The present invention relates to a fire detector according to the definition of the species in Claim 1 and an operating method for a fire detector of this type according to the definition of the species in Claim 11.
An optical fire detector, including a radiation transmitter and a radiation receiver, which manages without an optical labyrinth and may thus be installed flush in a ceiling, is known from DE 199 12 911 C2. Furthermore, the fire detector includes a system, using which soiling of the transparent cover plate of the fire detector may be recognized and, in addition, it may be monitored whether the radiation transmitter and radiation receiver of the fire detector provided for recognizing smoke still operate correctly. The known fire detector has the disadvantage that in addition to the radiation transmitter and radiation receiver provided for recognizing smoke, further radiation transmitters and radiation receivers are necessary for recognizing soiling and for function checking. Overall, at least three radiation transmitters and three radiation receivers are thus necessary.
A fire detector having a system, using which it is possible to differentiate between smoke and other foreign bodies in the scattering volume, is known from DE 100 46 992 C1. A significant complexity is also necessary in this known fire detector for differentiating between smoke and other foreign bodies, which makes manufacturing of a fire detector of this type more expensive.
The present invention discloses a fire detector which includes manifold functions and is distinguished by particularly high operational reliability in spite of a reduced complexity. The objects described in both of the publications cited with regard to the related art are achieved simultaneously using only three radiation transmitters and three radiation receivers in this case. Because at least one of multiple scattering volumes includes at least a partial area of a cover plate that terminates the fire detector, soiling of the cover plate may be recognized reliably. Through selective controllability of the radiation transmitters and radiation receivers using a microcomputer, the reliability performance of the radiation transmitters and radiation receivers of the fire detector may be checked easily. Furthermore, it is possible to differentiate between smoke and objects in front of the fire detector. By analyzing the scattered radiation measured values of scattering volumes which have different distances from the cover plate, the fire detector designed according to the present invention may differentiate various types of smoke from one another and therefore also better differentiate between signals originating from smoke and interference. Through comparison of scattered light measured values obtained at different instants, changes in the ambient temperature or aging effects may be recognized reliably and compensated for using appropriate correction factors. Finally, the disclosed fire detector also displays an even lower sensitivity to interfering radiation.
Exemplary embodiments of the present invention will be described in greater detail in the following with reference to the drawing.
A first exemplary embodiment of a fire detector 1 according to the present invention is shown in
Radiation transmitters 5.1, 5.2, 5.3 and radiation receivers 6.1, 6.2, 6.3 are situated in this case in such a way that their beam paths result in three different scattering volumes 7.1, 7.2, 7.3. First scattering volume 7.1 is formed by the beam paths of radiation transmitter 5.1 and radiation receiver 6.1. Second scattering volume 7.2 is formed by the beam paths of radiation transmitter 5.2 and radiation receiver 6.2. Third scattering volume 7.3 is formed by the beam paths of radiation transmitter 5.3 and radiation receiver 6.3. Radiation transmitter 5.1 and radiation receiver 6.1 are oriented in such a way that scattering volume 7.1, in which this system responds sensitively to smoke particles, is located several centimeters below cover plate 4 of fire detector 1, which is transparent to infrared light. Scattering volume 7.2 formed by the beam paths of radiation transmitter 5.2 and radiation receiver 6.2 may also be situated at a distance of several centimeters from cover plate 4. Alternatively, radiation transmitter 5.2 and radiation receiver 6.2 may also be oriented in such a way that scattering volume 7.2 has a larger or smaller distance from cover plate 4, however. Scattering volumes 7.1 and 7.2 are situated in this case in such a way that they do not overlap, but rather preferably are at a distance of several centimeters. Furthermore, radiation transmitter 5.2 and radiation receiver 6.2 are situated rotated by 180° in relation to radiation transmitter 5.1 and radiation receiver 6.1.
In addition, radiation transmitter 5.3 and radiation receiver 6.3 are oriented in such a way that scattering volume 7.3 formed by their beam paths includes at least a partial area of the surface of cover plate 4.
A block diagram of fire detector 1 shown in
Radiation transmitters 5.1, 5.2, 5.3 are controllable individually by microcomputer 9. Since switching means 11 is also controllable by microcomputer 9, radiation transmitters 5.1, 5.2, 5.3 and radiation receivers 6.1, 6.2, 6.3 may be activated in any arbitrary predefinable combinations to jointly form scattering volumes.
The mode of operation of fire detector 1 according to the present invention is described below.
The following functions may be implemented as a function of which radiation transmitters 5.1, 5.2, 5.3 are controlled by microcomputer 9 and of which radiation receivers 6.1, 6.2, 6.3 are connected by switching means 11 to electronic circuit system 8 at the instant at which radiation transmitters 5.1, 5.2, 5.3 emit radiation.
