EP2759994A2 - Fire alarm - Google Patents

Abstract

The fire alarm (1) has a sensor system (2) acquiring fire-specific measurement values, and an evaluation unit (3) for detection of fire on basis of the fire-specific measurement values. A positioning device (4) i.e. rotary switch, is provided for manual adjustment of evaluation sensitivity of the fire alarm. The positioning device is arranged in housing of the fire alarm. The evaluation sensitivity is more adjustable in three sensitivity stages. The sensor system includes sensors, which are activated with three sensitivity stages.

Description

State of the art

The invention relates to a fire detector for detecting a fire, having a sensor system for detecting fire-specific measured values, having an evaluation unit for detecting the fire on the basis of the fire-specific measured values and an adjusting device which is designed for manually setting the evaluation sensitivity of the fire detector, wherein the setting device is arranged in or on the fire detector.

Fire detectors are used to detect fires and to trigger an alarm in the event of a detected fire. For the detection of the brand certain characteristics, such. Temperature or density of smoke particles. The measurement data acquired by sensors are transmitted to a control device which determines an alarm triggering on the basis of the transmitted measurement data. The installation of fire alarms is increasingly being carried out in private households in order to minimize the risk of housing fire.

The publication JP 2007 280 326 A , which is probably the closest prior art discloses a fire detector with a switch. An operator can use the switch to switch between high and low sensitivity of the fire detector. By switching to high or low sensitivity, the switch allows the fire detector to be set for early or late fire detection.

Disclosure of the invention

In the context of the invention, a fire detector with the features of claim 1 is disclosed. Preferred or advantageous embodiments of the invention will become apparent from the dependent claims, the following description and the accompanying drawings.

The invention thus relates to a fire detector for detecting a fire. The fire detector is intended in particular for arrangement in a private household. Particularly preferably, the arrangement of the fire alarm takes place in a closed room of the private household, such. As kitchen, bedroom, living room, basement, workshop, office, bathroom or in a semi-closed room, such. B. hallway or garage. The fire detector can be arranged for example on a wall or on a ceiling of a room. Preferably, the fire detector has a design with a diameter smaller than 20 cm or a surface portion smaller than 20 cm ² , wherein the surface portion z. B. forms the wall or ceiling to be arranged portion. Optionally, the fire detector includes a siren for issuing an acoustic fire warning.

The fire detector includes a sensor system for recording brand-specific measured values. The brand-specific measured values are z. Example, a smoke particle concentration, a fire gas concentration, an ambient humidity and / or an ambient temperature of the fire detector in the room in which the fire alarm is arranged.

The fire detector has an evaluation unit for detecting the fire on the basis of the fire-specific measured values. The sensor system is coupled to the evaluation unit in order to transmit the brand-specific measured values recorded by the sensor system. For example, the evaluation unit is designed to output an alarm in the detection of a fire. Particularly preferably, the optical fire detector comprises a control device, which is designed to trigger the alarm when the evaluation unit has detected the fire.

In particular, the fire detector comprises a housing in which the sensor system and the evaluation unit are arranged. Particularly preferably, the housing a measuring chamber in which the sensor system is arranged or measures for the acquisition of the brand-specific measured values.

The fire detector comprises an adjusting device, which is designed for manually setting the evaluation sensitivity of the fire detector, in particular the evaluation unit on the fire detector. In particular, the evaluation sensitivity defines a triggering limit of an alarm for signaling a fire. Particularly preferably, the alarm is output the earlier, the higher the evaluation sensitivity is set. The adjusting device is coupled to the fire detector, in particular to the evaluation unit, in order to transmit the evaluation sensitivity set by the user to the evaluation unit. The adjusting device is arranged in or on the fire detector and in particular forms an integrated part of the fire detector. The arrangement of the control device on the fire detector advantageously allows a direct and quick setting of the desired evaluation sensitivity by a user.

In the context of the invention, it is proposed that the evaluation sensitivity of the fire detector can be set in at least three sensitivity levels. In particular, the evaluation sensitivity is adapted to one of the sensitivity levels when the control device is switched over, in particular up or stepped down.

