RU47547U1 - SMOKE DETECTOR - Google Patents

Abstract

The utility model relates to fire detection means, namely to optoelectronic smoke detectors. The objective of the claimed utility model is to expand the range of optoelectronic smoke detectors. The essence of the utility model is that in a smoke detector containing a section for controlling the optical density of a smoky environment with a light source and a photodetector located inside it, having a side enclosure, the inner surface of which participates in the formation of the working volume of the indicated section, and this surface is made flat, is located perpendicular to the plane of the horizontal section of the indicated section and contains a wedge-shaped region formed by its two sections, with the vertex facing outward, with the light source and the photodetector are mounted at an angle to each other so that their optical axes lie in the horizontal plane of the optical density control section of the smoky medium, the optical axis of the light source is outside the field of view of the photodetector, and the intersection point of these optical axes is located inside the working volume the specified section, according to the utility model, the light source and the photodetector are placed in hollow holders mounted at an angle to each other, the rear optical density control section The filler medium has a bottom and a cover, while the working volume of the indicated section is formed by the bottom and the cover, as well as the end surfaces of the holders placed at an angle to each other and the inner surface of the side fence formed by the first and second extended walls, placed on different sides relative to the intersection point of these optical axes and located relative to each other with the possibility of re-reflection of light incident on their inner surfaces, the first of which is oriented to the optical axis and source of light and arranged between said extended walls of the first and second shorter walls intersecting to form a wedge-shaped region, the first of which is located opposite the second longest wall, the wedge apex region in horizontal cross-sectional plane of the optical density of the medium control section of smoky lies at the periphery

the inner surface of the side fence, the mutual angular position of all these walls in the plane of the horizontal section of the indicated section, and also their width, are selected such that the radiation from the light source reflected by the inner surface of the first extended wall and subsequently reflected by the inner surfaces of the extended walls and the walls of the wedge-shaped region is directed the inner surface of the first extended wall and the inner surface of the first wall of the wedge-shaped region in the direction of the light source, at the same time, in the side fence, in addition to the indicated walls, there are walls in which grooves are made, forming openings for the penetration of smoke into the smoke density optical density control section. 1 n.p.ph., 2 s.p.f., 1 ill.

Description

The utility model relates to fire detection means, namely to optoelectronic smoke detectors.

The operation of an optoelectronic smoke detector containing a light source and a photodetector located in such a way that light cannot be transmitted directly from the source to the photodetector is based on the fact that in the presence of smoke particles in the area where the optical radiation density of a smoky medium is controlled, the scattered particles of smoke light radiation enters the photodetector, while the corresponding electrical signal is generated. In this regard, it is very important that light scattered specifically by the smoke particles enter the photodetector and the so-called background light reflected by the smoke detector parts or from the outside does not come in, since the electrical signal caused by the background light reduces the accuracy of the detector and can lead to its false positive.

Known smoke detector [RU 2189639], containing a light source and outside the field of view of the photodetector, placed inside the optical density control section of a smoky environment having a bottom, a lid and a side fence. Moreover, this section has a central lens hood, as well as peripheral lens hoods forming a labyrinth system, arranged so that the angle of incidence of the light rays emitted by the light source and received by the photodetector on these lens hoods is constant. The center and peripheral lens hoods, as well as the camera cover, have a shiny surface. Due to the fact that the indicated detector parts have a shiny surface and the light that is not absorbed by the detector parts is repeatedly reflected between the peripheral lens hoods, it is possible to suppress the background light to a large extent in this design and thereby increase the accuracy of the detector.

However, this smoke detector has a very complex structure.

Known smoke detector [RU 2141133], which is selected by the authors as the closest analogue.

The specified smoke detector contains a base, a housing provided with openings for the penetration of smoke, as well as a section for controlling the optical density of a smoky medium located inside the housing, the working volume of which is formed by the side fence. The inner surface of the side fence is made flat, located perpendicular to the horizontal plane of the section and is a side surface of a straight prism having an isosceles trapezoid at the base. The height of the indicated trapezoid is greater than the length of its smaller base. In the body of the section for controlling the optical density of a smoky medium, there are through channels located at an angle to each other, in which a light source and a photodetector are located, respectively. In this case, the light source and the photodetector are installed in such a way that their optical axes lie in the plane of the horizontal section of the indicated section, the optical axis of the light source is outside the field of view of the photodetector, these optical axes extend into the working volume of the optical density control section of the smoky medium from the surface corresponding to the face prisms formed by the smaller base of the trapezoid, and the intersection point of these optical axes is located inside the working volume of the specified section.