It is assumed that radiation is emitted by radiation transmitter 5.1 and received by radiation receiver 6.1 or radiation is emitted by radiation transmitter 5.2 and received by radiation receiver 6.2. In this case, the smoke density may be measured in scattering volume 7.1 and/or in scattering volume 7.2, which are located at a distance of several centimeters from the surface of cover plate 4. In the measurement using radiation transmitter 5.1 and radiation receiver 6.1, i.e., using scattering volume 7.1, a scattered radiation measured value S11 is obtained. In the measurement using radiation transmitter 5.2 and radiation receiver 6.2, i.e., using scattering volume 7.2, a scattered radiation measured value S22 is obtained. By comparing scattered radiation measured values S11 and S22, one may advantageously differentiate whether an interfering object, such as an insect 10 (
In the following, it is assumed that radiation transmitter 5.3 and radiation receiver 6.3 are activated. Since scattering volume 7.3 formed by the beam paths of radiation transmitter 5.3 and radiation receiver 6.3 encloses a partial area of the surface of cover plate 4, radiation of radiation transmitter 5.3 is reflected on cover plate 4 and thus reaches radiation receiver 6.3, which provides a scattered radiation measured value S33. Even if there is no dirt on cover plate 4, a certain part of the radiation emitted by radiation transmitter 5.3 will be reflected by cover plate 4 to radiation receiver 6.3 as a function of the angle of incidence of the radiation on cover plate 4. The intensity of radiation transmitter 5.3 may expediently be set in such a way that the idle signal of scattered radiation measured value S33 thus arising assumes a predefinable value. In contrast, if there is dirt in the area of scattering volume 7.3 on cover plate 4, additional radiation is reflected by the dirt, so that scattered radiation measured value S33 measured at radiation receiver 6.3 assumes a higher value. In this way, soiling of cover plate 4 may be recognized reliably.
A change in the ambient temperature or aging of radiation transmitter 5.3 may result in the idle signal of scattered radiation measured value S33 falling below its starting value. By calculating ratios between the original and the current idle signal, a correction factor KF may be derived in order to compensate for the intensity change of radiation transmitter 5.3. This is expediently performed by applying a current corrected by correction factor KF to radiation transmitter 5.3. Furthermore, a defect in radiation transmitter 5.3, radiation receiver 6.3, or electronic circuit system 8 may be recognized in that scattered radiation measured value S33x assumes a no longer measurable value. In order to guarantee a high operational reliability of the fire detector and reliably counteract gradual aging effects, a limiting value G is expediently predefined for scattered radiation measured value S33x. A value below this limiting value G is reported as a defect in fire detector 1.
In the following, it is assumed that radiation is emitted by radiation transmitter 5.1 and received by radiation receiver 6.2 or that radiation is emitted by radiation transmitter 5.2 and received by radiation receiver 6.1. As shown in
It is a further advantage of fire detector 1 according to the present invention that two further independent scattering volumes 7.4, 7.5 result through the rotation of radiation transmitters 5.1, 5.2 by 180°. The orientation of radiation transmitters 5.1, 5.2 and radiation receivers 6.1, 6.2 may, for example, be selected so that scattering volumes 7.4, 7.5 formed by them have a greater distance from cover plate 4 of fire detector 1 than scattering volumes 7.1 and 7.2. A smaller scattering angle thus results for scattering volumes 7.4, 7.5 than for scattering volumes 7.1 and 7.2. By comparing scattered radiation measured values S12 and S21 to scattered radiation measured values S1 and S22, the following additional information may advantageously be obtained. It may not only be recognized whether smoke is located in front of fire detector 1 at all. Rather, it may additionally be determined what type of smoke or fire it is. Since, if a smaller scattering angle is predefined, generally less radiation is scattered than in the case of a large scattering angle, scattered radiation measured values S12 and S21 will typically be smaller than scattered radiation measured values S11 and S22 if smoke is present in front of fire detector 1. The reduction of the intensity of the scattered radiation as a function of the scattering angle is strongly dependent on the type of smoke, in particular on the size of the smoke particles and the color of the smoke. Therefore, by calculating quotients S12/S11, S21/S11, S12/S22, and S21/S22, it may be determined what type of smoke it is. This information may be used for the purpose of better differentiating between dangerous fire smoke and rather harmless disturbance variables, such as water vapor or dust. Furthermore, it may be recognized whether an object is located in front of fire detector 1 and at what distance. For example, if scattered radiation measured values S11, S12, S12, and S21 are approximately of the same magnitude, then this indicates that an object is located in front of fire detector 1. If the object is located at a greater distance from fire detector 1, scattered radiation measured values S12 and S21 which are much larger than scattered radiation measured values S11 and S22 result.
In the following, it is assumed that radiation is emitted by radiation transmitter 5.3 and received by radiation receiver 6.2 or radiation is transmitted by radiation transmitter 5.3 and received by radiation receiver 6.1 or radiation is transmitted by radiation transmitter 5.2 and received by radiation receiver 6.3.
As shown in
Number | Date | Country | Kind |
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10 2004 001 699.2 | Jan 2004 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP2004/053047 | 11/23/2004 | WO | 00 | 7/13/2006 |