RU109599U1 - FIRST OPTICAL ELECTRONIC FIRE DETECTOR - Google Patents

Abstract

 1. Optical-smoke optical smoke detector comprising a detachable case, on the inside of the base of which there is a printed circuit board with an electronic circuit, a microcontroller and an optical camera containing a light emitting module with light emitters emitting at different wavelengths, and a light detector module, optically isolated from each other each other with a central hood, characterized in that the light emitters are arranged vertically one above the other in the holes of the holder of the light emitting module so that their optical axes intersect with the optical axis of the light detector in the sensitive area of the optical camera, forming the same angles in absolute value with the horizontal plane passing through the intersection point of the optical axes. ! 2. The optical-electronic smoke detector according to claim 1, characterized in that the light emitting module and the light detector module are mounted on a printed circuit board and are not rigidly connected to the optical camera.

Description

The utility model relates to fire fighting equipment, namely, fire alarm, and is designed to detect scattered radiation due to smoke in enclosed spaces of various buildings and structures.

Known fire smoke optical-electronic detector described in patent EP 0813178 "Optical smoke detector" (publ. 1997.12.17), containing a detachable housing, which houses a printed circuit board with an electronic circuit and an optical camera containing two emitting light at the same wavelength light-emitting modules and two light-receiving modules, optically isolated from each other, multifaceted reflective elements, diaphragms and transparent windows, arranged in such a way that two ways of measuring the optical density are formed in the optical camera environment associated with the external environment, and two reference measurement paths.

However, this design of the optical module is cumbersome, difficult to manufacture, maintain and repair, which leads to an increase in consumption and labor intensity and increases the cost of the device. In this case, the detector sensitivity decreases rapidly due to dust settling on the numerous internal surfaces of the optical camera, which increases the level of false alarms and reduces the reliability of the fire alarm system.

Known fire smoke optical-electronic detector described in patent DE 10246756 "Fire detection method and fire detector therefor" (publ. 2004.04.22), comprising a housing in which there is a printed circuit board and an optical camera containing two light-emitting modules located on one axes in separate holders opposite each other, and two light detector modules located on the other axis in their holders opposite each other, intersecting with the first axis in the center of the sensitive region of the optical camera, while any light emitting module is optically lined from any light receiver module with aperture holders and hoods. Light-emitting modules alternately emit light at different wavelengths: the first in the field of infrared radiation, and the second in the field of blue light or ultraviolet radiation.

However, with this design of the optical camera, accurate installation and alignment of the optical system is difficult, which reduces the reliability of the detector.

Closest to the claimed invention is a smoke optical-electronic fire detector described in GB 2397122, “Smoke detector with a low false alarm rate” (publ. 2004.07.14), comprising a detachable case, on the inside of the base of which there is a printed circuit board with electronic a circuit, a microcontroller and an optical camera containing a light emitting module with two LEDs mounted in a holder in the same horizontal plane at an angle to each other, and a light receiver module with a photodiode. The modules are optically isolated from each other by two central curved hoods. To direct the scattered light radiation to the light detector module, special reflective elements are placed in the optical camera, which ensure the same propagation paths of the scattered radiation from the first and second LEDs. In this case, the LEDs alternately emit light in different wavelength ranges: the first is in the visible region of the spectrum, and the second is near the infrared wavelength range.

However, the complex design of the optical module complicates the manufacturing and assembly technology of the fire detector, increases the dimensions, increases production costs and the cost of the product. Dust settling on reflective elements and central hoods reduces the sensitivity of the device and increases the number of false alarms.

The inventors were faced with the task of creating a reliable, technologically advanced, highly sensitive, small-sized detector of smoke optical-electronic fire, providing high accuracy in the detection of fires, accompanied by the appearance of various types of smoke of low concentration in enclosed spaces and the minimum level of false alarms at low cost of the finished product.

The problem is solved in that a smoke optical-electronic smoke detector is proposed, comprising a detachable case, on the inside of the base of which there is a printed circuit board with an electronic circuit, a microcontroller and an optical camera containing a light-emitting module with light emitters emitting at different wavelengths, and a module of the corresponding light receivers optically isolated from each other by a central hood.

What is new is that the light emitters are arranged vertically one above the other in the holes of the holder of the light emitting module so that their optical axes intersect with the optical axis of the light detector in the sensitive area of the optical camera, forming the same angles with the horizontal plane passing through the intersection point of the optical axes . In this case, the light emitting module and the light receiving module are mounted on a printed circuit board and are not rigidly connected to the optical camera.