The light rays emitted by the light source fall on the side face of the fence located opposite the light source, and then are repeatedly reflected by the faces of the wedge-shaped area in the side fence formed by this side face and the face formed by the large base of the trapezoid.

This detector provides suppression of background light. However, in this smoke detector, the optical density control section of the smoky medium is made open above and below, and smoke enters its working volume through the free space available in the detector body above and below this section, which limits the possibility of minimizing the size of the considered detector by its height.

The objective of the claimed utility model is to expand the range of optoelectronic smoke detectors.

The essence of the utility model is that in a smoke detector containing a section for controlling the optical density of a smoky environment with

placed inside it a light source and a photodetector having a side fence, the inner surface of which participates in the formation of the working volume of the specified section, and the specified surface is made flat, is perpendicular to the horizontal plane of the section and contains a wedge-shaped region formed by two of its sections, facing the apex outward, the light source and the photodetector are mounted at an angle to each other so that their optical axis lie in the plane of the horizon cross section of the control section of the optical density of a smoky medium, the optical axis of the light source is outside the field of view of the photodetector, and the intersection point of these optical axes is located inside the working volume of the specified section, according to a useful model, the light source and photodetector are placed in hollow holders installed at an angle to each other, the smoke density optical density control section has a bottom and a cover, while the working volume of the specified section is formed by the bottom and cover, as well as placed at an angle dr angled to each other by the end surfaces of the holders and the inner surface of the side fence formed by the first and second extended walls placed on different sides relative to the intersection point of these optical axes and located relative to each other with the possibility of re-reflection of light incident on their inner surfaces, the first of which is oriented optical axis of the light source, as well as shorter walls intersecting between the specified extended walls of the first and second, intersecting with the formation of a wedge-shaped region, the first of which is located opposite the second extended wall, and the top of the wedge-shaped region in the horizontal plane of the optical density control section of the smoky medium lies on the periphery of the inner surface of the juice fence, the relative angular position of all these walls in the horizontal plane of the section, and also their width is chosen such that the radiation from the light source reflected by the inner surface of the first extended wall and which is completely reflected by the inner surfaces of the extended walls and the walls of the wedge-shaped region, is guided by the inner surface of the first extended wall and the inner surface of the first wall of the wedge-shaped region toward the light source, while in the side fence, in addition to these walls, there are

walls in which grooves are made, forming openings for the penetration of smoke into the smoke density optical density control section.

A smoke detector embodiment is possible in which the side fence has an additional wall located outside relative to the first short wall of the wedge-shaped area and intersecting with it to form an additional wedge-shaped area on the periphery of the inner surface of the side fence, while this section is a figure in the horizontal plane, inscribed in a circle, and the inner surfaces of the first and second extended walls and the additional wall form the sides of a polygon nick, which are segments of the chords of the circle.

It is advisable that in the cavity of the holder of the light source and in the cavity of the holder of the photodetector, respectively, there is at least one diaphragm.

The presence of two extended walls and two walls of the wedge-shaped region in the lateral guard of the optical density control section of the smoky medium ensures the formation of two regions in which multiple re-reflection of the rays emitted by the light source occurs. Moreover, it is fundamentally important that the relative angular position of all these walls in the horizontal plane of the optical density control section of the smoky medium and their width are selected such that the radiation from the light source reflected by the inner surface of the first extended wall, to which the optical axis of the light source is oriented , and successively re-reflected by the inner surfaces of both extended walls and the inner surfaces of the walls of the wedge-shaped region, is guided by the inner the surface of the first extended wall and the inner surface of the first wall of the wedge-shaped region in the direction of the light source. Due to the above design features, the inventive smoke detector provides effective suppression of background light, which increases the accuracy of its operation and reduces the likelihood of false positives.

Due to the fact that the light source and the photodetector are placed in holders located at an angle to each other, and the input of light radiation into the working volume of the specified section and the output of light rays from it is carried out

from the end surfaces of these holders located normal to the optical axes of the radiation source and the photodetector respectively, these light beams are oriented strictly along their optical axes, which also increases the accuracy of its operation.

