RU160748U1 - SMOK ALARM - Google Patents

Abstract

Smoke detector using backscattering of light by smoke particles, containing a modulated monochromatic light source - a semiconductor laser, a photodetector consisting of a single-lens and several radiation detectors onto which astigmatic images of smoky sections of the laser beam are projected, the optical axis of the lens intersecting the laser beam underneath acute angle α (α≤3 °), the vernier mechanism controlling the angular position of the laser and kinematically connected with the longitudinal by moving the lens along its optical axis, the electronic unit for processing and selecting signals from radiation receivers arriving at its input, and the unit outputs are connected to a smoke alarm system, while all the detector design elements are located in a single housing, characterized in that they additionally install the radiation receiver on the optical axis of the lens, which focuses the image of the spot of the laser beam on the opposite wall of the compartment when combining with it the point of intersection of the laser beam and the optical axis of the object the lens, as evidenced by the maximum value of the output signal of the radiation receiver, while two polaroids are located on the optical axis of the lens in front of the radiation receiver, the plane of polarization of which is set at a certain angle to each other depending on the reflectivity of the opposite wall of the compartment to allow photosensitive irradiation the surface of the radiation receiver on a linear portion of its energy characteristic, regardless of the wall reflection coefficient compartment

Description

The utility model relates to devices for monitoring the state of optically transparent gas environments for smoke and can be used in fire detection systems in enclosed spaces, for example, baggage-cargo compartments of aircraft (aircraft) or ship holds for detecting smoke in the early stages of a fire.

Known "point" smoke detectors operating on the principle of light scattering by smoke particles falling inside the detector. Their application requires an extensive approach to solving the problem: the larger the room, the greater the number of signaling devices you need to use (ed. Certificate of the USSR No. 1264220 A1 G08B 17/10)

There are known “linear” control systems for an extended zone, alarm systems operating on the principle of measuring the transparency of a smoky gas environment, which can significantly reduce their number for monitoring the same area of a room as compared to “point” sensors, but they require laborious work to adjust the equipment when installing a photodetector or reflective reflector on the opposite wall of the room (patent US 2004/0155786 A1 G08B 17/10, patent RU 89739 U1 G08B 17/10)

The well-known "System for monitoring changes in the state of the atmosphere in the room" (patent RU 49320 U1, 2005 G08B 17/10), which uses light scattering from smoke particles, since the light sources are gas lasers are located on the same wall, and the group of photodetectors on the side wall rooms, while the photodetectors are oriented at an angle of 90 ° relative to the laser beams, which reduces the background signal from the opposite wall of the compartment and increases the sensitivity of the equipment.

However, this system has the same drawbacks associated with the installation and configuration of a large number of photodetectors on the side wall of the compartment.

A known sensor for measuring the concentration of smoke (dust) in an exhaust pipe (patent CN 102854109 A 2012), containing a laser as a light source, whose beam through a side hole in the pipe is directed at a certain angle into the pipe and "rests" against the opposite wall of the pipe outside the field of view of a photodetector consisting of a lens and a radiation receiver mounted in the vicinity of its focus.

Laser light scattered by smoke particles in a portion of a laser beam limited by the angle of view of the lens creates a signal on the photodetector proportional to the average concentration of smoke in the pipe. However, the sensor does not provide information about the specific distribution of smoke particles over the cross section of the chimney and cannot be used to detect smoke accumulation along the laser beam, for example, as a smoke detector for detecting smoke at an early stage of a fire.

This flaw is eliminated by a smoke detector (patent RU 138993 U1 G08B 17/10) using backscattering of smoke particles containing a modulated monochromatic light source - a semiconductor laser, a photodetector consisting of a single-lens and several radiation detectors onto which astigmatic images of smoky areas are projected the laser beam, and the signals from the radiation receivers are fed to the input of an electronic signal processing and selection unit, the outputs of which are connected to the smoke exhaust system scheniya. The optical axis of the lens intersects with the laser beam at an acute angle α (α≤3 °). The vernier mechanism controls the angular position of the laser and is kinematically connected with the lens barrel by moving the latter along the optical axis by an amount corresponding to a change in the angle α. All design elements of the detector are placed in a single housing.

The appearance of a signal at one of the photodetectors, exceeding a predetermined threshold level, indicates the appearance of smoke in a certain location of the compartment, which caused the smoke of a portion of the laser beam.

However, placing the detector in the cargo compartment requires accurate knowledge of the dimensions of the compartment or the distance from the detector to the opposite wall of the compartment in order to establish the corresponding angular position of the laser on the scale of the vernier mechanism. Distance measurement can be difficult if the compartment is loaded, and the detector should be placed at a height exceeding the height of the stored cargo.

The technical result, which is achieved by the claimed utility model, is to expand the possibility of using the detector in the baggage and cargo compartment of the aircraft in the absence of a priori information about its size and placing it in any convenient place for work.

Essential features.

To achieve this technical result, a smoke detector using backscattered light by smoke particles containing a modulated monochromatic light source - a semiconductor laser, a photodetector consisting of a single-lens and several radiation detectors onto which astigmatic images of smoky sections of the laser beam are projected, the optical axis the lens intersects the laser beam at an acute angle α (α≤3 °), the vernier mechanism controlling the angular position m of the laser and kinematically connected with the longitudinal movement of the lens along its optical axis, an electronic unit for processing and selecting signals from radiation receivers arriving at its input, and the unit outputs are connected to a smoke detection system, while all the design elements of the detector are located in a single housing, an additional receiver is placed radiation on the optical axis of the lens, on which the image of the spot of the laser beam is focused on the opposite wall of the compartment, when the point of suppression of the laser taking into account the optical axis of the lens, as evidenced by the maximum value of the output signal of the radiation receiver. Since there is no astigmatism for a beam of rays emanating from a point lying on the optical axis of the lens, and the caustic, as a result of spherical aberration of the lens, is symmetrical about the optical axis, it does not affect the maximum output signal (“Handbook of the designer of optical-mechanical devices” second Edition, publishing house "Engineering", Leningrad, 1967, p. 146, 152).