The technical result of the claimed device consists in increasing the reliability of work, improving manufacturability and reducing material consumption and weight and size characteristics of a smoke optical-electronic smoke detector by simplifying its design, namely, by making the light-emitting module in the form of a separate holder that is not rigidly connected to the optical camera in which two inclined cylindrical holes are molded vertically one above the other symmetrically to the center of the holder. The optical axis of the light emitters installed in the holder of the light emitting module intersect in the sensitive area of the optical camera with the optical axis of the light detector at identical vertical angles of the same magnitude. At the same time, the light-emitting module and the light receiver module installed on the printed circuit board and placed in the optical camera are optically isolated from each other by one central hood, which reduces the dustiness of the optical camera by reducing the area of the reflective elements.

Figure 1 presents the detector fire smoke optoelectronic assembly (section in planes along the optical axes of the light emitters and light detector); figure 2 is a view of the optical camera from below; figure 3 is a front view of the holder of the light emitting module; figure 4 is a view of the holder of the light emitting module in vertical section.

The device comprises a detachable housing 1 (Fig. 1), made in the form of a body of revolution with slots for smoke entry, on the inner side of the base 2 of which a printed circuit board 3 with an optical camera 4 is fixed above its central hole with fastening elements (for example, screws) (Fig. 1, 2), as well as with elements of an electronic circuit and a microcontroller (not shown in FIG.), With which, when a detector is connected to a fire alarm loop, smoke is detected and a Fire signal is transmitted. The optical camera 4 is made, for example, by casting from black plastic in the form of a removable cylindrical cover with a ribbed base 12 inside (Fig. 2), a central hood 7 and a lateral cylindrical shell 13 with labyrinth plates 14 and diaphragms 15, 16, positioning a place for placement of light-emitting module 5 (Fig. 1) and light detector module 6, respectively, which form an optoelectronic pair of modules optically isolated from each other. For fixing the optical camera 4 on the printed circuit board 3 on the lower part of the lateral cylindrical shell 13 (figure 2) of the optical camera 4 (figure 1, 2), latches 17 (figure 2) are made. The light emitting module 5 (FIG. 1) and the light receiving module 6 are mounted on the printed circuit board 3 and are not rigidly connected to the optical camera 4. The light emitting module 5 is formed by the holder 8 (FIGS. 1, 3, 4), in which the light emitters 10 are installed (FIG. 1), for example, an IR LED with a wavelength of 940 nm and a blue LED with a wavelength of 470 nm, the terminals of which are soldered in the corresponding places of the electronic circuit of the printed circuit board 3. The holder 8 of the light-emitting module 5 is molded from plastic, for example, in the form of a side surface rectangular prism in tel e of which there are two mutually inclined cylindrical holes 9 (Figs. 3, 4) for installing light emitters 10 (Fig. 1), arranged vertically one above the other symmetrically to the center of the holder 8, and elastic L-shaped latches 18 protrude on the side faces of the base (Fig. .3, 4) for fixing on the circuit board 3 (figure 1). The light receiver module 6 is also made of plastic in the form of a light detector 11 (for example, a photodiode) mounted in a separate holder, the holder being made with a corresponding mounting hole and latches. To improve the manufacturability of the device assembly, it is possible to make the holder 8 of the light-emitting module 5 composite (not shown in Fig.), For example, of two parts connected by latches, each of which is made by a corresponding inclined cylindrical hole 9 (Figs. 3, 4).

The assembly of the device is as follows. A light emitter 10 and a light detector 11 are mounted at a suitable height on a printed circuit board 3 with a surface mounted on one side and electrically connected to each other 11. A holder 8 is mounted on the base of the light emitters 10 until it stops, which is then fixed by latches 18 in the corresponding holes on the printed circuit board 3 forming a light emitting module 5. Also, the light detector 6 is formed by the light detector 11 and the corresponding holder fixed on the printed circuit board 3. O The camera 4 is located above the printed circuit board 3 so that each of the installed modules 5 and 6 is located respectively to the diaphragms 15 and 16 and is pressed securely by latches 17 on the printed circuit board 3 by pressing the outer side of the base 12, forming a light-tight measuring volume limited by the lateral cylindrical shell 13 with labyrinth plates 14, in which the opaque central hood 7 optically isolates from each other the light emitter module 5 and the light detector module 6. Moreover, the optical axis of the light emitters 10 ne esekayutsya in the sensitive region of the measuring volume, situated near the central hood 7 with the optical axis of the light detector 11 and form with the horizontal plane passing through the point of intersection of the optical axes, equal to the absolute value of angles of, for example, 10-15 degrees. Then the printed circuit board 3 is fixed on the inner side of the base 2 and the detachable housing 1 is latched.

