RU85716U1 - SMOKE CAMERA FOR OPTICAL-ELECTRONIC FIRE SMOKE DETECTOR - Google Patents

Abstract

1. A smoke chamber containing vertical labyrinth partitions located along the perimeter of the side surface, characterized in that each of the vertical labyrinth partitions consists of two rounded plates — a first plate located on the outside and a second plate extending from the end of the first plate, convex sides which are directed outward, towards the smoke inlet, and concave - inward, towards the center of the smoke chamber, while the radius of curvature of the second plate is greater than the radius of curvature of the first plate. ! 2. The smoke chamber according to claim 1, characterized in that the labyrinth walls are located around the circumference of the smoke chamber. ! 3. The smoke chamber according to claim 2, characterized in that the labyrinth partitions are arranged at equal intervals around the circumference of the smoke chamber. ! 4. The smoke chamber according to claim 1, or 2, or 3, characterized in that the ratio of the radius of curvature of the second plate to the radius of curvature of the first plate is from 1.8 to 2.2. ! 5. The smoke chamber according to claim 4, characterized in that the ratio of the radius of curvature of the second plate to the radius of curvature of the first plate is 2.0. ! 6. The smoke chamber according to claim 1, characterized in that it is made with a protective cover. ! 7. The smoke chamber according to claim 1, characterized in that the flue plane is perpendicular to the horizontal air flow. ! 8. The smoke chamber according to claim 1, characterized in that it has a protective insect screen installed on its outer side. ! 9. The smoke chamber according to claim 6, characterized in that it has a protective insect screen placed in the lid of the smoke chamber. ! 10. Smoke chamber according to claim 8 or 9, characterized in that the insect protection mesh is made with a size

Description

The inventive utility model relates to the field of fire alarm, namely, smoke detection devices at an early stage of fire development at low smoke concentrations.

Known fire detectors with stray light contain fixed on the base of the housing with an optical camera containing a light source, a light detector, a measuring chamber. The optical camera is designed in such a way that interfering extraneous light cannot penetrate the measuring chamber, and smoke penetrates very easily. The light source and the light receiver are arranged so that the light rays from the light source to the receiver cannot be directly received. When smoke particles appear in the path of the rays, light from the source is scattered on them and part of this scattered light enters the light detector, resulting in an electrical signal.

To increase the protection against artificial and natural light sources, as well as to ensure uniform airflow from various horizontal directions, vertical labyrinth plates are installed around the chamber perimeter to exclude the influence of external light, difficulty in accessing dust and dirt particles into the smoke chamber, and at the same time time to provide easy access for horizontal air flow. Vertical labyrinth plates are made in such a way as to prevent direct light from entering the photodiode. In most detectors, they are made in the form of V-shaped plates. Sometimes more complex T-shaped plates are used. The use of V-shaped or T-shaped detectors of labyrinth plates in the design of smoke chambers reduces the aerodynamic properties of the smoke chamber due to the increased aerodynamic drag exerted by the air flow.

The practical use of scattered light fire smoke detectors with a cylindrical measuring chamber has shown that they can increase the frequency of false alarms as their life spans, and the reason for this is the deposition of dust particles in the smoke chamber, usually gray, simulating the presence of smoke particles. To eliminate the occurrence of such false alarms, the smoke chambers of the detectors must be periodically cleaned of dust. The preventive maintenance of the detector consists in disassembling it with the subsequent cleaning of the smoke chamber and its cover with a net. Following the sequence of preventive maintenance operations, the fire detector is disconnected from the outlet, the grid and the lid of the smoke chamber are subsequently cleaned of dust, then the smoke chamber and detector cover with a vacuum cleaner for one minute. These works are associated with significant labor costs. Therefore, when performing this type of work, the design of the detector for its disassembly and access to the smoke chamber for its cleaning from dust is of decisive importance.

All known types of smoke detectors are designed in such a way that access to the smoke chamber is possible only when carrying out a number of dismantling works using additional tools. Disassembling the detector consists in opening with the aid of a tool, as a rule, four latches connecting the housing and the detector cover. This work requires a great deal of accuracy and experience, since a slight additional effort when squeezing the latch with a tool can lead (and often leads) to a breakage of the latch made of plastic. At the same time, the latch cannot be repaired and the detector needs to be replaced with a new one.

