RU110520U1 - FIRST OPTICAL ELECTRONIC FIRE DETECTOR - Google Patents

Abstract

 Optoelectronic smoke detector containing a detachable case, on the inner side of the base of which there is a printed circuit board with an electronic circuit, a microcontroller and an optical camera containing light-emitting and light-receiving modules optically isolated from each other by a central hood, the holders of which are latched to the printed circuit board, characterized the fact that the holder for the light-emitting and light-receiving modules is made in the form of a lateral surface of a rectangular prism with an internal inclination second cylindrical cavity and bounding shelf situated parallel to the optical axis of the light emitter or light receiver, respectively.

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.

A known optical optical smoke detector described in JP 9231485 “Photoelectric smoke sensor” (publ. 1997.09.05), comprising a detachable housing, on the inner side of the base of which there is a printed circuit board with an electronic circuit and an optical camera containing light-emitting and light-receiving modules optically isolated from each other by a central hood made with sawtooth teeth to scatter optical radiation. In this case, the holders of the light-emitting and light-receiving modules mounted on the base of the optical camera have a complex shape with asymmetrical protrusions, and the light-receiving module contains a prismatic lens mounted in the holder.

However, this design of the optical camera is difficult to manufacture, maintain and repair, which increases the complexity of production and the cost of the device.

Known fire smoke optical-electronic detector described in patent RU 2379760 "Optical smoke sensor" (publ. 2010.01.20), containing a detachable housing, on the inside of the base of which is placed a printed circuit board with an electronic circuit and an optical camera having a closed side cover the fence and the bottom with holes for the passage of smoke, inside of which are installed optically isolated from each other, light emitting and light receiving modules in the holders. In the area between the holders, the side fence is made in the form of two faces forming a wedge-shaped region, the apex of which is oriented to the sensitive area of the optical camera, and the inner surface of the face located near the holder of the light-emitting module is gear.

However, with this design of the optical camera, the passage of smoke through the sensitive region of the camera is difficult. In addition, the design is difficult to manufacture and the sensitivity of the detector decreases rapidly due to dust settling on the numerous internal surfaces of the optical camera, which reduces the reliability of the device.

Closest to the claimed invention is the “Optical smoke electronic smoke detector” according to patent RU 66577 (publ. 2007.04.12), comprising a detachable housing, 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 optically isolated light-emitting and light-receiving modules, the holders of which are secured by latches on a printed circuit board and made prefabricated in the form of two fastened with corresponding locking elements, from each other by a central hood entami parts.

However, the implementation of prefabricated optical modules complicates the manufacturing technology and assembly of the fire detector, increases the complexity, production costs and cost of the product. Dust settling on the internal elements of the optical camera reduces the sensitivity of the device.

The inventors were faced with the task of creating a reliable, technologically advanced and inexpensive optical-electronic smoke detector that provides stable smoke sensitivity, which is practically independent of dust settling on the circuit board.

The problem is solved in that a smoke optical-electronic smoke detector is proposed, comprising a detachable housing, on the inner side of the base of which there is a printed circuit board with an electronic circuit, a microcontroller and an optical camera containing light-emitting and light-receiving modules optically isolated from each other by a central hood, the holders of which secured by latches on the circuit board.

What is new is that the holder for the light-emitting and light-receiving modules is made in the form of a lateral surface of a rectangular prism with an inclined cylindrical cavity and a bounding shelf parallel to the optical axis of the light emitter or light detector, respectively.

The technical result of the claimed device is to increase the reliability of the production process and improve the manufacturability of the assembly of a smoke optical-electronic smoke detector by making the holder of the light-emitting and light-receiving modules interchangeable in the form of a side surface of a rectangular prism with an internal inclined cylindrical cavity and a restrictive shelf parallel to the optical the axis of the light emitter or light detector, respectively, which cuts off from the "field of view" of the light emitter or light receiver, the printed circuit board with dust falling on it and allows the use of LEDs and photodiodes with a large variation in parameters in terms of luminosity and scattering angle. And using the same holder for both the light emitter and the light detector simplifies the manufacturing and assembly process and reduces the cost of the product.

Figure 1 presents the fire detector smoke optical-electronic assembly (section in planes along the optical axes of the light emitter and light detector); figure 2 is a General view of the optical camera, the holders of the light-emitting and light-receiving modules, the printed circuit board; figure 3 is a holder of a light receiving (light emitting) module, front view; figure 4 is the same holder in a vertical section; figure 5 - holder, top view.

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 is fixed above its central hole with fastening elements (for example, screws) (Figs. 1, 2) with an optical camera 4, 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 also contains a light emitting module formed by the holder 5 (Fig. 1, 2) and the light emitter 7 installed in it (Fig. 1), for example, an LED with a wavelength of 940 nm, the terminals of which are soldered in the corresponding places of the electronic circuit of the printed circuit board 3 and a light receiving module formed by a holder 6 (Figs. 1-5) with a light detector 7 installed therein (Fig. 1), for example, a photodiode, the terminals of which are also connected to the electronic circuit of the printed circuit board 3.

The optical camera 4 (FIGS. 1, 2) is made, for example, by casting from black plastic in the form of a removable cylindrical cover with a ribbed base 9 inside, made with slots 10 (FIG. 2) for smoke entry, with a central hood (not shown in FIG. ) and a lateral cylindrical shell 11 (Fig. 1, 2) formed by labyrinth plates 12 (Fig. 2), which prevent the penetration of external light, but transmitting smoke, and lodgements 13, 14, positioning the location for holding the holder 5 (Fig. 1, 2) and a holder 6 (FIGS. 1-5), respectively, light emitting and light receiving about modules forming 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 11 (figure 2) of the optical camera 4 (figure 1, 2), latches 15 (figure 2) are made.

