RU177379U1 - Smoke detector - Google Patents

Abstract

The device relates to fire fighting equipment, namely to fire alarms, and is designed to detect scattered radiation caused by smoke in enclosed spaces of various buildings and structures. The technical task to be solved is to create a low-inertia fire smoke detector that provides a high reaction rate to smoke due to fast and symmetrical distribution of both horizontal and vertical air flows inside the housing, and stable smoke sensitivity, does not depend extending from ambient light and dust deposited in need minimal maintenance. The technical result consists in improving the sensitivity of the detector to smoke. The stated technical problem is solved by the fact that a smoke detector is proposed, comprising a housing consisting of matching bases and a lid with a smoke window, an upper smoke ring with radially oriented plate fins on its lower surface , the lower smoke intake ring connected to the base of the housing so that after it is paired with the upper smoke intake ring connected to the cover, the space between it forms a smoke intake chamber, in the center of which at the intersection of the channels for horizontal and vertical smoke passage there is a zone for monitoring the optical density of the medium, a protective grid, a circuit board with holes for vertical smoke passage, an optical module consisting of upper and lower parts and containing in its upper parts inclined, radially oriented hollow holders in which at least one radiation source and receiver are installed, the optical axes of which intersect in the control zone, radiation trap, located on the continuation of the optical axes of the radiation sources and made in the form of an internal cavity in the base of the housing. In this case, the end surfaces of each hollow holder are placed at an angle to each other and form a v-shaped partition that prevents the direct propagation of light, and slots are made between the adjacent end surfaces of adjacent holders. 4 s.p. f-ly, 3 ill.

Description

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

A known smoke smoke detector (patent RU 2301455, a smoke chamber horizontally ventilated, IPC G08B 25/00, published on 06/20/2007), comprising a housing, a smoke intake chamber, a radiation trap, an optical module in which a radiation source is installed in the holders and radiation receiver, the optical axes of which are located at an angle to each other and form in the place of their intersection a control zone of the optical density of the medium. In this case, the smoke intake chamber is formed in the form of a cylindrical surface of a larger diameter with many smooth opaque labyrinth plates located on its periphery in such a way that the radiation incident from the outside is repeatedly reflected from the surfaces of the partitions and partially attenuated, and the smoke penetrates into the optical density control zone of the medium runs along a difficult path between partitions. The control zone of the optical density of the medium is located above the smoke intake chamber and is made in the form of a cylindrical surface of smaller diameter, on the inner surface of which is corrugated both in diameter and on the upper part of the surface, which serves as a radiation trap, the optical axes of the radiation source and receiver are aligned in a horizontal plane with the formation of an obtuse angle between them, and an opaque screen is installed in the center of the upper part of the surface perpendicularly to the optical axes of the radiation source and receiver Preventing direct illumination of the receiver of the radiation source.

However, in the above-described fire smoke detector, there is no vertical smoke passage channel, and the horizontal passage channel has a “broken” path and does not provide free horizontal smoke passage. Opaque screens block only part of the direct radiation from the source to the radiation receiver, and the labyrinth plates only partially weaken the external radiation, which is due to spurious illumination of the radiation receiver, which significantly reduces the sensitivity of the detector as a whole due to the increased level of the initial signal. In addition, the numerous labyrinth plates of the smoke intake chamber have many surfaces on which dust is actively deposited during operation of the above-described fire smoke detector, and the absence of a free horizontal air flow contributes to its accumulation, which leads to more and more false alarms as the device’s operating time increases, since the radiation from the source will be scattered by the dust particles, simulating the scattering from smoke particles caused by a fire. As a result, at least once every few months, the detector is required to be cleaned of dust, which requires shutting down, disassembling, cleaning, checking and calibrating it.

Known fire smoke detector (patent US 4596465 Scattered light type smoke detector, IPC G01N 21/53; G08B 17/10; G08B17 / 107, publ. 06/24/1986), containing a housing in which smoke inlets are made, smoke intake a chamber with labyrinth plates for horizontal smoke passage, a circuit board, an optical module in which a radiation source and a radiation receiver are installed, the optical axes of which are angled to each other in a vertical direction and are mounted obliquely in holders separated by a plate partition without protruding into the smoke intake chamber horizontal x planes and intersect in the smoke intake chamber directly above the partition of the optical module, forming in the place of their intersection a control zone of the optical density of the medium, as well as a radiation trap for attenuating or reflecting the incident radiation in a direction other than to the control zone, made in the form of sawtooth teeth on inclined the upper surfaces of the optical module and on the inner surface of the holders along the optical axes of the radiation source and receiver.