In addition, for a clear observation of the maximum output signal, it is necessary that the irradiation intensity of the radiation receiver is maintained on a linear portion of its energy characteristic, regardless of the reflection coefficient of the compartment wall.

This is accomplished by using a light-attenuating polarization system of two polaroids located on the optical axis of the lens in front of an additional radiation receiver. Polarization planes of polyroids are set at a certain angle to each other, depending on the reflectivity of the opposite wall of the compartment. The transmission of light by such a system according to the law of Malus is expressed by the dependence I = I ₀ cos ² φ (A. A. Shishlovsky “Applied Physical Optics” Fizmatgiz Moscow, 1961, p. 330)

In our case, taking into account the transparency of the polaroids and the reflection coefficient of the compartment wall, we can write I = kRI ₀ cos ² φ, where

I is the intensity of light transmitted through the polaroids;

k is the total transmission of polaroids at φ = 0 °;

R is the reflection coefficient of the compartment wall (0 <R <1);

I ₀ is the light intensity in the laser beam;

φ is the angle of intersection of the polarization planes of the polaroids.

If the condition Rcos2φ = const is satisfied, then for any R we can choose the angle φ at which I≈const.

The use of polaroids is justified by the fact that the photodetector of the detector works at large aperture angles.

Thus, the installation in the photodetector of an additional radiation receiver located on the optical axis of the lens allows it to be used as a photoelectric range finder in compartments of any size (the restriction is only related to the power of the laser used) and placed in any convenient place for work.

The figure 1 shows the optical diagram of the smoke detector when it is installed in the cargo compartment of the aircraft.

The smoke detector (1) contains a modulated monochromatic light source - a semiconductor laser (2) and a photodetector consisting of a single-lens (4), an optical axis (3), which intersects with the laser beam (5) at an acute angle α≤3 ° at to the opposite wall of the compartment (13), radiation receivers (6 ÷ 9), onto which astigmatic images of smoky sections of the laser beam (5) are projected, coupled to radiation receivers (lines 3.1 ÷ 3.4), the outputs of the radiation receivers (6 ÷ 9) are connected to the inputs electronic processing unit and signal selection (10), and its outputs are connected to a smoke detection system; an additional radiation receiver (11) located on the optical axis of the lens, a vernier mechanism (12) kinematically associated with the angular position of the semiconductor laser (2) and the lens barrel (4), combining the point of intersection of the laser beam (5) and the optical axis (3) lens (4) with the wall surface of the compartment (13) and at the same time moving the lens (4) along its optical axis (3), and ensures accurate focusing of the laser spot on the photosensitive surface of the radiation receiver (11) by the maximum output signal on power meter (15); two polaroids (14) located on the optical axis (3) of the lens (4) in front of the radiation receiver (11), the plane of polarization of which is set at a certain angle to each other, depending on the reflectivity of the opposite wall (13) of the compartment.

Description of the operation of the claimed device.

In the manufacture of the detector, its adjustment to the maximum compartment size is carried out, based on the power of the laser used. On the scale of the vernier mechanism, graduated in meters, the angular position of the laser is established, which corresponds to the alignment of the point of intersection of the laser beam and the optical axis of the lens with the wall of the compartment, for this changing the angular position of the laser and, according to the readings of the output signal of the electrical measuring device (15), bring the laser beam closer to the point the intersection of the optical axis with the surface of the compartment. Then, the angle between the polarization planes of the polaroids is adjusted until the peak dependence of the output signal of the receiver (11) on the angle of intersection of the polarization planes φ is detected.

With this position of the polaroids, the illumination of the sensitive surface of the radiation receiver (11) is located on its linear portion of the energy characteristic. When a particular section of the laser beam is smoked by smoke appearing in the compartment at the corresponding radiation receiver, paired with this section, a signal will appear and, if its value exceeds a predetermined threshold level, the smoke alarm system will turn on an alarm.

Claims (1)

Smoke detector using backscattering of light by smoke particles, containing a modulated monochromatic light source - a semiconductor laser, a photodetector consisting of a single-lens and several radiation detectors onto which astigmatic images of smoky sections of the laser beam are projected, the optical axis of the lens intersecting the laser beam underneath acute angle α (α≤3 °), the vernier mechanism controlling the angular position of the laser and kinematically connected with the longitudinal by moving the lens along its optical axis, the electronic unit for processing and selecting signals from radiation receivers arriving at its input, and the unit outputs are connected to a smoke alarm system, while all the detector design elements are located in a single housing, characterized in that they additionally install the radiation receiver on the optical axis of the lens, which focuses the image of the spot of the laser beam on the opposite wall of the compartment when combining with it the point of intersection of the laser beam and the optical axis of the object the lens, as evidenced by the maximum value of the output signal of the radiation receiver, while two polaroids are located on the optical axis of the lens in front of the radiation receiver, the plane of polarization of which is set at a certain angle to each other depending on the reflectivity of the opposite wall of the compartment to allow photosensitive irradiation the surface of the radiation receiver on a linear portion of its energy characteristic, regardless of the wall reflection coefficient compartment for clear observation of the maximum output signal.

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