In a private household, due to the different usage characteristics, there are usually different environmental parameters in the rooms, which influence the detection of a fire. To form in the kitchen z. As water vapor or smoke during cooking environment parameters that can be detected by the sensors and identified by the evaluation as a fire. In the bedroom, on the other hand, there are usually hardly any environmental parameters that influence the detection of a fire. Due to the widely varying environmental parameters in the rooms, the risk of a false alarm or a low level of sensitivity may present a risk of late fire detection at a high sensitivity level. Thus, an advantage of the gradual adjustment of the evaluation sensitivity is the possibility of individual adaptation of the fire detector to the specific Environmental parameters of a room. The at least three sensitivity levels thus result in a reduction of false alarms or a more reliable or earlier decision for a real alarm.

In a preferred embodiment, the evaluation sensitivity is defined by at least one limit value of the recorded fire-specific measured values, which is used to detect a fire with the fire-specific measured values z. B. is compared or set in correlation. In particular, the at least one limit value defines the triggering limit of the evaluation unit for detecting the fire. Preferably, in each case one of the at least three sensitivity levels is assigned a limit value, the limit values being selected to be different from one another such that the at least three sensitivity levels have different evaluation sensitivities. Particularly preferably, an evaluation of a fire takes place when the sensor system detects a fire-specific measured value which exceeds or falls below the limit value, the limit value being determined by the selected sensitivity level.

The recorded brand-specific measured values are evaluated, for example, as absolute values. Alternatively, the fire-specific measured values are evaluated by relative measurement as relative values by detecting the change between two fire-specific measured values. As a further alternative, the evaluation z. By a correlation value of the brand-specific measured values. For example, an alarm is issued as the combustion gas and smoke particle concentration increase. The detection of a fire is z. Example by comparing the limit value with the absolute values, with the relative values and / or with the correlation values.

In one possible embodiment of the invention, the sensor system comprises exactly one sensor, wherein the sensor z. B. as an optical sensor, as a thermal sensor, as a moisture or as a gas sensor is formed.

In the optical sensor, the smoke particle concentration is detected according to the scattered light principle. In particular, the optical sensor comprises a light emitter and a light receiver, which in a measuring chamber are arranged angled to each other. If smoke particles are present in the measuring chamber, the light emitted by the light emitter is scattered to the light receiver, with the light intensity scattered to the light receiver forming the fire-specific measured value. Should the light receiver receive a light intensity which is greater than a reference light intensity, the reference light intensity being determined as a limit value by the sensitivity level, this indicates a fire. In the thermal sensor, the ambient temperature of the fire detector is detected in the arranged space, wherein the detected ambient temperature forms the fire-specific measured value. If the thermal sensor detects an ambient temperature that is greater than a reference temperature, with the reference temperature as the limit set by the sensitivity level, this indicates a fire. In the humidity sensor, the ambient humidity of the fire detector is detected in the arranged space, wherein the ambient humidity forms the fire-specific measured value. If the humidity sensor senses an ambient humidity that is less than a reference humidity, with the reference humidity threshold set by the sensitivity level, this indicates a fire. In the gas sensor, a combustion gas concentration is detected on the basis of an evaluated attenuation of a light beam, the combustion gas concentration forming the fire-specific measured value. The detection of the fire gas concentration is dependent on the light intensity of the light beam received by a light receiver. A decrease in the light intensity occurs during absorption or scattering of the light beam by fire gases. Should the light receiver receive a light intensity which is less than a reference light intensity, the reference light intensity being determined as a limit value by the sensitivity level, this indicates a fire gas and consequently a fire.

In a particularly preferred embodiment, the sensor system comprises a plurality of sensors. For example, the plurality of sensors comprises at least one optical, one thermal, one moisture and / or one gas sensor, in particular as described above. For example, the plurality of sensors by a single sensor type, for. B. formed by a plurality of optical sensors. However, it is particularly preferred that the plurality of sensors be replaced by a selection of different sensor types, e.g. B. by at least one optical, a thermal and / or a gas sensor is formed. The plurality of sensors advantageously reduces the probability of a false alarm.

The brand-specific measured values detected by the plurality of sensors are, for example, correlated in order to carry out a mutual referencing. For example, in the case of an optical sensor and a gas sensor, an evaluation of a fire takes place with a detected increase in the particle and combustion gas concentration. Alternatively, it is possible that the detected brand-specific measured values of the sensors are evaluated independently of one another as absolute values or as relative values.