However, in the above-described fire smoke detector, direct radiation from the radiation source, propagating along its optical axis and passing through the optical density control zone of the medium, enters the smoke intake chamber with smooth surfaces and is only slightly attenuated there, which leads to an increase in the initial signal level and negatively affects the detector’s sensitivity, while dust accumulates on the labyrinth plates and the bottom of the smoke intake chamber, which also degrades the sensitivity and changes the level of the initial signal . In addition, the design of the detector provides for the entry of smoke into the measuring chamber only horizontally, and even with obstacles to the free flow of air, while the flow of warm smoke rises vertically, which inevitably increases the response time of the detector in case of fire. Thus, the complex configuration of the labyrinth plates of the smoke intake chamber and the accepted direction of the smoke flow reduce the flow rate in the chamber, which contributes to an increase in dust accumulation and, consequently, leads to an increase in the number of false positives. Therefore, the smoke detector in question, like the previous analogue, needs frequent cleaning from dust.

As a prototype, a smoke smoke detector (patent RU 2509369, Optical smoke detector, IPC G08B 17/10, publ. 03/10/2014) was selected, comprising a housing consisting of bases and lids corresponding to each other, a smoke intake chamber with a plate bottom, upper smoke intake ring, restricting the smoke intake chamber on top and made with radially oriented plate-shaped ribs on its lower surface, forming straight through channels for horizontal smoke passage, and a central hole for vertical passage and smoke, a protective grid, a circuit board, an optical module with a radiation source and receiver, an opaque plate that prevents direct radiation from reaching the radiation receiver, and also a closed side fence, along the perimeter of which are distributed elements of the labyrinth light-reflecting system in the form of cells, forming a radiation trap. In this case, the inner end sections of the plate edges of the smoke intake ring are located near the central hole, but do not protrude beyond its boundary. The plate bottom of the smoke chamber, the area of which corresponds to the area of the central hole of the upper smoke ring, is installed under the specified hole at a level corresponding to the level of the lower surfaces of the ribs, with the formation of a gap for vertical smoke penetration, and the optical module consists of the upper and lower parts, located on the upper surface of the upper smoke intake ring and contains holders in which the source and receiver of radiation are installed without protruding into the smoke intake chamber areas whose optical axes are located at an angle to each other and form a zone of optical density control at their intersection.

However, in the prototype, direct through channels for horizontal smoke passage of the smoke intake chamber and the optical density control zone of the medium are specially structurally located in different horizontal planes and smoke passes into the optical density control zone of the medium through a narrow slot gap, which, together with the implementation of the optical chamber with a closed labyrinth system creates increased aerodynamic resistance to the smoke stream flowing in the zone of optical density control of the medium, thereby increasing the detection time pa. Moreover, in the prototype there is no free vertical smoke flow into the control zone of the optical density of the medium. In addition, the accumulation of dust on the cells of the labyrinth system and the plate bottom causes a decrease in the sensitivity of the detector and its false alarms. So, again, its corresponding service is inevitable.

The inventors were faced with the task of developing a low-inertia fire smoke detector, which provides a high reaction rate to the appearance of smoke due to the fast and symmetrical distribution of both horizontal and vertical air flows inside the housing, and stable sensitivity to smoke, independent of external exposure and settled dust, and in need of minimal maintenance.