Known smoke detector US 6,778,091 A, 08/17/2004, G08B 17/10, including a smoke chamber containing a housing with openings located in its upper plane, a light source and receiver mounted under the flat part of the housing, the optical axis of the emitter and light receiver pass through the holes, while lying in the same plane perpendicular to the upper flat part of the body, and intersect in the Central region of the smoke chamber, the cover of the smoke chamber includes many vertical reflective plates that form an external south wall of the smoke chamber, the shape of the reflective labyrinth plates is a V-shape to prevent external light from entering the smoke chamber. The labyrinth plates are arranged at equal intervals around the circumference of the smoke chamber. The smoke chamber cover has first and second locking elements that move smoothly over the entire surface of the protrusions or base of the chamber. The use of V-shaped labyrinth plates in this design reduces the aerodynamic properties of the smoke chamber due to the increased aerodynamic drag exerted on the air flow. The problem of disassembly complexity is also not solved in this technical solution.

As the closest analogue, a smoke chamber for a smoke detector RU 57491 U1, 10.10.2006, G08B 17/10 is adopted, which includes a housing, covers and circumferential side labyrinth plates, while the covers and side labyrinth plates are made of material having antistatic properties. This technical solution is aimed at reducing the complexity and maintenance cost of the smoke detector. However, the material used for the manufacture of covers and side labyrinth plates with antistatic properties, for example, from STAREX (USA), makes the smoke chamber more expensive. The presence of the bottom cover, made as a separate part, makes the device less technologically advanced both in manufacturing and during preventive maintenance.

The claimed utility model solves the problem of overcoming the above disadvantages of analogues.

The technical result of the claimed utility model is the creation of a reliable, inexpensive smoke detector with high sensitivity for detecting smoke in the early stages of a fire by creating a small-sized, technological one with improved aerodynamic properties of a smoke chamber, a detector with a high degree of protection against external light radiation, easy to manufacture and preventative maintenance .

The specified technical result is ensured by the fact that the smoke chamber contains vertical labyrinth partitions located along the perimeter of the side surface, characterized in that each of the vertical labyrinth partitions consists of two rounded plates — the first plate located on the outside and the second plate extending from the end of the first plates, the convex sides of which are directed outward, towards the smoke inlet, and the concave ones, inward, towards the center of the smoke chamber, while the radius of curvature of the second plate is greater less than the radius of curvature of the first plate. Labyrinth partitions are located around the circumference of the smoke chamber at equal intervals. The ratio of the radius of curvature of the second plate to the radius of curvature of the first plate is from 1.8 to 2.2, preferably 2.0. The side surface of the smoke chamber may have a cross section in the form of a circle. This option is preferred and disclosed below. However, there may be other embodiments of its lateral surface, its cross section may be oval, square, rectangular, polygonal, etc.

The smoke chamber is made with a protective cover. The chimney plane is perpendicular to the horizontal air flow.

The smoke chamber has a protective insect screen installed on the outside of its body or placed in the lid of the smoke chamber. The insect screen is made with a mesh size of 1 × 1 mm.

The smoke chamber is a monolithic part and is made by casting. The smoke chamber is made of matte black plastic with corrugated surfaces on its bottom and / or protective cover.

Figure 1 presents the view of the fire smoke detector in section at an angle of 135 °. Figure 2 presents the view of the fire smoke detector in section at an angle of 180 °. Figure 3 presents a top view of the smoke chamber indicating the location of the light emitter and the light receiver. Figure 4 presents a fragment of the drawing design of the labyrinth walls (plates) of the smoke chamber. Figure 5 presents the cover of the smoke chamber of the smoke detector. Figure 6 presents the protective mesh. Figure 7 presents a General view of the smoke chamber. On Fig presents a self-locking lock with which to connect the housing and the cover of the detector. Figure 9 presents a top view of the smoke chamber indicating the latches for connecting the smoke chamber to the electronic circuit board.

