EP4216183A1 - Smoke warning device and method for operating and/or calibrating the smoke warning device - Google Patents

Abstract

A smoke alarm device (10) with at least one sensor unit (12) for detecting a warning signal of a smoke alarm device (14), with at least one communication unit (16) for data communication with at least one external smoke alarm device (14), in particular different Unit (18) and with at least one attachment unit (20) for attachment, in particular detachable, to the smoke alarm device (14).

Description

State of the art

Various smoke alarm devices have already been proposed.

Disclosure of Invention

A smoke alarm device is proposed with at least one sensor unit for detecting a warning signal from a smoke alarm, with at least one communication unit for data communication with at least one external unit, in particular different from a smoke alarm, and with at least one fastening unit for a, in particular detachable, attachment to the smoke alarm.

In particular, the smoke alarm device comprises at least one housing. The housing is preferably flat, in particular plate-shaped. For example, the housing has a flat cylindrical shape. Alternatively, it is also conceivable for the housing to be cube-shaped, spherical or some other shape that appears sensible to a person skilled in the art. The sensor unit and/or the communication unit are/is preferably arranged on, in particular at least partially in, the housing. The fastening unit is preferably arranged on the housing. It is conceivable that the fastening unit is designed in one piece with the housing. Including that "at least one unit and at least one further unit/an object are formed at least partially in one piece with one another" should be understood in particular that at least one element of the unit is formed in one piece with at least one further element of the further unit/with the object. "In one piece" can be understood as being at least cohesively connected, for example by a welding process, an adhesive process, an injection molding process and/or another process that appears sensible to the person skilled in the art, and/or advantageously formed in one piece, such as by production from a single cast and/or by production in a single or multi-component injection molding process and advantageously from a single blank. A detachable fastening can be detached in particular without being destroyed. The fastening unit preferably comprises at least one fastening element for fastening the housing to the smoke alarm device. The fastening element is preferably formed by the housing. For example, the fastening element is designed as a bayonet catch for receiving the smoke alarm device. Alternatively, it is also conceivable that the fastening element is designed as an adhesive tape, in particular as a double-sided adhesive tape, as a Velcro strip, as a permanent magnet, as a recess in the housing for a screw or the like, as a positive-locking element, as a locking projection, as a locking recess, as a clamp or as another fastening element that a person skilled in the art considers useful. It is conceivable that the smoke alarm device has at least one fastening element that corresponds to the fastening element, for example an adhesive surface, an adhesive tape, a Velcro strip, a permanent magnet, a recess in a smoke alarm device housing of the smoke alarm device for a screw or the like, a positive-locking element, a latching recess, a latching projection, a clamp or another fastening element that a person skilled in the art considers useful. It is also conceivable for the smoke alarm device to be designed without any fastening elements that specifically correspond to the fastening element of the fastening unit of the smoke alarm device. The housing can preferably be fastened to a building structure by the at least one fastening element. Alternatively or additionally, it is also conceivable that the fastening unit comprises a further fastening element in order to fasten the housing to the building structure. It is conceivable that the further fastening element is designed identically or differently to the fastening element of the fastening unit. The housing preferably rests directly on the smoke alarm device in at least one operating state.

The communication unit is preferably provided for contactless data communication with the at least one external unit. Alternatively or additionally, it is also conceivable that the communication unit is provided for contact-based data communication with the at least one external unit. The communication unit is designed, for example, as a radio-based communication unit, as an induction-based communication unit, as a contact-based electrical communication unit, as an optical communication unit, in particular a contact-based and/or contactless one, or as another communication unit that a person skilled in the art considers useful. The external unit is designed, for example, as a smartphone, as a laptop, as a computer, as a server, as a cloud, as a gateway, in particular as a smart home gateway, or as another external unit that a person skilled in the art considers useful. The sensor unit is preferably intended to optically, acoustically or haptically detect a warning signal from the smoke alarm device. The sensor unit preferably includes at least one acoustic sensor, in particular a microphone, which is set up to detect an acoustic warning signal from the smoke alarm device. The communication unit is intended in particular to transmit information about a warning signal of the smoke alarm device detected by means of the sensor unit to the at least one external unit. It is conceivable that the external unit comprises at least one output means, for example a screen, a loudspeaker, an LED, an incandescent lamp or the like, for outputting information about the detected warning signal, preferably to a user.