The problem is solved in that a fire smoke detector is proposed, comprising a housing consisting of bases and lids corresponding to each other, a smoke sampling chamber bounded by an upper smoke sampling ring made with radially oriented plate ribs on its lower surface, forming straight through channels for horizontal passage smoke, and with a central hole for vertical passage of smoke, a protective grid, a circuit board, a radiation trap, an optical module consisting of an upper and lower hour s and comprising holders, in which no protrusion into chamber dymozabornuyu installed, at least one radiation source and the receiver, the optical axes of which are arranged at an angle to each other and intersect at the optical density of the control zone of the medium. New in the inventive detector is that the housing cover in the upper part contains a smoke intake window, the central region of the circuit board is made with holes for vertical smoke passage located under the smoke intake window of the housing cover, the upper part of the optical module is made in the form of a disk with a central hole for vertical passage smoke, the upper surface of which is connected to the circuit board, and on the lower, symmetrically relative to the center of the disk, inclined, radially oriented hollow holders are made, in which At least one radiation source and one radiation receiver are installed, while the end surfaces of each hollow holder are placed at an angle to each other and form a v-shaped partition that prevents direct light propagation, and slots of vertical smoke passage are made between the adjacent end surfaces of adjacent holders, the lower part of the optical module is an inverted conical ring, covering the assembly of hollow holders with installed sources and receivers of radiation. In this case, the housing contains a lower smoke intake ring connected to the base of the housing so that when it is paired with the upper smoke intake ring connected to the cover, the space between the upper surface of the lower smoke intake ring and the lower surface of the upper smoke intake ring forms a smoke intake chamber, in the center of which is at the intersection of the channels For horizontal and vertical smoke passage, a zone of optical density control is located. The base of the housing contains a radiation trap located on the continuation of the optical axes of the radiation sources and made in the form of an internal cavity in the base of the housing, bounded by the internal surface of the base, a diametrical partition and a lower smoke intake ring. In addition, the base, cover, optical module, upper and lower smoke intake rings are made of a material that simulates dusting the surface, the surfaces of the radiation trap are ribbed, hollow holders in the optical module are located in two vertical planes perpendicular to each other, in front of the radiation sources and receivers in the optical the module can be equipped with focusing lenses with foci located in the zone of optical density control of the medium.

The technical result is to improve the sensitivity of the detector to smoke. The claimed technical result is achieved by improving the design of the chimney and the use of two direct-flow chimney channels, horizontal and vertical, as well as by performing a radiation trap for scattering and absorption of spurious radiation from a source in the form of an internal cavity in the base of the detector. The smoke intake chamber for direct horizontal smoke entry is made in the form of the space between the upper surface of the lower smoke intake ring and the lower surface of the upper smoke intake ring, delimited by radially oriented plate-shaped ribs on the lower surface of the upper smoke intake ring, which form straight through channels for horizontal smoke passage, which ensures a quick flow smoke in the event of smoke spreading from the ceiling due to air flow in the room. The above-described design of the smoke intake chamber with straight channels without labyrinth plates and a closed side fence and the installation of radiation sources and receivers in the optical module without protruding into the smoke intake chamber with tilting their optical axes in horizontal and vertical planes in inclined, radially oriented hollow holders, end surfaces of each of which are placed at an angle to each other and form a v-shaped partition that prevents the direct propagation of light, provides high senses detector performance and free flow of air flows inside the housing, which accelerates the detector response to smoke and prevents dust from settling during operation, thereby ensuring long-term stabilization of sensitivity at the initial level. A smoke intake window in the upper part of the housing cover, openings in the central region of the circuit board, a central hole and vertical smoke passage openings in the upper part of the optical module, made between the adjacent end surfaces of the adjacent hollow holders, as well as the inner hole of the inverted conical ring of the lower part of the optical module, covering hollow holders in the assembled optical module, and the opening of the upper smoke intake ring form a vertical smoke channel directing smoke for the shortest possible time it has a direct route to the control zone of the optical density of the medium, which is important for the rapid detection of smoldering, only incipient fires in rooms with poor ventilation. This application of two direct-flow smoke channels, horizontal and vertical, and the location of the optical density control zone in the center of the smoke chamber at the intersection of the smoke channels ensures high speed and uniform sensitivity of the detector regardless of the direction of smoke propagation and improves the sensitivity of the declared detector to fires with various types of smoke propagation . In addition, in the inventive fire smoke detector for scattering and absorption of spurious radiation from the source, the internal surfaces of the open cavity at the base of the detector are rationally used, forming a radiation trap, which allows you to abandon the smoke chamber of black light-absorbing material with labyrinth plates that quickly accumulate dust used in analogues with low sensitivity, and provides higher sensitivity of the detector with similar overall dimensions. In this case, the surface of the radiation trap is made with a low reflection coefficient, which minimizes backscattering and reflection and ensures stable detector sensitivity for a long time, since when dust enters the camera and settles on the walls, there is no change in the level of radiation incident on the radiation receiver, and the detector does not give a false alarm. In addition, when installing the detector on the ceiling of the controlled room, the radiation trap is located with a hole down and above the smoke chamber, which will significantly reduce the accumulation of dust and other small particles, since the particles will not “fall through” into the internal cavity at the base of the body, and the air flow, passing through the direct-flow smoke channels of the smoke chamber, it will easily remove them from the housing. Therefore, the inventive fire smoke detector provides not only a higher, but also more uniform and stable sensitivity, independent of the direction of smoke propagation.