The smoke smoke detector comprises a housing 1 with a cover 2. Inside the housing 1 with a cover 2, a smoke chamber 7 with a cover 8 is installed using latches 10.

The smoke chamber 7 is a housing (Fig. 3 and Fig. 7), in the side wall of which vertical labyrinth partitions 15 are made in the form of plates arranged at equal intervals along the perimeter of the side surface of the smoke chamber 7, and four latches 10 for attaching the electronic board 3 With their help, a smoke chamber is mounted with an electronic board for installation inside the housing. Similar latches (not shown) has a detector housing 1 for connecting to a smoke chamber together with an electronic circuit board. The smoke chamber 7 with vertical labyrinth walls 15 and four latches is a monolithic part and is made by injection molding of black plastic. The smoke chamber (housing) is made two-level. The first level begins with the internal corrugated surface of the protective cover 8 of the smoke chamber 7 and is limited by the height of the labyrinth walls 15. If the smoke chamber is made without a cover, the first level of the smoke chamber is limited by the height of the labyrinth walls.

Here, the height of the labyrinth partitions 15 is understood to mean that part of them that is located at the level of the smoke inlet. At the same time, the upper edges of the labyrinth partitions fit snugly against the inside of the protective cover 8 of the smoke chamber 7. The smoke exhaust is located at this first (upper) level of the smoke chamber 7 and is covered by an insect net 9. The second level of the smoke chamber 7 is limited by the corrugated bottom of the smoke chamber and the lower part of the partitions 15, that is, part of the partitions to the level of the smoke inlet. There are no labyrinth partitions in the second level of the smoke chamber. A light emitter 4 and a light detector 5 are located in the second level of the smoke chamber.

The protective cover 8 (figure 5) of the smoke chamber 7 is also an independent part of the fire smoke detector. The upper flat part of the protective cover (usually made with a diameter of 55 mm) is connected to its lower part, in the form of a ring, with six thin ribs. On the inside, the protective cover has a corrugated surface to reduce the background light signal inside the smoke chamber when it is filled with smoke and dust accumulates. The protective cover of the smoke chamber is made of black plastic by injection molding in a specially made mold. On the inner side of the protective cover close to the ribs is installed a protective mesh 9 (Fig.6) to protect against insects. Its width is usually 8 mm and is equal to the height of the first level of the smoke chamber.

Each of the vertical labyrinth partitions 15 consists of two rounded plates, the convex sides of which are directed outward, and the concave sides inward, to the center of the detector. Thus, each of the two mentioned plates in the plan (figure 3, 4) represents a part of a circle (arc). The first plate, located on the outside (from the smoke inlet side), has a radius of curvature R2. A second plate (located closer to the center of the detector) departs from its end, which has a radius of curvature R1. The radius of curvature of the second plate R1 is greater than the radius of curvature of the first plate R2. The ratio of R1 / R2 is in the range of 1.8-2.2, preferably 2.0.

To the bottom of the smoke chamber 7, using its latches 10, an electronic board 3 is attached with a light emitter 4 installed on it (it can be made, for example, in the form of an infrared LED) and a light receiver 5 (it can be made, for example, in the form of a photodiode) such so that the light emitter 4 and the light receiver 5 are placed inside the smoke chamber 7. The terminals of the light detector 5 are closed externally by a metal screen 6. The light emitter 4 and the light receiver 5 are located relative to each other so that the angle formed by By cutting off the optical axes of the light emitter and the light detector, it is in the range 130-140 degrees, preferably 135 °.

The electronic board 3 is connected to the contact current collectors of the housing 1 (not shown). At the same time, the electronic board 3 is in electrical contact with the contact pads (current collectors) 11 located on the housing 1, which are connected to the contact pads (current collectors) of the socket 12 (not shown), making it possible to connect the detector to the fire alarm loop.

The socket 12 is attached from below to the housing 1. The detector status indication (standby mode or “Fire” mode) is determined by the glow of the LED 13 indicating the status mode installed on the electronic board with the LED housing in the round hole of the cover 2 of the housing 1.

