RU52184U1 - DUST ALARM - Google Patents

Abstract

The dust detector relates to measuring technique, and more particularly, to optical devices for continuous measurement of air dust by the degree of scattering of light by dust particles. The utility model can be used in aeronautical engineering, mainly in helicopters, to control the dustiness of air at the inlet to the air intake of a gas turbine engine when the helicopter hangs near the ground. A dust detector containing two emitters and two photodetectors, focusing optics, forming a measuring volume and using light scattering at an angle φ, an electrical signal processing unit, emitters power supply, a switching device for alternately turning on emitters with a frequency f, and in order to increase the accuracy of measuring mass the concentration of polydisperse dust is additionally equipped with at least one more photodetector, the optical axis of which is oriented to the measuring volume and is optically the axis of one of the photodetectors angle α <φ / 2, and the output of the photodetector through an AC amplifier is connected to an electronic signal processing unit, for adjusting the magnitude of the mass concentration readings polydisperse dust.

Description

The utility model relates to measuring equipment, and more particularly, to optical devices for continuous measurement of air dust by the degree of scattering of light by dust particles.

The dust detector can be used in aircraft. mainly by helicopters, to control the dustiness of the air at the entrance to the air intake of a gas turbine engine when the helicopter hangs near the ground. In case of exceeding the established threshold for the concentration of dust raised by the working helicopter screws from the underlying surface of the earth, an alarm device is triggered. It should be noted that the abrasive effect of dust, which reduces the life of the engine, depends both on the physicochemical composition of dust particles, determined by the nature of the underlying surface (loess dust, silica sand, and so on), so on the size of the dust particles.

The scattering indicatrixes of the day of dust particles, the dimensions of which are much larger than the wavelength of the probe radiation, are characterized by strongly pronounced forward scattering and can be calculated in approximation of the laws of geometric optics, as a function of wavelength and particle size (Klimenko A.P. “Methods and devices for measuring concentration dust "M:" Chemistry "1978 p.64-67).

For spherical particles at the same mass concentration of dust, the intensity of the scattered light is inversely proportional to the radius of the particles.

The measurement of the mass concentration M of polydispersed dust by integrated light scattering, as a solution to an incorrectly posed problem, leads to an ambiguous result, and it is referred to as

average dust particle size . The error in measuring the mass concentration of polydisperse dust can reach ± 15% (Klimenko AP “Methods and devices for measuring dust concentration” M: “Chemistry” 1978 p. 68-69).

Known optical device for measuring the concentration of dust in the dust and gas stream entering the device through openings covered with porous plastic (No. US3868184. Publ. 25.02.75. NCI 356/103). The light source and the receiver, the optical axes of which are located at an angle of 120 °, are strengthened in the instrument case. The device has a simulator of dust particles, which is introduced during calibration into the measuring volume (the point of intersection of the optical axes of the light source and the photodetector) with the simultaneous termination of the flow of dust and gas into the device. The intensity of the light scattered by dust is recorded by the photodetector and compared with the intensity of the light scattered by the simulator, the parameters of which are considered unchanged, thereby eliminating the measurement error associated with the instability of the light source and receiver, dusty optics, and the like.

A disadvantage of the known device is that the simulator, made in the form of a comb of thin wire, when covered with a dust-gas mixture, is covered with a layer of dust and changes its light-scattering characteristics. In addition, the porous wall through which the dust and gas mixture flows can change the polydisperse composition of dust. sifting out large particles.

The closest in technical essence to the claimed utility model is a device for measuring the concentration of soot in vehicle exhausts ("... a device for measuring exhaust smoke" by Drozd SN, Kugeiko MM and Figaro V. A., M .: Measuring equipment - 2004. No. 7. S. 56-59). The device has a gas sampler in the form of a pipe coaxially inserted into the exhaust pipe of the car. The diffuser that ends the sampler has a ring with two

in pairs of diametrically opposite openings, behind which two LEDs (or laser diodes) and two photodetectors are mounted so that the light fluxes of the “LED-photodetector” intersect at the center of the ring at an angle φ, forming a measuring volume from which the light scattered from the soot particles enters one of the photodetectors, and the other photodetector at this moment receives direct light flux, attenuated by the amount of light absorbed by the soot. Since the LEDs turn on alternately, the functions of the photodetectors also change alternately.

Thus, it becomes possible to determine the mass concentration of soot with high accuracy by the ratio of the sensing fluxes detected by the photodetectors by eliminating methodological errors related to the contamination of the optics, the instability of LED radiation and the sensitivity of photodetectors, etc.

The disadvantage of this device is that it does not take into account the polydispersity of aerosol particles (soot), and therefore the measurement error associated with it.

The purpose of developing a utility model is to increase the accuracy of measuring the mass concentration M of polydisperse dust.

The goal is achieved by the fact that in a dust detector containing two sources of probing radiation, for example, LEDs and two diametrically oppositely installed around the circumference of the photodetector and focusing optics, the optical axes of the LED-photodetector system intersect at the center of the circle at an angle φ, forming from intersecting light beams measuring volume.

New in the dust detector is that it is additionally equipped with at least one more photodetector located between the photodetectors on an arc of a circle at an angle α <φ / 2 to one of the photodetectors, and its optical axis is oriented to the same measuring volume in the center of the circle, moreover, the output of the photodetector is connected

with an electronic signal processing unit through an AC amplifier.