In FIG. 1 is a schematic cross-sectional view of an assembled fire detector located in a working position when a controlled room is installed on the ceiling, where arrows indicate the direction of air flow at the entrance to its smoke channels; in FIG. 2 is a perspective view of the components of a fire smoke detector in isometry; in FIG. 3-upper part of the optical module, top view.

The device comprises a housing 1 (Fig. 1, 2), consisting of mating base 2 and a cover 3 made by hot casting from plastic, a radiation trap 4 (Fig. 1, 2), a smoke chamber 5 (Fig. 1), formed the upper smoke sampling ring 6 (Fig. 1, 2), restricting the smoke intake chamber 5 from above (Fig. 1), and the lower smoke sampling ring 7 (Fig. 1, 2), restricting it from below, a protective net 8 installed between them (Fig. 2) ), circuit board 9 (Fig. 1, 2), an optical module 10 (Fig. 1, 2), consisting of the upper part 11 (Fig. 1, 2, 3) and the lower part 12 (Fig. 1, 2) and including hollow holders 13 (Fig. 1, 2, 3) in which at least one radiation source 14 (Fig. 1, 2) and at least one radiation receiver 15 (Fig. 1, 2) are installed, without protrusion into the smoke intake chamber 5 ), the optical axes of which are located at an angle to each other and form in the place of their intersection of the control zone of the optical density of the medium 16 (Fig. 1). The upper part 11 (Fig. 1, 2, 3) of the optical module 10 (Fig. 1, 2) is molded from plastic by hot casting in the form of a disk 17 (Fig. 1, 3) with a central hole 18 (Fig. 2, 3) for vertical passage of smoke, the upper surface of which is assembled connected to the circuit board 9, and on the lower, symmetrically relative to the center of the disk 17, inclined, radially oriented hollow holders 13 (Figs. 1, 2, 3) are located, for example, in two vertical planes perpendicular to each other, and partially overlapping the central hole 18. In the holders 13 set at least one radiation source 14 and at least one radiation receiver 15 with a tilt of their optical axes in horizontal and vertical planes (either one source and a radiation receiver opposite each other, or two sources and one a receiver, or one source and two receivers in the zones of backward and side scattering, or two sources and two radiation receivers opposite each other, depending on the operating conditions of the detector and the need to exclude a decision on fire When present in the air space of controlled particle size which is different from the size of smoke particles). In this case, the end surfaces 19 (Fig. 3) of each hollow holder 13 are placed at an angle to each other and form a vertical v-shaped partition that prevents direct light propagation, and slots 20 are made between the adjacent end surfaces of adjacent holders (Fig. 1, 3) for vertical smoke passage, which converge to the center of the optical module 10 and form a curly slot, for example, when the holders are located in two vertical planes perpendicular to each other, a cross-shaped slot with the center on the vertical hydrochloric central axis of the detector. The lateral surface 21 (Fig. 2, 3) of the hollow holders 13 can be made, for example, tubular, box-shaped or other, suitable for fixed installation in the holders 13 of the source 14 or radiation receiver 15. As the radiation source 14, for example, infrared (or other wavelength range) LED, and as a radiation detector 15 - a photodiode. It is permissible to use a source 14 and a radiation receiver 15 with narrow radiation patterns or an installation, in front of them focusing lenses (not shown in the figure), the foci of which are located in the optical density control zone of the medium 16, for the formation of narrower light beams. The lower part 12 of the optical module 10 is molded from plastic and is, for example, an inverted conical ring 22 (Fig. 1, 2), the outer diameter of which corresponds to the diameter of the disk 17 of the upper part 11 of the optical module 10, covering the complete hollow holders 13 and fixing installed they contain 14 sources and radiation receivers 15. The lower opening of a smaller diameter of the inverted conical ring 22 provides free vertical smoke passage and radiation propagation from sources 14 to the optical density control zone 16, but limits the illumination of the radiation receiver 15. The control zone of the optical density of the medium 16 is an internal space of the detector housing 1 located in the center of the smoke chamber 5 at the intersection of the channels for horizontal and vertical smoke passage, in which the optical axes of the radiation sources 14 and radiation receivers intersect 15. The dimensions