The housing 1 and the cover 2 of the housing are interconnected by using self-locking locks 14 (Fig. 8). The optimal number of such locks is three. With such a number of locks, the necessary detector rigidity and ease of disassembly are ensured. Each lock consists of a latch 16, which is an elastic hook made on the lid and a shoulder 17 made on the housing, the hook being able to engage with a shoulder for locking the lock, and a button 18 located in the housing. When pressed, the button 18 pushes the hook 16, as a result of which it disengages from the shoulder 17. The lock buttons have a limited stroke H2 equal to the meshing value of the lock H1. The engagement length of the latch H1 is shorter than the stroke of the H2 button by 1-1.5 mm.

The detector is disassembled by simultaneously pressing three buttons 18 of self-locking locks without the use of an additional tool. After pressing the lock buttons 18 with 14 fingers, the housing 1 and the detector cover 2 are separated from each other, providing access for preventive maintenance to clean the smoke chamber 7 and its cover 8 from dust, and, if necessary, repair work of the electronic board 3. Detector assembly after the completion of preventive work is carried out by connecting its body 1 and cover 2 in the position of the correct alignment of the guides to close the self-locking locks 14.

The buttons of the locks 14 have a limited stroke H2 equal to the amount of engagement of the lock H1 (that is, equal to the engaging part of the hook), so even applying considerable force when pressing the buttons of the lock 14 cannot cause it to break. With this design, the detector disassembly (without the use of additional tools) dramatically reduces the cost of operating costs for its maintenance and repair without the risk of damage to its structural elements.

The performance of the claimed device is confirmed by tests of the developed sample.

The detector housing 1 has a horizontal smoke inlet. A protective insect screen with mesh sizes less than 1 × 1 mm is placed in the protective cover 8 of the smoke chamber 7. A round smoke chamber in the horizontal plane provides equally high sensitivity when smoke comes from any direction. The complex shape of the plates 15 located along its perimeter, provides protection from external light and good blowability. To reduce the background signal from natural and artificial lighting, the smoke chamber is made of matte black plastic, with rugged surfaces on the bottom and the lid of the chamber (Figure 3), which, compared with flat surfaces, further reduces the level of the reflected signal, since only protruding parts. The inner surface of the camera, from which radiation is reflected towards the photodiode, slightly increases the background signal when dust appears. The detector has a good ratio of the area of the smoke inlet to the internal volume of the smoke chamber equal to 1.6 cm ^-1 .

The height of the insect screen is equal to the height of the first level of the smoke chamber, which ensures the maximum smoke area.

Separate structural elements (three chimney sections - not shown) of the detector cover form funnels that direct air flow into the detector. Good ventilation of the smoke chamber determines its low inertia. The chimney plane is perpendicular to the horizontal air flow. Racks of fastening of the bottom cover exclude flow around the detector in a horizontal plane.

The device operates as follows.

A smoke detector can detect a fire hazard only when a certain concentration of smoke appears in it. The time it takes to fill the smoke of the detector’s smoke chamber primarily depends on the aerodynamic properties of the smoke detector design of the fire detector, protective structural elements, structure of the smoke chamber, etc. The design of the proposed smoke point fire detector is primarily designed for horizontal air flows of low concentration, since at a sufficiently high concentration of smoke, all fire detectors behave approximately the same. The concentration of smoke generated in the smoke chamber is largely dependent on the aerodynamic drag created by the labyrinth walls.

Unlike most existing smoke chambers with V-, T- and other types of labyrinth walls installed along the perimeter of the smoke chamber, they are convex in the inventive detector.