The presence of a bottom and a cover in the optical density control section of a smoky environment increases the security of the specified section from penetration of light rays from outside into its working volume. Moreover, in the side enclosure of the indicated section, in addition to the above-described walls, there are walls in which grooves are made forming holes for the penetration of smoke into the indicated section, which minimizes the height of the inventive smoke detector, since open space is not required in order to ensure the access of smoke into the indicated section smoke detector housing above and / or below the specified section.

The required angular position of all the walls involved in light reflection in the horizontal plane of the optical density control section of a smoky medium, as well as the width of each of these walls, are selected experimentally, in particular, by computer simulation of the process of reflection and re-reflection of light rays emitted by a light source.

An embodiment of a smoke detector, in which in the horizontal plane the indicated section is a figure inscribed in a circle, provides the convenience of mounting said section on the basis of a smoke detector, traditionally in the shape of a circle, as well as a rational arrangement of parts of this section in terms of achieving its minimum dimensions in the plane of horizontal section. Due to the presence in the considered embodiment of the smoke detector of an additional wedge-shaped region on the periphery of the inner surface of the side fence formed by the additional wall and the first wall of the wedge-shaped region, the security of the optical density control section of the smoky medium from penetrating into its working volume of radiation from an external light source is increased. Moreover, due to the fact that in the horizontal plane of the indicated section, the inner surfaces of the first and second extended walls and the additional wall form the sides of the polygon, which are segments of the chords of the circle into which the indicated section is inscribed, the process of selecting the required angular and linear

the dimensions of these walls of the side rails, carried out by modeling the process of reflection of light rays using a computer.

The presence in the cavity of the holder of the light source and in the cavity of the holder of the photodetector of one or more diaphragms contributes to the formation of narrow, respectively, emitted and received light fluxes, which increases the accuracy of the smoke detector.

The figure shows a General view drawing of the inventive smoke detector in horizontal section.

The smoke detector contains a section 1 for controlling the optical density of a smoky medium, inside of which there are a light source 2 and a photodetector 3, placed in hollow tubular holders 4 and 5 mounted at an angle to each other.

The working volume of section 1 is formed by the end surfaces of the holders 4 and 5 located at an angle to each other, as well as a side fence formed by the flat inner surface of the walls 6, 7, 8, 9 of section 1. A light source 2 and a photodetector 3 are installed in the holders 4 and 5 so that their optical axes lie in the horizontal plane of section 1, the optical axis of the light source 2 is outside the field of view of the photodetector 3, and the intersection point O of the indicated optical axes is located inside the working volume of section 1. In addition, sec Section 1 has a bottom 10 and a cover (not shown in the drawing).

Walls 6 and 7 are placed on different sides relative to the intersection point of these optical axes and are located relative to each other with the possibility of re-reflection of light incident on their inner surfaces 11 and 12. Walls 8 and 9 are located between these extended walls 6 and 7, and the inner surfaces 13 and 14 of walls 8 and 9 intersect with the formation of a wedge-shaped region, the apex of which in the horizontal plane of section 1 is facing outward and lies on the periphery of the inner surface of the side fence. In this case, the optical axis of the light source 2 is oriented to the inner surface 11 of the wall b, and the inner surface 13 of the wall 8 is located opposite the inner surface 12 of the wall 7.

Section 1 also has an additional wall 15 having an inner surface 16. The wall 15 is located outside relative to the wall 8 and

intersects with it to form an additional wedge-shaped area on the periphery of the inner surface of the side railing of section 1. Section 1 also contains a wall 17 placed between the side surface of the holder 5 and wall 6, wall 18 placed between the wall 9 and wall 7, wall 19 placed between wall 7 and the side surface of the holder 4, in which grooves are made (not visible in the drawing), forming holes for smoke to enter the section 1. A similar groove (not shown in the drawing) is also on the end section of the wall 6. Cr In addition, section 1 comprises a wall 20 placed at its periphery between the side surfaces of the holders 4 and 5, which prevents the penetration of section 1 through the gap between the indicated light beam holders from the outside, as well as walls 21 and 22 located between the wall 20 and the side surfaces of the holders 4 and 5, in which grooves are also made (not visible in the drawing), forming openings for the penetration of smoke into section 1. Section 1 in the plane of horizontal section is a figure inscribed in a circle, while Cored oil surface 11, 12 and 23 of the walls 6, 7 and 20 are the lengths of chords of said circle.