of the control zone of the optical density of the medium 16 are directly proportional to the solid angles of radiation of the source 14 and the radiation receiver 15. The upper smoke intake ring 6 in full hot molding of the plastic in the form of an annular plate with a radially oriented plate fin 23 (Fig. 2) on the lower surface, forming straight through channels for horizontal smoke passage, and with a central hole 25 (Fig. 2) for vertical smoke passage, which also serves to reduce spurious illumination of radiation receivers 14. In this case, the plate fins 23 decrease in height from the periphery to the center, and their inner end sections 24 (Fig. 2) protrude into the Central hole 25 to direct horizontal air flow directly into the control zone of the optical density of the medium 16. When assembling the upper smoke intake ring 6 fixed in the cover 3, thereby finally fixing the circuit board 9 and the optical module 10 in it. The lower smoke intake ring 7 (Fig. 1, 2) is made by hot casting of plastic in the form of an annular plate, which has a diameter and a hole size of 26 (fig. . 1, 2) in the center of the lower smoke intake ring 7, are commensurate with the corresponding parameters of the upper smoke intake ring 6. During assembly, the lower smoke intake ring 7 is connected to the base 2 of the housing 1 and, after it is paired with the upper smoke intake ring 6, forms a smoke intake chamber 5 in the form of transports between the upper surface of the lower smoke sampling ring 7 and the lower surface of the upper smoke sampling ring 6, which is delimited by radially oriented plate ribs 23 of the upper smoke sampling ring 6. The lower smoke sampling ring 7 restricts the radiation trap 4 from above to scatter and absorb light from radiation sources. The radiation trap 4 is located on the continuation of the optical axes of the radiation sources 14 and is made in the form of an open inner cavity in the base 2, limited on the sides by the inner surface 27 (Fig. 1, 2) of the base 2 (for example, the inner surface of its bottom and side surface) and diametrical by a partition 28 (Fig. 1, 2), and from above by a lower smoke sampling ring 7, through a central opening 26 of which radiation from a source 14 directly penetrates into the internal space of a radiation trap 4, where, due to repeated reflection and diffusion, ence on the internal surfaces is absorbed efficiently, without departing from the cavity. The radiation trap 4 can be made, for example, in a hemispherical shape or in the shape of a half truncated cone, and its dimensions and shape are proportional to the size and shape of the base. Moreover, the surface of the radiation trap 4 is made with a small reflection coefficient, for example, rough, ribbed, with notches in the form of a saw tooth or from a material that simulates dusting, which improves backscattering and reflection of radiation, and also ensures stable detector sensitivity independent of settling dust. The cover 3 of the housing 1 is molded from plastic in the form of a body of revolution, for example, in the form of a hollow truncated cone, in the upper base of which there is a smoke intake window 29 (Fig. 1, 2), and positioning elements are located on the inner surface (not shown in the figure) for example, protrusions for positioning and fixing the circuit board 9, the optical module 10 and the upper smoke sampling ring 6. The base 2 of the housing 1 on the lower side contains electrical contacts (not shown in the figure) for electrical connection of the detector to the loop alarm system. All the above-described plastic structural elements of the claimed fire smoke detector can be made in any color and with a surface of smooth or varying degrees of roughness. The circuit board 9, on which the elements of the electronic circuit and the microcontroller are installed (not shown in the figure), which control the operating state of the detector when it is connected to the fire alarm loop, is preferably made in the form of a round plate, in the center of which holes 30 are made by perforation (FIG. 2) for vertical smoke passage, located in the area corresponding to the smoke intake window 29 of the cover 3 of the housing 1. A protective mesh 8, which prevents the entry of insects and similar small objects into the control zone, is made on example, from a metal wire with a diameter of 0.25 mm with a mesh size of 0.65 × 0.65 mm in the form of a ring of a certain diameter, sealed or welded by spot welding, and in the assembled detector is fixed in the housing between the lower smoke ring and the upper smoke ring, around the outer ends of the plate ribs.