When smoke spreads in a horizontal plane, it passes through the smoke detector sections of the detector and passes into the target between the partitions, flowing around the surface of the labyrinth partitions first with a radius of R2 and then with a radius of R1 (the first plate with radius R2 is located on the outside, and the second plate with radius R1 is located on the inside of the smoke chamber). It enters the smoke chamber as a swirling stream of smoke particles. The radii of the labyrinth partitions are selected experimentally so as to provide a detector sensitivity of 0.05 dB / m at a low concentration and speed of smoke propagation and, at the same time, to provide, possibly, the minimum light background in the smoke chamber from sources of natural and artificial lighting at a strictly defined angle а = 135 degrees of location in space of light and photodiodes. The best results were obtained in the manufacture of a smoke chamber with a ratio of R1 / R2 = 2. Smoke particles passing into the target between adjacent partitions additionally twist adjacent layers of smoke in the same direction. In this case, a swirling stream of smoke particles forms in the smoke chamber. Such a state of smoke in the optical chamber increases the specific optical density of the medium to a sensitivity of 0.05 dB / m, which at an early stage of the development of a fire at low smoke concentrations allows the activation of a fire smoke detector.

From the aerodynamic properties of the movement of gases, it follows that they experience less aerodynamic drag when propagating along complex surfaces (surfaces with a sharp change in direction of movement) with elements of spherical shapes, in contrast to surfaces of other types. The shape of the labyrinth plates located along the perimeter of the smoke chamber in the form of biconvex surfaces allows to reduce the aerodynamic resistance to the air flow, to ensure good blowability of the detector and to protect the smoke chamber from external light.

In the detector, as in most fire, smoke optoelectronic fire smoke detectors, the effect of diffuse scattering of LED radiation on smoke particles is used. The LED is positioned in such a way as to prevent direct radiation from entering the photodiode. When smoke particles appear, part of the radiation is reflected from them and gets on the photodiode. Here diffuse scattering is observed, which, unlike specular scattering, has a wide directivity. To protect the optocoupler from external light, the LED 4 and the photodiode 5 are placed directly in the smoke chamber 7, which is installed in the housing 1 of the smoke detector.

When a room ignites, smoke enters the smoke chamber 7. Light pulses emitted from the infrared LED 4, reflected from the smoke particles, enter the photodiode 5, generating an electrical signal that is processed by the electronic circuit board 3 and enters the fire alarm system as a fire signal.

The advantage of the inventive detector over analogues is to increase the aerodynamic characteristics of its smoke chamber. Improving manufacturability, maintainability and reducing labor costs during operational and preventive maintenance.

Although the present disclosure has been described with reference to this embodiment, it will be understood by those skilled in the art that other embodiments of the claimed utility model may occur within the scope of the attached utility model formula.

Claims (12)

1. A smoke chamber containing vertical labyrinth partitions located along the perimeter of the side surface, characterized in that each of the vertical labyrinth partitions consists of two rounded plates — a first plate located on the outside and a second plate extending from the end of the first plate, convex sides which are directed outward, towards the smoke inlet, and concave - inward, towards the center of the smoke chamber, while the radius of curvature of the second plate is greater than the radius of curvature of the first plate. 2. The smoke chamber according to claim 1, characterized in that the labyrinth walls are located around the circumference of the smoke chamber. 3. The smoke chamber according to claim 2, characterized in that the labyrinth partitions are arranged at equal intervals around the circumference of the smoke chamber. 4. The smoke chamber according to claim 1, or 2, or 3, characterized in that the ratio of the radius of curvature of the second plate to the radius of curvature of the first plate is from 1.8 to 2.2. 5. The smoke chamber according to claim 4, characterized in that the ratio of the radius of curvature of the second plate to the radius of curvature of the first plate is 2.0. 6. The smoke chamber according to claim 1, characterized in that it is made with a protective cover. 7. The smoke chamber according to claim 1, characterized in that the flue plane is perpendicular to the horizontal air flow. 8. The smoke chamber according to claim 1, characterized in that it has a protective insect screen installed on its outer side. 9. The smoke chamber according to claim 6, characterized in that it has a protective insect screen placed in the lid of the smoke chamber. 10. Smoke chamber according to claim 8 or 9, characterized in that the insect screen is made with mesh sizes of 1 × 1 mm. 11. The smoke chamber according to claim 1, characterized in that it is a monolithic part and is made by casting. 12. The smoke chamber according to claim 1, or 6, or 11, characterized in that it is made of matte black plastic with corrugated surfaces at its bottom and / or protective cover.