The holder 6 (Figs. 1-5) of the light receiving module is molded from black plastic in the form of a lateral surface of a rectangular prism 16 (Figs. 2-5) with an internal inclined cylindrical cavity 17 (Figs. 2-4) for mounting the photodiode 8 (Figs. 1) and a restrictive shelf 18 (FIGS. 2-5), made, for example, in the form of a platform protruding at the base of a rectangular prism from the input side of the light beam parallel to the optical axis of the light receiver at an angle of 7-9 degrees to the plane of the printed circuit board 3 (FIG. 12). The restriction shelf 18 (FIGS. 2-5) is designed to delay the light radiation reflected from the printed circuit board 3 (FIGS. 1, 2) or the inner surface of the optical camera 4, as a result of which the detector becomes more resistant to dust deposited inside the optical camera 4. The dimensions of the restrictive shelf 18 (Fig.2-5) depend on the geometric dimensions and design features of the optical camera 4 (Fig.1, 2), the scattering angles of the LED 7 (Fig.1) and photodiode 8. For example, when performing an optical camera 4 (figures 1, 2) with a height of 17 mm and with an internal m diameter 35 mm, length restrictive shelf 18 is 7 ± 2,5 mm and the width corresponds to the width of six (1-5) of the holder. For fixing on the circuit board 3 (Fig.1, 2) on the side faces of the base of the holder 6 (Fig.1-5) are elastic L-shaped latches 19 (Fig.2-5).

The holder 5 (figure 1, 2) of the light-emitting module is molded from black plastic in the form of a lateral surface of a rectangular prism 20 with an internal inclined cylindrical cavity 21 for installing the light emitter 7 (figure 1) and elastic L-shaped latches 22 (figure 2) . To simplify the manufacturing process, improve the manufacturability of the device assembly and install various types of light emitters (for example, LEDs with different luminosities and scattering angles), the holder 5 (figure 1, 2) of the light emitting module is made with a restrictive shelf 23 (figure 2), location, tilt and the dimensions of which correspond to the same parameters of the restrictive shelf 18 (FIGS. 2-5) of the holder 6 (FIGS. 1-5) of the light receiving module, that is, the holders 5 and 6 are interchangeable.

The assembly of the device is as follows. A light emitter 7 and a light detector 8 are mounted and soldered onto a printed circuit board 3 with one-sided surface mounting and electrically interconnected electronic elements 8. The holder 5 is mounted by the internal inclined cylindrical cavity 21 on the base of the light emitter 7 until it stops and is fixed by latches 22 in the corresponding holes on the printed circuit board 3, forming a light emitting module. The holder 6 is installed by an internal inclined cylindrical cavity 17 on the base of the light detector 8 and is fixed by latches 19 on the printed circuit board 3, forming a light receiving module. In this case, the restrictive shelves 18 and 23 are located above the printed circuit board 3 at an acute angle (for example, 7-9 degrees to the plane of the printed circuit board). Then the optical camera 4 is located above the printed circuit board 3 so that the mounted holders 5 and 6 are located respectively under the lodges 13 and 14 and pressed on the outside of the base 9 Reliably fixed by latches 15 on the printed circuit board 3, forming an opaque measuring volume limited by the lateral cylindrical shell 11 with labyrinth plates 12, in which the light emitter and light detector modules are optically isolated from each other and are not connected rigidly with the optical camera 4. In this case, the optical axes of the light emitter 7 and the light detector 8 intersect in the sensitive region of the measuring volume located near the central hood. Then the printed circuit board 3 is fixed on the inner side of the base 2 and the detachable housing 1 is latched.

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 8, at which a “Fire” signal is generated and transmitted to the fire alarm loop. The device is electrically connected to the fire alarm loop. LED 7 emits light pulses (for example, with a duration of 40 μs with a frequency of once every 3 seconds), which are scattered in the measuring volume formed between the surface of the printed circuit board 3 and the optical camera 4 mounted on it, and are received by the light receiver 8. The light receiver 8 generates a corresponding electrical signal , which is fed to the electronic board 3, where it is converted from analog to digital, is converted by the microcontroller to the smoke level using a calibration factor and compared with the value of the “critical threshold” of smoke stored in the non-volatile memory of the microcontroller. In the absence of smoke, the electrical signals from the light detector 8 do not exceed a predetermined threshold value and, accordingly, the “Fire” signal is not generated. When a room ignites, smoke passes through the smoke entry slots of the housing 1, the slit 10 of the base 9 of the optical camera 4 and the labyrinth plates 12 of the lateral cylindrical shell 11 fall into the measuring volume formed by the surface of the printed circuit board 3 and the optical camera 4 mounted on it. Light pulses emitted LED 7, are reflected from smoke particles in the sensitive region of the measuring volume and increase the electrical signal of the light detector 8 to a value exceeding the value of the "critical threshold" of the smoke stored in the energy microcontroller independent memory. The microcontroller generates a “Fire” signal, which is transmitted to the loop of the fire alarm system.

The declared optical-electronic smoke detector is reliable, technologically advanced in production, small-sized, provides stable sensitivity to smoke, independent of dust settling on the circuit board, and a low level of false alarms.

Claims (1)

Optoelectronic smoke detector containing a detachable case, on the inner side of the base of which there is a printed circuit board with an electronic circuit, a microcontroller and an optical camera containing light-emitting and light-receiving modules optically isolated from each other by a central hood, the holders of which are latched to the printed circuit board, characterized the fact that the holder for the light-emitting and light-receiving modules is made in the form of a lateral surface of a rectangular prism with an internal inclination second cylindrical cavity and bounding shelf situated parallel to the optical axis of the light emitter or light receiver, respectively.