When assembling the claimed fire smoke detector, a circuit board 9 with electronic circuit elements, a microcontroller, sources 14 and radiation detectors 15 in the optical module 10 is installed in the cover 3 and is fixed in it by the upper smoke sampling ring 6. The circuit board 9 is electrically connected by wires to the electrical contacts of the base 2 . In the base 2 of the housing 1, the lower smoke intake ring 7 is fixed, a protective mesh 8 is positioned on it on the periphery, and the base 2 is connected to the cover 3 in a single housing 1, made in the form body of rotation, while the lower smoke intake ring 7 mates with the upper smoke intake ring 6, forming a direct-flow smoke intake chamber 5, surrounded by a protective mesh 8.

The device operates as follows. The radiation source 14 emits light in a given wavelength range, the beam from the source 14, focused in the zone of optical density control of the medium 16, propagates further and falls into the radiation trap 4, where it is scattered without introducing errors into the low level of the radiation receiver signal 15. When fire in a room controlled by the detector, the smoke quickly and unhindered penetrates into the interior of the sensor directly into the control zone of the optical density of the medium 16, passing through a horizontal smoke channel through the grid 8 and a smoke intake chamber 5 between radially oriented plate-shaped ribs 23 on the lower surface of the upper smoke intake ring 6 and the upper surface of the lower smoke intake ring 7, as well as through a vertical smoke channel formed by the smoke intake window 29 of the cover 3 of the housing 1, holes 30 in the circuit board 9, the central hole 18 and slots 20 for vertical smoke passage in the upper part 11 of the optical module 10, a hole in the conical ring 22 of the lower part 12 of the optical module 10 and the hole 25 of the upper smoke intake ring 6. From teachings of the radiation source 14 is scattered by the smoke particles is detected radiation detector 15 as a high signal level.

The claimed fire smoke detector is low inertia, has a straight-through structural design of horizontal and vertical smoke entry, which provides quick and symmetrical distribution of the air flow inside the housing, high reaction speed and stable sensitivity to smoke when changing the size and direction of the air flow, reliable, has effective protection against dust and insects, needs rare maintenance during operation and is able to control smoke in contaminated displacements.

Claims (5)

1. Fire smoke detector, comprising a housing consisting of bases and lids corresponding to each other, a smoke intake chamber bounded by an upper smoke intake ring made with radially oriented plate fins on its lower surface, forming straight through channels for horizontal smoke passage, and with a central a hole for vertical smoke passage, a protective grid, a circuit board, a radiation trap, an optical module consisting of upper and lower parts and including holders in which at least one radiation source and receiver, the optical axes of which intersect in the control zone of the optical density of the medium, characterized in that the housing cover in the upper part contains a smoke intake window, the central region of the circuit board is made with holes for vertical smoke passage, located under the smoke intake window of the housing cover, the upper part of the optical module is made in the form of a disk with a central hole for vertical smoke passage, the upper surface of which is connected to the circuit board, and on the lower, symmetrically relative to the center of the disk, inclined, radially oriented hollow holders are made, in which at least one radiation source and one radiation receiver are installed, while the end surfaces of each hollow holder are placed at an angle to each other and form an obstacle to the direct propagation of light a v-shaped partition, and between the adjacent end surfaces of adjacent holders there are slots of vertical smoke passage, the lower part of the optical module is a a curved conical ring that encompasses the hollow holders with installed radiation sources and receivers, the housing comprising a lower smoke ring connected to the base of the housing so that when it is paired with the upper smoke ring connected to the cover, the space between the upper surface of the lower smoke ring and the lower surface of the upper smoke intake ring forms a smoke intake chamber, in the center of which at the intersection of the channels for horizontal and vertical smoke passage is located to control the optical density of the medium, in addition, the base of the housing contains a radiation trap located on the continuation of the optical axes of the radiation sources and made in the form of an internal cavity in the base of the housing, limited by the internal surface of the base, a diametrical partition and a lower smoke ring. 2. Smoke fire detector according to claim 1, characterized in that the surfaces of the radiation trap are made ribbed. 3. The smoke detector according to claim 1, characterized in that the hollow holders in the optical module are located in two vertical planes perpendicular to each other. 4. Fire smoke detector according to claim 1, characterized in that in front of the radiation sources and receivers in the optical module there are focusing lenses with foci located in the optical density control zone of the medium. 5. The smoke detector according to claim 1, characterized in that the base, cover, optical module, upper and lower smoke intake rings are made of a material that simulates dusting of the surface.

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