DE2134563A1 - Smoke detector for the optical detection of aerosols generated by combustion - Google Patents

Description

The invention relates to a smoke detector with which aerosols can be determined optically that are generated by combustion and which has a light source and a light-sensitive and smoke-indicating device so arranged is that the light rays from the light source are dependent on | migrate from the concentration of the aerosols to the display device. The smoke detector according to the invention is suitable as a fire alarm.

In known devices of this type, a photosensitive Element used, which is arranged outside the path of a light beam falling through a measuring chamber, the is shielded from external light. The light rays can only reach the photosensitive element if they pass through Reflection or dispersion are deflected.

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The aerosols generated during fires penetrate the measuring chamber and create the so-called Tyndall effect, "at which the light beam is scattered. The photosensitive element is then only reached by those light rays that have experienced the required deflection.

The brightness of the scattered light beam decreases very rapidly with the angle of deflection. Will be the photosensitive element arranged in such a way that the light beam only needs to be deflected a little, only a very small proportion of the the entire amount of light of the light beam is used, and the shielding against direct light becomes very difficult.

The main purpose of the invention is a better utilization of the available amount of light, so that a high fire alarm sensitivity is achieved, wherein the photosensitive element is shielded from direct light so that the scattered light rays Reach the photosensitive element without distraction can. The features of the invention are in the characterizing part of the accompanying claim 1 cited.

The device according to the invention should also offer satisfactory protection against a false fire alarm. This is made possible according to the invention in that the alarm is not triggered by an absolute aerosol concentration level but rather as a function of the extent of the change in aerosol. oil concentration. The this part of the invention pertains L 'ck times are indicated in the claim. 2

The invention will now be described in detail. In <ier The drawing is enclosed

Pig.1 a representation of a serving the stated purpose known arrangement,

Pig. 2 a representation of the Tyndall effect,

Pig. 3 an illustration of an embodiment of the invention,

Pig. 4 an illustration of another embodiment of the invention,

Pig.5 is a circuit diagram for the electrical device of the invention Smoke detector.

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The device according to the invention has one against the light Chamber 1 shielded from the environment with ventilation slots through which the ambient air can flow into the chamber. A light source 3 is attached to one of the "walls of the chamber 1, the light of which from a lens 4 becomes a light beam is bundled, which is directed against the opposite wall of the chamber. Is out of the path of the light beam a photosensitive member 5 is arranged.

In the event of a fire, aerosols are generated which penetrate the measuring chamber 1 and scatter the light beam. The light-sensitive element is then only reached by those light beams which have experienced the required deflection. At a sufficiently high concentration of the aerosol is a fire alarm from an external electric g means into which the light-sensitive element 5 is turned on, tripped.

Pig. 2 shows the dispersion by means of polar coordinates of a light beam as a result of the Tyndall effect. From this is it can be seen that the brightness B decreases rapidly with the deflection angle delta of the light rays. When arranging according to In FIG. 1, only a very small proportion of the total amount of light can therefore reach the photosensitive element 5.

In Figure 3 is an embodiment of an inventive Smoke detector shown with a cylindrical chamber 1, which is impermeable to the light from the environment and is provided with ventilation slots 2 through which the ambient air is J can flow. A light source 3 is arranged in the chamber 1, the power of which is bundled by a lens 4 to form a light beam is · In the path of the light beam two polarization filters 6 and 7 are arranged one behind the other, the polarization axes of which are perpendicular to each other, so that the light beam after the polarization through the filter 6, the filter 7 can normally no longer penetrate.

In the event of a fire, the aerosols generated in this way penetrate through the ventilation slots 2 into the chamber, with the Tyndall effect causes the light beam to change the polarization caused by the filter 6 depending on the concentration of the aerosols

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partially loses and contains depolarized light rays that fall through the filter 7 and from a lens 8 onto the photosensitive element 5 are aligned. When a critical aerosol concentration is exceeded Threshold value, a fire alarm is triggered by an external circuit containing the light-sensitive element.

The light source 1 can consist of a glow lamp, a halogen lamp, a gas discharge lamp, a light emitting diode or another known light source. That generated light can be constant or fluctuating. The light sensitive Element 5 can be photoconductive or photoelectric.