The design of the smoke alarm device according to the invention allows a non-networked smoke alarm to be networked, in particular in a smart home system or the like. Advantageously, a non-networked smoke alarm device can be networked in a particularly convenient and time-saving manner. In particular, a particularly high level of protection against smoke, fire or the like can be realized. A particularly high degree of reliability can advantageously be achieved when a warning signal from a smoke alarm device is detected.

In addition, it is proposed that the fastening unit is provided for fastening the smoke alarm device to a building structure, in particular to the building structure already mentioned above. It is conceivable that the smoke alarm device can be fastened to the building structure by means of the at least one fastening element, the further fastening element and/or by means of at least one additional fastening element of the fastening unit. For example, the smoke alarm device can be fastened, in particular clamped, to the building structure between the housing and the housing structure by fastening the housing, for example by means of the fastening element and/or the further fastening element. It is also conceivable that the fastening unit is designed in such a way that the housing is arranged between the smoke alarm device and the building structure when the housing and the smoke alarm device are fastened to the building structure. The smoke alarm device, in particular the attachment unit of the smoke alarm device, can advantageously be used to attach the smoke alarm device to the building structure. Additional fastening elements for fastening the smoke alarm device to the building structure can advantageously be dispensed with. Advantageously, a smoke alarm device can be networked and installed in a particularly cost-effective manner.

Furthermore, it is proposed that the sensor unit has a vibration sensor, which is intended to detect vibrations that can be generated by a warning signal, in particular an acoustic warning signal, from the smoke alarm device. The vibration sensor is preferably set up to detect vibrations that can be generated by the warning signal of the smoke alarm device and can be transmitted from the smoke alarm device to the housing, for example. In particular, the smoke alarm device comprises at least one control or regulation unit. The control or regulation unit is preferably set up to evaluate sensor signals from the sensor unit, in particular at least from the vibration sensor and/or the acoustic sensor. In particular, the control or regulation unit set up to determine, as a function of sensor signals from the sensor unit, in particular at least the vibration sensor and/or the acoustic sensor, whether the smoke alarm device emits a warning signal. In particular, the control or regulation unit comprises at least one processor and one memory element as well as an operating program stored on the memory element. The storage element is preferably designed as a digital storage medium, for example as a hard disk or the like. The vibration sensor is preferably arranged on, in particular in, the housing in such a way that the vibration sensor is arranged on a side of the housing facing the smoke alarm device, at least when it is arranged on the smoke alarm device. A particularly high detection rate for the warning signal can advantageously be achieved. A warning signal from a smoke alarm device can advantageously be flexibly detected.

Furthermore, it is proposed that the sensor unit comprises at least one optical sensor which is intended to detect an optical warning signal from the smoke alarm device. The smoke alarm device comprises, for example, at least one output element for optically outputting the warning signal, the output element being designed as an LED, an incandescent lamp or another output element for optically outputting a warning signal that a person skilled in the art considers useful. The optical sensor is preferably designed as a preferably flexible light guide which can be connected to the output element of the smoke alarm device in particular for detecting the warning signal, preferably without obscuring the output element of the smoke alarm device. It is alternatively or additionally conceivable that the optical sensor comprises a camera sensor, a CMOS sensor, a CCD sensor, a photocell, a photodiode or the like. A particularly high detection rate for the warning signal can advantageously be achieved. Advantageously, a warning signal from a smoke alarm device can be detected particularly reliably. A warning signal from a smoke alarm device can advantageously be flexibly detected.