In a first possible embodiment, the majority of sensors are always active. That is, the majority of sensors are active regardless of the sensitivity level set. In this case, by setting the sensitivity level for each sensor, an individual limit value per sensitivity level and / or a limit value for the correlation values per sensitivity level and / or a limit value for the relative values per sensitivity level can be set.

In a second possible embodiment, the at least three sensitivity levels are each assigned a sensor of different sensor type of the plurality of sensors and / or a different selection of sensors from the plurality of sensors, so that the selection of the active sensor or sensors is different at the different sensitivity levels. Thus, the sensitivity levels preferably each have an active sensor, which differs in its sensor design from the active sensors of the further sensitivity levels. Alternatively or optionally additionally, at least some of the sensitivity levels each have a selection of active sensors which differ with at least one active sensor for the selection of the active sensors of the further sensitivity levels. An advantage of the different selection of the active sensors is that the evaluation sensitivity can be adapted to the different environmental parameters of a room, which influence the detection of a fire. For example, in a first sensitivity stage of the thermal sensor, in a second sensitivity level of the optical and the gas sensor and the third Sensitivity level to be activated all three of these sensors. The setting of the first sensitivity level is suitable, for example, for the arrangement of the fire detector in the kitchen, since the evaluation sensitivity is oriented so that the detection of a fire is not based on moisture, combustion gas or smoke particle characteristics. The setting of the second sensitivity level is suitable for. B. in the garage and the third sensitivity level z. B. for the bedroom or living room. The selection of different sensors thus allows an individual setting of the fire detector for different rooms. By selecting the active sensors, the detection spectrum of the fire detector can be adapted, in particular extended. Consequently, the fire alarm ensures increased security to detect a fire in a room in time and to reduce the likelihood of a false alarm.

In a third possible embodiment, the evaluation sensitivity is adjustable from a lowest sensitivity level to a highest sensitivity level, at least one of the sensors being activated when the lowest sensitivity level is set, wherein when switching to a higher or highest of the at least three sensitivity levels, a further one of the sensors is activated is switched on and is brought from the deactivated state to the activated state. In particular, the evaluation sensitivity at the higher and highest sensitivity level is increased by the connection of the further sensor to the lowest sensitivity level. An advantage of the stepwise activation is that the evaluation sensitivity, in particular the detection spectrum, can be adapted, in particular extended, to the various environmental parameters of a room which influence the detection of a fire. For example, at the lowest sensitivity level, a first optical scattered light sensor functioning with a red light-emitting diode and at the higher sensitivity level additionally a second optical scattered light sensor functioning with a blue light-emitting diode can be activated. By means of the blue LED, the second optical scattered-light sensor makes it possible, in particular, to detect small particles which as a rule can arise in foam fires of mattresses. At the highest sensitivity level, other sensors, such. B. a gas sensor are switched on. The selection of the sensitivity level, ie the selection of the activated and connected sensors, can be done after the Installation site of the fire alarm can be selected. So the lowest sensitivity level z. B. for the kitchen and the highest sensitivity level z. B. be selected for the bedroom. The different sensitivity levels thus achieve an individual setting of the fire detector for different rooms. In particular, the fire detector ensures through the different sensitivity levels increased security to detect a fire in a room in good time and to reduce the likelihood of false alarm.

In a preferred development it can be provided that the fire detector has at least one signal device which displays the set sensitivity level to the user. Preferably, the signaling device is designed as an optical and / or acoustic signal device. For example, the signaling device comprises a plurality of differently colored LEDs. By way of example, each sensitivity stage is assigned at least one light-emitting diode, so that when setting one of the sensitivity levels, the set sensitivity level is signaled to the user by the activated light-emitting diode that is switched on. Alternatively or optionally in addition, it can be provided that the display device comprises a loudspeaker which emits a short tone when setting one of the sensitivity levels. Thus, the user is signaled to set one of the sensitivity levels.

