase in air flow above a predetermined value, the spring-loaded cone 12 removes the increased flow pressure and is pressed into the washer 11,

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reducing the gap, and with it the expense. If the air flow rate decreases, the cone 12 experiences a lower flow pressure and the spring lifts it, thereby increasing the gap between the washer and the cone, which leads to an increase in the flow. The adjusting screw sets the initial position of the cone in relation to the washer 11 and sets the air flow rate that the fan draws through the device. And this one, the expense is then supported automatically,

If there is no wind, then the injected device pulls air through filter 22, and the inlet of tip 3 will be at the annular cut directed 15x16 and will have the largest cross-sectional area, for example, 20 cm. If the constant discharge air flow rate is equal to 1 l / s, the air velocity at the inlet of the pinner will be 0.5 m / s. At such a speed, non-compliance with isokineticity (calm) will cause a small quite stable solution in determining the content of suspended particles, since with calm air small particles are contained in the air, while large ones fall out.

In the absence of power, the fly-gun 6 is fixed and the lever 31 does not touch the PC of one of the contacts 32 and 33.

When the wind rises, the direction of which does not coincide with the direction of the wind vane, the latter turns under the influence of the wind and the lever 3t locks one of the contacts 32 or 33 depending on the direction of the wind.

The closure of one of the aforementioned contacts leads to the appearance of a signal in which the tracking system 34 starts the servomotor 28 in such a direction that the rotation of the rotary part 2 leads to the withdrawal of the closed contact (32 or 33) from the lever 3t, then the servomotor 28 de-energizes and rotation of the rotational part 2 is stopped. In this case, tip 3 turns against the wind ..

In the described rotation of the turning part 2, the servomotor 28 also rotates the roller 25 by means of the gear 27, which leads to pulling the filter 22 before exiting the tip

3 by an amount corresponding to the amount of rotation of the tip 3. Thus, the suspended particles are separated into parts of filter 22 corresponding to the determined wind directions.

The occurrence of wind not only causes the rotation of the wind vane and the turning part 2, but also causes the impeller 7 to rotate, which is a wind speed sensor with an electrical output signal. This signal enters the tracking system 21, which starts the servomotor 20, the latter with the help of gears 19 and 18 and 17 and pushes the tip 3 along its longitudinal axis. From the guides 15 and 16. At the same time, the input section of the tip 3 is smaller. And since the flow rate of intake air at the same time remains unchanged, a decrease in the area of the inlet section of the tip is accompanied by a corresponding increase in air velocity in this section. It should be noted that this increase in air speed at the inlet of the handpiece does not need to be spent on the additional energy of the fan due to the fact that the intake air already has the necessary velocity, which is the increased wind speed. At the same time, due to the invariance of the flow of suction air, the resistance of the path from the tip to the fan also remains the same, since the speed of the air in this path remains unchanged.

In order to maintain isokineticity at the tip inlet, it is required that when the wind speed changes by some amount, the same value will change (and with the same sign) the air speed at the tip entrance. In order to achieve this, one should calibrate to find the relationship between the signal value of the wind speed sensor 7 and the wind speed in a given range of its speeds. After that, according to this dependence, gears 19 and 18 should be selected from servomotor 20 to tip 3. If mentioned is a function of the sensor signal wind speed and wind speed is expressed by a straight line, it is possible to use a worm gear, and in the case of a more complicated relationship, use a cam gear. If the area of the input section (m The smaller base of the conical tip 3) in the absence of wind is 20 cm, then in the case of a strong wind the flexible elastic plate forming the conical tip 3, the servomotor pulls out of the guides 4 and 16 and its inlet opening can be reduced to 0.1 cm. will be obtained if the plate is made of a sufficiently thin elastic material, such as Teflon or Beryllium bronze, 0.1-0.2 mm thick. When reducing the inlet section of the tip to 0.1 cm and the received intake air flow is 1 l / s speed in Air in such an inlet section will be 100 m / s. Tie. will reach such a speed, which is extremely rarely seen even in the strongest tropical hurricanes. As the wind speed increases, the servomotor 20 will, according to signals from wind speed sensor 7, move tip 3 out of the guides and thus reduce the inlet section of the tip to the extent that the intake air the inlet of the tip will always correspond to the wind speed, i.e. the isokinetics will be observed. As the wind speed decreases, the servomotor 20 will retract the tip into the guides, increasing the 11 or 8 tip inlet of the tip in accordance with the requirement of the intake of the air intake. In this case, the device will provide the mentioned isokineticity in the whole range of wind speeds encountered in nature. The proposed device can be used not only in the form of the proposed stationary installation, but also on aircraft (in helicopters, for example). In this case, the speed sensor can be implemented not in the form of an impeller, but using a speed sensor used in aviation, built on the principle of the Pitot tube. A wind sensor will not be needed. And the filter will not be drawn at the command of the wind direction sensor, but at the command of the clock mechanism. Thus, the proposed device allows to take samples of gas containing suspended particles, automatically providing a low kinetics at the tip inlet at a greater range of speeds, when it is necessary to take samples under conditions of frequent and significant fluctuations in the velocity of the gas. This makes it possible to increase the efficiency of monitoring the content of suspended particles in a gas, which is important in controlling air pollution, in geological exploration, and also in monitoring various technological processes.

Claims (4)

1. AEROSOL SAMPLING DEVICE, comprising a conical intake tip, an aerosol suction device, an actuator for changing the intake cross-sectional area of the intake tip, an aerosol flow rate sensor and a tracking system connecting the sensor to the actuator, In order to increase the efficiency of monitoring the content of suspended particles in the air by ensuring isokinetic selection in any range of aerosol velocities, the intake tip is made of another plate, and the actuator is equipped with a device for reciprocating movement of the intake tip. 2. The device according to claim 1, wherein the actuator for changing the input section area of the intake tip is made in the form of coaxial guides, rods attached at one end to the intake tip, and the other to a device for reciprocating movement the tip, equipped with a reversible servo motor connected to the flow rate sensor through the servo system, and the device for reciprocating movement of the tip is made in the form of a cam gear or wine transfer and the nut is connected with the servomotor. 3. The device according to claim 1, characterized in that the device for suctioning the aerosol is made in the form of a fan with an air flow regulator. 4. The device according to paragraphs. 1 and 3, characterized in that the air flow regulator is made in the form of a washer installed in the inlet channel of the fan, in the opening of which is located a tapering cone installed by the apex to the fan. sd • fe »SP □ About i