It is also proposed that the smoke alarm device comprises at least one control or regulating unit, in particular the previously mentioned control or regulating unit, which comprises at least one machine learning module that is set up to carry out an alarm recognition learning process. Preferably the Control unit can be trained using the alarm detection learning process of the machine learning module to determine a warning signal of the smoke alarm from sensor signals detected by the sensor unit, preferably using test warning signals that can be output in particular by the smoke alarm. Carrying out the alarm detection training process preferably trains the machine learning module. It is conceivable that the control or regulation unit, in particular the machine learning module, can be controlled by the communication unit via the at least one external unit. The alarm detection learning process can preferably be activated by the at least one external unit by means of a control signal that can be transmitted by means of the communication unit. Alternatively or additionally, it is also conceivable that the smoke alarm device comprises at least one input element, for example a key, button, switch, touch screen or the like, with the alarm detection learning process being able to be activated in particular by actuating the input element. It is also conceivable that the smoke alarm device comprises at least one output element. The output element of the smoke alarm device is preferably arranged on the housing. The output element of the smoke alarm device is designed, for example, as a loudspeaker, as an LED, as an incandescent lamp or as another output element that appears sensible to a person skilled in the art. The output element of the smoke alarm device is preferably provided at least to signal to a user acoustically, optically and/or haptically that the alarm recognition learning process has been completed. Furthermore, it is also conceivable that the output element of the smoke alarm device is provided to output another warning signal when a warning signal of the smoke alarm is determined by the control or regulating unit based on sensor signals determined by the sensor unit. In particular, the control or regulation unit is set up to trigger the output element of the smoke alarm device to output a further warning signal if the control or regulation unit receives a corresponding control signal from the at least one external unit via the communication unit. A "machine learning module" can be understood in particular as a computer architecture that is set up to generate knowledge from experience, in particular to learn from examples and to generalize it. The machine learning module preferably comprises at least one self-adaptive algorithm. That is preferred Machine learning module as a deep learning module (deep learning module), in particular with at least one neural network, formed. A "deep learning module" can be understood in particular as a machine learning module that is set up to independently specify features relevant to learning. In an alternative embodiment, it is conceivable that the machine learning module is set up to process learning-relevant features specified by a user. A “neural network” can be understood in particular as a computer architecture that includes artificial neurons that are networked with one another. The neural network can be designed in particular as a single-layer feedforward network, as a multi-layer feedforward network, as a recurrent network or as another neural network that appears sensible to a person skilled in the art. Advantageously, the smoke alarm device can be trained to detect different warning signals. The smoke alarm device can advantageously be used on smoke alarms with different warning signals. A particularly convenient configuration of the smoke alarm device can advantageously be made available.

In addition, it is proposed that the smoke alarm device comprises an energy generation unit which is intended to generate electrical energy from the warning signal of the smoke alarm device. The energy generation unit is preferably provided to generate electrical energy from the warning signal of the smoke alarm device for data transmission between the smoke alarm device and the at least one external unit. In particular, the energy generation unit is set up to generate electrical energy from sound waves, vibrations and/or electromagnetic radiation that can be generated by the warning signal of the smoke alarm device. The energy generation unit preferably comprises at least one nanogenerator. The smoke alarm device comprises in particular at least one energy storage element which is preferably provided to supply the control or regulation unit, the sensor unit and/or the communication unit with electrical energy. The energy storage element is designed, for example, as a battery, as a rechargeable battery pack or the like. In particular, the energy generation unit is set up to generate energy generated from the warning signal feed electrical energy into the energy storage element. A particularly durable electrical energy supply can advantageously be made available for the smoke alarm device. A smoke alarm device with a particularly high level of operating convenience can advantageously be made available.

Furthermore, a method for operating and/or calibrating a smoke alarm device, in particular the smoke alarm device according to the invention, is proposed, which comprises at least one sensor unit, in particular the one already mentioned above, for detecting a warning signal of a smoke alarm device, in particular the one already mentioned above. In one method step, the control or regulation unit is preferably calibrated as a function of the smoke alarm device, in particular as a function of warning signals from the smoke alarm device. It is conceivable that the smoke alarm device is calibrated to the smoke alarm device, in particular to a warning signal from the smoke alarm device, during production of the smoke alarm device. It is also conceivable that the smoke alarm device is calibrated by a user before the smoke alarm device is put into operation. It is conceivable that, in order to calibrate the smoke alarm device, data from an external unit, in particular the previously mentioned external unit, is transmitted, in particular wirelessly or with a cable, to the smoke alarm device, preferably to the control or regulation unit. It is also conceivable that the control or regulation unit is set up to calibrate itself as a function of a warning signal from the smoke alarm device detected by the sensor unit. In a further method step, in particular when the smoke alarm device is attached to the building structure with the smoke alarm device, a warning signal of the smoke alarm device is detected in an operating state of the smoke alarm device by means of the sensor unit, in particular by means of the acoustic sensor. In the further method step, the control or regulating unit preferably uses sensor signals determined by the sensor unit to determine whether the smoke alarm device emits a warning signal. In an additional method step, information about a smoke alarm warning signal detected by the sensor unit is transmitted to the at least one external unit. A warning signal from a non-networked smoke detector can be particularly advantageous reliably detected and information about the warning signal can be conveniently transmitted to an external unit, such as a smart home system.