A preferred structural embodiment of the invention provides that the adjusting device is arranged in or on the housing of the fire detector. In particular, the adjusting device is designed as a switch, particularly preferably as a rotary switch. The switch is an intuitive means of operation and thus achieves a particularly simple handling. Thus, a quick and easy adjustment of the desired sensitivity level is implemented. The adjusting device is z. B. arranged on a side wall of the housing. Alternatively it can be provided to arrange the adjusting device on a lower housing part. The lower housing part can preferably be arranged on the ceiling or on the wall. Thus, the actuator is not visible in the arrangement of the fire detector on the ceiling or on the wall for a person visible. The embodiment has the advantage that in the arrangement of the fire alarm on the ceiling or on the wall, a subsequent adjustment The set sensitivity level is only possible after removing the fire alarm. The possibility of unauthorized manipulation of the sensitivity level setting by unauthorized persons is thus reduced. Alternatively, the adjusting device may be arranged on a housing upper part. The upper housing part is preferably directed in the arrangement of the fire alarm on the ceiling or on the wall in the room. The adjusting device is thus arranged visible to a person in the arrangement of the fire detector on the ceiling or wall, so that switching the adjusting device without removing the fire alarm is possible.

From the structural design is preferred that the at least three sensitivity levels each have a name is assigned, wherein the name indicates the degree of sensitivity of the associated sensitivity level. In particular, the evaluation sensitivity of the individual sensitivity stages is indicated to the user by naming the degree of sensitivity of the respective sensitivity levels.

In a preferred embodiment, the designation respectively describes the number of activated sensors of the associated sensitivity level, so that the designation of the activated sensors indicates the degree of sensitivity of the associated sensitivity level with respect to the number of active sensors. For example, the designation is "1 sensor on", "2 sensors on", "3 sensors on" and / or "all sensors activated". The designation of the activated sensors proves to be advantageous in the third embodiment.

Alternatively, it is conceivable to designate the sensitivity levels as, for example, "insensitive", "sensitive" and / or "very sensitive" as the degree of sensitivity.

In a particularly preferred embodiment, each of the at least three sensitivity levels is assigned a designation, the designation identifying the installation location of the associated sensitivity level. In particular, the installation locations mentioned are rooms of the private household. The designation assigned to the sensitivity levels is z. "Kitchen", "Living Room", "Garage", "Workshop", "Office" and / or "Bathroom". Thus, the user is shown for which or for which Rooms the sensitivity levels are designed. When naming the at least three sensitivity levels according to the installation locations, it is particularly preferred that the sensitivity levels are each assigned a different selection of the plurality of sensors, as explained in connection with the second embodiment. In this way, the evaluation sensitivities of the sensitivity levels can be selected in such a way that fire-specific sources of interference of a room, such as e.g. As smoke particles in the kitchen, are not detected by the sensors or only in correlation with other brand-specific measurements. The probability of a false alarm is thus reduced.

As an alternative, it may be provided that the designation describes in each case the selection of the connected sensors of the associated sensitivity level. For example, the designation is "optical sensor on", "optical and thermal sensor on" and / or "optical, thermal and gas sensor on". In this way it is possible for the user to autonomously select the sensitivity level according to the various sources of interference present in a room.

In the case of a plurality of scattered-light sensors with different LEDs, it may be provided that the term "Activate Red Shield" for the optical scattered light sensor activated by the red light-emitting diode, "Activate Blue Shield" for the optical scattered-light sensor activated with the blue light-emitting diode and "Activate both "for both activated sensors reads. The activation of the optical, working with the red LED scattered light sensor can, for. B. the user by a red LED, the activation of the optical, working with the blue LED scattered light sensor to the user by a blue LED and both activated sensors to the user by both the red, and the blue LED are displayed.

In a preferred structural implementation of the fire detector is operated autonomously. For example, the fire detector has an integrated energy supply. In particular, the fire detector is battery operated. The fire detector preferably has an LED which indicates the functionality of the fire detector. Particularly preferably, the autonomous fire detector comprises a siren for outputting an acoustic fire warning. Alternatively, it is possible that the Fire alarm is part of an alarm system and with one or more fire detectors that are mounted in the rooms, and / or signal technology connected to a fire alarm panel.