The mutual angular position in the plane of the horizontal section of section 1 of the walls 6, 7, 8, and 9, the inner surfaces of which are involved in the reflection of light, and their width are selected such that the radiation from the light source 2 is reflected by the inner surface 11 of the wall 6 and subsequently re-reflected the inner surfaces 11 and 12 of the walls 6 and 7 and the inner surfaces 13 and 14 of the walls 8 and 9 are guided by the inner surface 11 of the wall b and the inner surface 13 of the wall 8 towards the light source 2.

In the cavity of the holder 4 of the light source 2 there is a diaphragm 24, contributing to the formation of a narrow light beam. The outlet located at the end of the holder 4 is provided with a partition 25 that prevents light from the light source 2 from entering the area located near the inlet of the holder 5 located at its end. In the cavity of the holder 5 of the photodetector 3 there are diaphragms 26 and 27, contributing to the narrowing of the beam of light rays received by the photodetector 3

The device operates as follows

In the absence of smoke particles, light radiation from the light source 2 enters the inner surface 11 of the wall 6, partially reflects it to the area of the light source 2, and partially goes to the inner surface 12 of the wall 7, after which it is reflected onto the inner surface 11 of the wall 6. The light radiation repeatedly reflected by the inner surfaces 11 and 12 is substantially attenuated, while the radiation not absorbed by the indicated surfaces is directed by the surface 11 toward the source Nick 2 light. Similarly, light radiation reflected by surface 12 and not falling onto surface 11 hits the surface 13 of the wall 8 of the wedge-shaped region, partially reflects it to the area of the light source 2, and partially directs the indicated surface to the surface 14 of the wall 9 of the wedge-shaped region. Repeatedly reflected by the surfaces 13 and 14 of the walls 8 and 9 of the wedge-shaped region, the light radiation is significantly weakened, while the radiation not absorbed by the indicated surfaces is directed by the surface 13 towards the light source 2. As a result, in the inventive smoke detector, it is possible to effectively suppress the background light, so that in the absence of smoke particles, light radiation does not enter the photodetector 3.

In the presence of smoke particles, the light emitted by the source 2 is scattered by the indicated particles, and the scattered radiation enters the photodetector 3, while it generates a corresponding electrical signal.

Claims (3)

1. A smoke detector containing a section for controlling the optical density of a smoky medium with a light source and a photodetector located inside it, having a side fence, the inner surface of which participates in the formation of the working volume of the indicated section, the indicated surface being flat, located perpendicular to the horizontal plane of the section and contains a wedge-shaped region formed by two of its sections, with its apex facing outward, while a light source and a photodetector are installed at an angle to each other so that their optical axes lie in the horizontal plane of the section for monitoring the optical density of the smoky medium, the optical axis of the light source is outside the field of view of the photodetector, and the intersection point of these optical axes is located inside the working volume of the specified section, characterized in that the light source and the photodetector are placed in hollow holders installed at an angle to each other, the section for controlling the optical density of the smoky medium has a bottom and a cover, while the slab of the indicated section is formed by the bottom and the cover, as well as the end surfaces of the holders placed at an angle to each other and the inner surface of the side fence formed by the first and second extended walls, placed on different sides relative to the intersection point of these optical axes and located relative to each other with the possibility of re-reflection incident on their inner surface of the light, on the first of which the optical axis of the light source is oriented, as well as between the long walls of the first and second shorter walls intersecting to form a wedge-shaped region, the first of which is opposite the second extended wall, and the top of the wedge-shaped region in the horizontal plane of the optical density control section of the smoky medium lies on the periphery of the inner surface of the side railing, mutual angular position all these walls in the plane of the horizontal section of the indicated section, as well as their width, are selected such that the radiation from the source light reflected by the inner surface of the first extended wall and successively reflected by the inner surfaces of the extended walls and the walls of the wedge-shaped region is directed by the inner surface of the first extended wall and the inner surface of the first wall of the wedge-shaped region toward the light source, while in the side enclosure there are walls in addition to these walls, which are grooves forming openings for the penetration of smoke into the smoke density optical density control section. 2. The smoke detector according to claim 1, characterized in that the side fence has an additional wall located outside relative to the first short wall of the wedge-shaped area and intersecting with it to form an additional wedge-shaped area on the periphery of the inner surface of the side fence, wherein in the horizontal section plane the section is a figure inscribed in a circle, and the inner surfaces of the first and second extended walls and the additional wall form the sides of the polygon, which s are segments of the chords of the circle. 3. The smoke detector according to claim 1 or 2, characterized in that in the cavity of the holder of the light source and in the subnet of the holder of the photodetector, respectively, there is at least one diaphragm.