The principle of operation of the device is based on the properties of elastic scattering of light radiation (electromagnetic waves) from particles larger than the wavelength of light. However, scattering can be caused not only by smoke particles, but also, for example, by dust, steam or aerosol. In this case, the device may give a false “Fire” signal. To reduce false alarms, the fact is known from the prior art that fumes consist of smaller particles than dust particles, and besides, smoke of different colors has different particle sizes. For fumes, the particle size varies from 0.1 to 0.6 microns, and for steam, dust and aerosols, from 0.6 to 1 microns. In this case, the amount of scattering of radiation strongly depends on the size of the particles; therefore, with the help of radiation with a shorter wavelength, smaller particles can be detected. With the same size of the smoke particles, the light scattering intensity is inversely proportional to the wavelength. The use of two LEDs with different wavelengths in the light emitting module 5 makes it possible to detect smaller smoke particles by the device, increases the sensitivity to black smoke and sharply reduces the likelihood of false Fire signals caused by the presence of dust, steam and aerosols in the controlled space. And the vertical arrangement of LEDs allows you to minimize the size of the optical camera and reduce the dustiness of the optical camera 4.

The device operates as follows. The smoke optical-electronic smoke detector is calibrated, that is, the critical threshold of smoke is determined in the microcontroller of the device, which is determined by the minimum value of the scattered light received by the light detector module 6, at which a Fire signal is generated and transmitted to the fire alarm loop. The device is electrically connected to the fire alarm loop and, in the absence of a controlled alarm situation, is in standby mode: the infrared and blue LEDs 10 of the light-emitting module 5 alternately (for example, with a shift of 200 ms) emit light pulses of 40 μs duration with a frequency of once every 3 seconds, which scattered in the measuring volume formed between the surface of the printed circuit board 3 and the optical camera 4 mounted on it, and received by the photodiode 11. Photodiode 11 generates the corresponding ktrichesky signal which is supplied to the electronic circuit board 3, wherein the microcontroller is converted into smoke level with a calibration coefficient for each light emitter and compared with the values of "critical threshold" smoke stored in the nonvolatile memory of the microcontroller. In standby mode, the electrical signals from the light detector module 6 do not exceed a predetermined threshold value and, accordingly, the “Fire” signal is not generated.

When a room ignites, smoke through the smoke entry slots of the housing 1 and the labyrinth plates 14 of the optical camera 4 enters the measuring volume formed by the surface of the printed circuit board 3 and the optical camera 4 mounted on it. Light pulses emitted by the infrared LED 10 of the light-emitting module 5 in sequence, described for the standby mode, are reflected from smoke particles in the sensitive region of the measuring volume and fall on the photodiode 11 of the light detector module 6. Photodiode 11 produces an electric signal al, which is supplied to the electronic circuit board 3, is converted from analog to digital, and is compared with a value of "critical threshold" smoke stored in the nonvolatile memory of the microcontroller. When the "critical threshold" is exceeded, two additional measurements of signals from the infrared LED 10 are made with an interval of 0.2 seconds to exclude the influence of various noise, after which the microcontroller generates a signal that the "critical threshold" of smoke is exceeded by the infrared radiation of the LED 10 received by the photodetector 11. Also, radiation measurements are made for the blue LED. Then, the results of measurements of smoke density values (for blue and infrared LEDs) are compared with the “critical threshold” values for each of the LEDs, and if the smoke level for the blue LED is 1.4 times higher than the smoke value for the infrared LED, the microcontroller generates a signal "Fire", which is transmitted to the loop of the fire alarm system. The resumption of the standby mode is carried out after the set time after disconnecting the smoke optical-electronic smoke detector from the power supply.

The claimed smoke optoelectronic fire detector is reliable, technologically advanced in production, small-sized, while it contains a highly sensitive optical system that provides an equally fast response to various types of fires with any color of smoke at a low level of false alarms.

Claims (2)

1. Optical-smoke optical smoke detector comprising a detachable case, on the inside of the base of which there is a printed circuit board with an electronic circuit, a microcontroller and an optical camera containing a light emitting module with light emitters emitting at different wavelengths, and a light detector module, optically isolated from each other each other with a central hood, characterized in that the light emitters are arranged vertically one above the other in the holes of the holder of the light emitting module so that their optical axes intersect with the optical axis of the light detector in the sensitive area of the optical camera, forming the same angles in absolute value with the horizontal plane passing through the intersection point of the optical axes. 2. The optical-electronic smoke detector according to claim 1, characterized in that the light emitting module and the light detector module are mounted on a printed circuit board and are not rigidly connected to the optical camera.