It is also proposed that in one method step, in particular the additional step already mentioned above, vibrations that can be generated by a warning signal, in particular acoustic, of the smoke alarm device are detected by means of a vibration sensor, in particular the aforementioned vibration sensor, of the sensor unit of the smoke alarm device. In the further method step, vibrations that can be generated by the warning signal of the smoke alarm device and can be transmitted in particular from the smoke alarm device to the housing are preferably detected by means of the vibration sensor. Sensor signals from the sensor unit, in particular at least from the vibration sensor and/or the acoustic sensor, are preferably evaluated in the further method step using the control or regulating unit. In the further method step, the control or regulating unit is used, in particular, to determine whether the smoke alarm device emits a warning signal as a function of sensor signals from the sensor unit, in particular at least from the vibration sensor and/or the acoustic sensor. A warning signal from the smoke alarm device can advantageously be detected using vibrations caused by the warning signal.

In addition, it is proposed that in one method step, in particular the additional method step already mentioned above, an optical warning signal of the smoke alarm device is detected by an optical sensor, in particular the optical sensor already mentioned above, of the sensor unit of the smoke alarm alarm device. The warning signal can advantageously be detected particularly reliably.

Furthermore, it is proposed that in one method step, in particular the one already mentioned above, an alarm detection learning process is carried out by means of one, in particular the one already mentioned, machine learning module of one, in particular the one already mentioned, control or regulation unit of the smoke alarm device. The control or regulation unit is preferably trained by means of the alarm detection training process of the machine learning module in the method step to determine a warning signal of the smoke alarm device from sensor signals detected by the sensor unit, preferably based on test warning signals that are output in particular by the smoke alarm device. The alarm detection learning process is preferably activated by a control signal that can be transmitted by the communication unit from the at least one external unit or by actuating the input element in the method step. In the method step, information about a status, preferably a conclusion, of the alarm detection learning process is output acoustically, optically and/or haptically via the output element of the smoke alarm device. Furthermore, it is also conceivable that in the further method step, when a warning signal of the smoke alarm is determined by the control or regulating unit based on sensor signals determined by the sensor unit, another warning signal is output via the output element of the smoke alarm device. It is conceivable that the output element of the smoke alarm device is actuated by the control or regulation unit to output a warning signal when the control or regulation unit receives a corresponding control signal from the at least one external unit via the communication unit. The smoke alarm device can advantageously be configured in a particularly convenient manner. The smoke alarm device can advantageously be configured for different smoke alarms.

It is also proposed that in one method step, in particular the additional method step already mentioned above, electrical energy is obtained from the warning signal of the smoke alarm device by means of an energy generation unit of the smoke alarm device, in particular the one already mentioned above. In the further method step, electrical energy for data transmission between the smoke alarm device and the at least one external unit is obtained in particular by means of the energy generation unit from the warning signal of the smoke alarm device. In particular, electrical energy obtained by means of the energy generation unit is fed into the energy storage element in the further method step. Advantageously, the smoke alarm device can be operated with a particularly low maintenance effort. Advantageously, energy from the warning signal can be used to operate the smoke alarm device.

The smoke alarm device according to the invention and/or the method according to the invention should/should not be limited to the application and embodiment described above. In particular, the smoke alarm device according to the invention and/or the method according to the invention can/can have a number of individual elements, components and units as well as method steps that differs from the number specified here in order to fulfill a function described herein. In addition, in the value ranges specified in this disclosure, values lying within the specified limits should also be considered disclosed and can be used as desired.

drawing

Further advantages result from the following description of the drawings. In the drawing an embodiment of the invention is shown. The drawing, the description and the claims contain numerous features in combination. The person skilled in the art will expediently also consider the features individually and combine them into further meaningful combinations.