In a further embodiment, the fire detector has an interface, wherein the interface is designed such that the evaluation sensitivity can be set remotely. The interface of the fire detector is preferably designed as a wireless interface, in particular as a Bluetooth interface. In a further variant, the interface of the fire detector is designed as a wired interface. The evaluation sensitivity is preferably carried out via a wireless telephone, in particular via an application program, for example a smartphone app. This application program of the telephone accesses the fire detector either directly via the wireless interface, or the application program of the telephone accesses a program via a server, in particular a cloud, in a telecommunications network, this program then in turn accessing the fire detector to make the settings of the evaluation sensitivity of the fire alarm.

Figur 1

eine schematische Blockdarstellung eines Brandmelders als ein Ausführungsbeispiel der Erfindung;

Figur 2

in einer Draufsicht den Brandmelder aus Figur 1.

Further features, advantages and effects of the invention will become apparent from the following description of preferred embodiments of the invention. Showing:

FIG. 1

a schematic block diagram of a fire detector as an embodiment of the invention;

FIG. 2

in a top view of the fire alarm FIG. 1 ,

Corresponding or identical parts are each provided with the same reference numerals in the figures.

FIG. 1 shows a schematic block diagram of a fire detector 1 as an embodiment of the invention. The fire detector 1 is z. B. as an optical fire detector, as a fire gas detector, as a heat detector or as a multi-criteria detector. The fire detector 1 has a sensor 2 for detecting a fire, wherein the sensor 2 for detecting brand-specific measured values is formed. The sensor 2 includes z. B. exactly one or a plurality of sensors. For example, the sensor system 2 comprises at least one optical, one thermal and / or one gas sensor, which detect the brand-specific measured values. The sensor 2 detects as brand-specific measured values z. As a Rauchpartikel-, fire gas, moisture concentration and / or the ambient temperature of the fire detector 1 in the arranged space. The plurality of sensors, the fire detector 1 can ensure increased security to detect a fire in good time.

The fire detector 1 comprises an evaluation unit 3, wherein the evaluation unit 3 evaluates a fire on the basis of the fire-specific measured values. The sensor system 2 is coupled to the evaluation unit 3 for the transmission of the recorded brand-specific measured values. The evaluation unit 3 evaluates the brand-specific measured values z. B. as absolute and / or relative values, or, in a plurality of sensors, for. B. as correlation values.

The evaluation of a fire is determined by an evaluation sensitivity of the evaluation unit 3. The evaluation sensitivity thus defines a tripping limit of a fire alarm. If an evaluation of a fire by the evaluation unit 3, an alarm is triggered, which can be signaled for example by an acoustic signal.

The fire detector 1 comprises an adjusting device 4, wherein by means of the adjusting device 4, the evaluation sensitivity of the evaluation unit 3 is manually adjustable in at least three sensitivity levels. The setting device 4 is coupled to transmit the sensitivity level set by a user to the evaluation unit 3, so that the evaluation sensitivity is set according to the set sensitivity level. The adjusting device 4 is arranged on the fire detector 1, so that a user a direct adjustment of the evaluation sensitivity is possible.

For example, the evaluation sensitivity is defined by at least one limit value of the recorded brand-specific measured values, wherein the at least one limit value is assigned to one of the at least three sensitivity levels. The limit values assigned to the sensitivity levels differ from each other, so that the sensitivity levels have different evaluation sensitivities. The at least one limit value of the set sensitivity level is used to evaluate a fire with the recorded fire-specific measured values z. B. compared or set in correlation.

If the sensor system 2 comprises one or a plurality of sensors, it may be provided that they are always, that is, d. H. regardless of the sensitivity levels, are active. In the case of a plurality of sensors, it is alternatively possible for each sensitivity stage to be assigned a selection of sensors. This means that when switching to one of the sensitivity levels at least one of the sensors is activated or deactivated. By selecting different sensors, the evaluation sensitivity is based on different brand-specific measured values. As a further alternative it can be provided that the evaluation sensitivity is adjustable from a lowest to a highest sensitivity level, wherein at the lowest sensitivity level at least one of the sensors is activated, and wherein when switching to a higher or the highest sensitivity level respectively at least one of the Sensors is switched on.

FIG. 2 shows the fire detector 1 off FIG. 1 in a top view. The fire detector 1 is z. B. on a ceiling or on a room wall can be arranged. The fire detector 1 comprises a housing 5 with a measuring chamber. In the measuring chamber, the sensor 2 for detecting a fire is arranged. Furthermore, the evaluation unit 3 is arranged in the housing 5.