Figure 1 schematically shows the device of the signaling device. LEDs 1, 2 with focusing lenses are located on the cylindrical body of the device in a plane normal to the axis of the cylinder. In the same plane, on the diametrically opposite side of the cylinder, there are two photodetectors 3, 5 with focusing lenses in such a way that their optical axes coincide with the optical axes of the LEDs and intersect on the cylinder axis at an angle φ. A photodetector 4 with a focusing lens is located on a cylindrical surface between the photodetectors 3 and 5 and is oriented to the same measuring volume. moreover, its optical axis makes an angle a with the optical axis of the photodetector 3. The output of photodetector 4 is connected to the electronic signal processing unit (BOC) 6 through an AC amplifier 7, and photodetectors 3 and 5 are connected directly to the input of the BOC 6. The output of the signal processing unit is connected the recording device 8 of the mass concentration of dust M and a pointer 9 of the percentage of coarse dust in it, as well as a signal device for exceeding the threshold dust content 10. The power supply 12 carries out through the switch 13 Independent user of the LEDs. Blend 11 eliminates unwanted background illumination of photodetectors.

The device operates as follows.

The radiation sent by LED 1 with a power of I _{01 is} recorded by a photodetector 3 in the form of a signal A ₃ I ₀₁ , and photodetectors 4, 5 register radiation scattered at angles α and φ, respectively: A ₄ δ (α) I ₀₁ and A ₅ δ (φ) I ₀₁ (And _i is the hardware constant depending on the sensitivity of the photodetector, aperture of the optics and the like, and δ (α) and δ (φ) are the scattering coefficients at angles α and φ). After a time τ = 1 / f, the voltage is supplied to LED 2 (LED 1 is de-energized) and its radiation is detected by photodetector 5 in the form of signal A ₅ I ₀₂ , and photodetectors 4, 3

the signals A ₄ δ (φ-α) I ₀₂ and A ₃ δ (φ) I ₀₂ are respectively scattered by the measuring volume at angles (φ-α) and φ, respectively. Since the photodetector 4 is connected to an AC amplifier, its signal will be proportional to the difference of the signals A4 {δ (α) I ₀₁ -δ (φ-α) I ₀₂ } and from the output of the AC amplifier will go to the electronic signal processing unit 6, where also the signals A ₃ I ₀₁ and A ₅ δ (φ) I ₀₁ alternately arrive; and A ₅ I ₀₂ and A ₃ δ (φ) I ₀₂ . Neglecting the absorption of radiation on the segments "1-3" and "2-5" at low mass concentrations and determining, when calibrating using known parameters of monodisperse dust, the values of A ₃ , A ₄ , A ₅ and scattering coefficients dδ (α) / dα; dδ (φ) / dφ; dδ (φ-α) / d (φ-α), we obtain at the output of the signal processing unit the mass concentration of polydisperse dust at an average particle size of dust

where ρ is the specific gravity of the particles, and the value of the correction signal is proportional to:

At and I ₀₁ = I _{02 the} last expression is the derivative .

The proportionality coefficient is determined when calibrating the device using mono-dispersed suspensions.

Presenting a suspension of polydisperse dust from the underlying surface in the form of a binary mixture of particles with geometric dimensions and their corresponding mass concentrations of m ₁ and m ₂ (m ₁ + m ₂ = M), where - the dispersion of particle sizes obtained

during successive screening of dust samples through whitefish with hole diameters , we will calibrate the device according to monodisperse suspensions with particle sizes d ₁ and d ₂ and the same mass concentrations M. The obtained values days of particles with sizes d ₁ and d ₂ respectively represent the boundary values of the derivatives, and the choice of d ₁ and d _{2 is} carried out from the conditions: normalization , where f (r) is the particle size distribution function (r = is the radius of the particles), and the boundary f (0) = f (R _max ) = 0. If accept , then we obtain the values of d ₁ and d ₂ . for which condition d ₁ < <d ₂ .

As regards the choice of the angle φ, given that when light is scattered by large particles, the scattering indicatrix has a side maximum already at angles greater than 20 ° -25 °, it is desirable that the angle φ be as small as possible, but at the same time it should be large enough in order to constructively eliminate direct probing radiation from entering the photodetector 4. The optimal angle is φ = 15 ° and angle α = 6 °.

The use of a dust detector provides the following technical and economic advantages:

- the ability to continuously monitor the dustiness of the air entering the air intake of the gas turbine engine (GTE) of the helicopter and take operational measures to reduce dust concentration, thereby increasing the life of the engine;

- the ability to directly assess the nature of the underlying surface from the point of view of its abrasive effect on the GTE blades according to the readings of the device.

Claims (1)

A dust detector containing two emitters and two photodetectors, focusing optics, forming a measuring volume and using light scattering at an angle φ, an electric signal processing unit, emitter power supply, a switching device for alternately switching on emitters with a frequency f, characterized in that, for the purpose of To increase the accuracy of measuring the mass concentration of polydisperse dust, it is additionally equipped with at least one more photodetector, whose optical axis is oriented to the measuring volume and with stavlyaet with the optical axis of one of photodetectors angle α <φ / 2, and the output of the photodetector through an AC amplifier is connected to an electronic signal processing unit.