4 shows another embodiment of the smoke detector according to the invention.

Two cylindrical tubes are concentrically arranged to form an outer chamber 11 and an inner chamber 12. The Außenkamraer 11 is on the ventilation slots 2 with the Ambient air in connection and is equipped with a light source 3, the light from a lens 4 to a light beam is bundled. The inner chamber 12 is closed off by two polarization filters 6 and 7, one behind the other in the path of the light beam are arranged such that their polarization axes are perpendicular to one another. The light can after the polarization brought about by the filter 6, it normally no longer penetrates the filter 7. The core of the light beam travels through the inner chamber 12, while the outer part of the light beam travels through the outer chamber 11. the Ventilation slots 9 allow the air between the chambers can flow through.

The ambient air contains aerosols that have penetrated through the ventilation slots 2 and 9 into the chambers 11 and 12 and are evenly distributed, the light beam contains depolarized light which passes through the filter 7 and from a lens 8 is thrown onto two circular and concentrically arranged light-sensitive elements 51 and 52, the Element 51 the light from the outer chamber 11 and the element

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receives only the light from the inner chamber 12.

Da "the concentration of the aerosols generated in a fire rises rapidly in the ambient air, the aerosols penetrate into the chamber 11 faster than into the chamber 12, so that the relevant absolute concentration level of the aerosols in the two chambers are briefly unequal. Light therefore also falls on the two light-sensitive elements 51 and 52 different brightness. One on elements 51 and 52 The connected external comparison circuit determines the difference between the various brightnesses and resolves if it is exceeded a fire alarm.

The Pig.5 shows the manner in which the two light-sensitive Elemaite _ä eingeschal- in a comparison circuit 51 and 52 are tet, which consists of a bridge circuit 13, whose output is balanced ™ 14 when the elements receive 51 and 52 light with the same brightness . The output of the bridge circuit 13 can be routed in a known manner to an amplifier which, if an imbalance occurs, feeds the output voltage of the bridge circuit 13 to a relay which triggers the fire alarm.

The invention is not restricted to the two embodiments described above. For example, the two chambers 11 and 12 are designed as mutually independent chambers, provided that they have a different air exchange with the ambient air.

Claims

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Claims (6)

Claims Smoke detector for the optical detection of fire generated aerosols with a light source (3) and with a light-sensitive smoke-indicating device (5), the so is arranged that the light rays from the light source depending on the concentration of the aerosols on the Display device covered, characterized in that the light beams through at least two polarization filters (6, 7), the polarization axes of which are offset with respect to one another in such a way that the light rays can penetrate normally prevented up to the display device, but is made possible in the presence of aerosols, that the polarization caused by the light rays is influenced by the concentration of the aerosols. 2. Smoke detector »oh claim 1, characterized in that that the display device is in the path of the light beam is arranged. 3. Smoke detector according to claim 2, characterized in that that the light from the light source is bundled by a first lens (4) to form a light beam that passes through the polarization filter is directed, and that a second lens (8) directs those light beams onto the display device, which emerge from the polarization filters. 4. Smoke detector according to claim 1, characterized in that two chambers next to each other in the path of the light beams (11, 12) are arranged, of which one chamber (11) a rapid and the other chamber (12) a slow influx of aerosols from the ambient air allows that the display device consists of two light-sensitive elements (51 »52) which are arranged so that one Element (51) mainly those rays of light 109885/1256 that fall through the former chamber (11), while the other element (52) mainly receives those Receives rays of light passing through the latter chamber (12) fall, and that the two photosensitive elements are switched into a comparison circuit. 5. Smoke detector according to claim 4 »characterized in that that said two chambers are formed by two cylindrical and concentrically arranged tubes, and that the said two light-sensitive elements are circular and. are arranged concentrically. 6. Smoke detector according to claim 4-, characterized in that said comparison circuit consists of a bridge ™ circuit (13) with which the two light-sensitive Elements are connected in such a way that the bridge circuit is in equilibrium at the output (14) when the Aerosols in the two chambers have the same concentration. 109885/1256 Blank page