The adjusting device 4 is formed in this embodiment as a rotary switch and disposed on the housing 5 of the fire detector 1. The adjusting device 4 is switchable into four positions, wherein each of the four position is associated with a sensitivity level of the evaluation sensitivity. The sensitivity levels are each assigned a designation A, B, C, D, the designations A, B, C, D denoting the evaluation sensitivity of the respective sensitivity stage. By the designations A, B, C, D a rewriting of the respective sensitivity levels, so that the meaning of the different sensitivity levels is immediately recognizable for the user.

For example, the terms A, B, C, D describe the degree of sensitivity of the respective sensitivity level, such. B. "very insensitive", "insensitive", "very sensitive", "extremely sensitive". Alternatively, the terms A, B, C, D can describe the number of activated sensors, such as. Eg "1 sensor on", "2 sensors on", "3 sensors on", "all sensors activated". In this way, the user is able to select the evaluation sensitivity based on the aforementioned sensitivity levels.

The detection of a fire can vary according to the installation site due to different fire-specific environmental parameters. Therefore, another alternative provides that the designations A, B, C, D designate the installation location of the respective sensitivity level. The names A, B, C, D assigned to the sensitivity levels are for example "living room", "garage", "kitchen", "bedroom". The user is identified by the naming of the installation sites the evaluation sensitivity to the installation locations.

When describing the sensitivity levels according to the installation site, the evaluation sensitivities are eg. B. determined by the different selection of sensors. The selection of the sensors are to be aligned, for example, according to the fire-specific sources of interference of a room. In other words, the fire-specific measured values to be recorded are to be selected in such a way that the fire-specific sources of interference of a room, such As water vapor or smoke particles in the kitchen, are not detected by the sensors or only in correlation with other brand-specific measurements. Thus, the evaluation sensitivity of the respective sensitivity levels is aligned for a specific space, so that the risk of a false alarm is reduced.

Claims (11)

Fire detector (1) for the detection of a fire,
with a sensor system (2) for capturing brand-specific measured values,
with an evaluation unit (3) for detecting the fire on the basis of the brand-specific measured values,
with an adjusting device (4), which is designed for manually setting the evaluation sensitivity of the fire detector (1) on the fire detector (1), wherein the adjusting device (4) is arranged in or on the fire detector (1),
characterized in that
the evaluation sensitivity can be set in at least three sensitivity levels. Fire detector (1) according to claim 1, characterized in that the evaluation sensitivity is defined by at least one limit value of the recorded fire-specific measured values, wherein the at least one limit value defines a triggering limit of the evaluation unit for detecting the fire. Fire detector (1) according to claim 1 or 2, characterized in that the sensor (2) has a plurality of sensors, wherein at a first of the at least three sensitivity levels of at least one of the sensors is activated, wherein when switching to a second or third of the at least three sensitivity levels another of the sensors is switched on. Fire detector (1) according to claim 1 or 2, characterized in that the sensor (2) has a plurality of sensors, wherein the at least three sensitivity levels are each assigned a sensor of different sensor type and / or a different selection of the plurality of sensors. Fire detector (1) according to claim 3 or 4, characterized in that the plurality of sensors comprises at least one optical, a thermal, a moisture and / or a gas sensor. Fire detector (1) according to one of the preceding claims, characterized in that the fire detector comprises a housing (5), wherein the adjusting device (4) in or on the housing (5) is arranged, and wherein the adjusting device (4) as a switch is trained. Fire detector (1) according to one of the preceding claims, characterized in that the at least three sensitivity levels are each assigned a name, wherein the name indicates a degree of sensitivity of the associated sensitivity level. Fire detector (1) according to claim 7, characterized in that the designation describes in each case the number of activated sensors of the sensor system (2) of the associated sensitivity level. Fire detector according to one of the preceding claims 1 to 6, characterized in that the at least three sensitivity levels are each assigned a name, wherein the name in each case describes an installation location for the fire detector (1). Fire detector (1) according to one of the preceding claims, characterized in that the fire detector is autonomously operable. Fire detector (1) according to one of the preceding claims, characterized in that the fire detector (1) has an interface, wherein the interface is designed such that the evaluation sensitivity of the fire detector (1) is remotely adjustable.

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