Fig. 1

eine erfindungsgemäße Rauchwarnmeldevorrichtung in einem an einem Rauchwarnmelder angeordneten Zustand in einer schematischen Darstellung,

Fig. 2

die erfindungsgemäße Rauchwarnmeldevorrichtung in einer schematischen Darstellung und

Fig. 3

einen schematischen Ablauf eines erfindungsgemäßen Verfahrens zu einem Betrieb und/oder einer Kalibrierung der erfindungsgemäßen Rauchwarnmeldevorrichtung.

Show it:

1

a smoke alarm device according to the invention in a state arranged on a smoke alarm in a schematic representation,

2

the smoke alarm device according to the invention in a schematic representation and

3

a schematic sequence of a method according to the invention for operation and/or calibration of the smoke alarm device according to the invention.

Description of the embodiment

figure 1 shows a smoke alarm device 10 and a smoke alarm device 14. The smoke alarm device 10 comprises at least one sensor unit 12 for detecting a warning signal of the smoke alarm device 14. The smoke alarm device 10 comprises at least one communication unit 16 for data-technical communication with at least one external unit 18, in particular different from a smoke alarm device 14. The smoke alarm device 10 comprises at least one attachment unit 20 for an, in particular detachable, attachment to the smoke alarm device 14. The smoke alarm device 10 comprises in particular at least one housing 42 The housing 42 is flat, in particular plate-shaped. The housing 42 has a flat cylindrical shape. Alternatively, it is also conceivable for the housing 42 to be cube-shaped, spherical or have another shape that a person skilled in the art considers appropriate. The fastening unit 20 is arranged on the housing 42 . The fastening unit 20 comprises at least two fastening elements 40 for fastening the housing 42 to the smoke alarm device 14 (cf. figure 2 ). Alternatively, it is also conceivable that the fastening unit 20 has only one fastening element 40 or more than two fastening elements 40 . The two fastening elements 40 are designed as recesses in the housing 42 for a screw or the like. Alternatively, it is also conceivable that the two fastening elements 40 are each embodied as an adhesive tape, in particular as a double-sided adhesive tape, as a Velcro strip, as a permanent magnet, as a positive-locking element, as a locking projection, as a locking recess, as a clamp or as another fastening element 40 that a person skilled in the art considers useful. Alternatively, for example, it is also conceivable for the fastening unit 20 to have a fastening element designed as a bayonet lock for receiving the smoke alarm device 14 , the bayonet lock being formed in particular by the housing 42 . Alternatively, it is also conceivable that the two fastening elements 40 are designed as fastening elements that are different from one another.

Smoke alarm device 14 has at least one fastening element (not shown here) that corresponds to the two fastening elements 40, preferably recesses in a smoke alarm device housing of smoke alarm device 14. Alternatively, however, it is also conceivable for smoke alarm device 14 to have a fastening element (not shown here), which, for example, an adhesive surface, as an adhesive tape, as a Velcro strip, as a permanent magnet, as a form-fitting element, as a locking recess, as a locking projection, as a clamp or as another fastening element that a person skilled in the art considers useful. It is also conceivable that the smoke alarm device 14 is designed without any fastening elements that specifically correspond to the two fastening elements 40 of the fastening unit 20 of the smoke alarm device 10 . The housing 42 can be fastened to a building structure 22 by the two fastening elements 40 . Alternatively or additionally, it is also conceivable that the fastening unit 20 comprises at least one further fastening element (not shown here) in order to fasten the housing 42 to a building structure 22 . It is conceivable that the further fastening element is identical to or different from the two fastening elements 40 of the fastening unit 20 .

The attachment unit 20 is intended to attach the smoke alarm device 14 to the building structure 22 . The smoke alarm device 14 can be fastened to the building structure 22 via the at least two fastening elements 40 of the fastening unit 20 . The smoke alarm device 14 can be fastened, in particular clamped, to the building structure 22 between the housing 42 and the building structure 22 by fastening the housing 42, in particular by means of a screw connection, by the two fastening elements 40 of the fastening unit 20. Alternatively, it is also conceivable that the smoke alarm device 14 can be fastened to the building structure 22 by means of the further fastening element of the fastening unit 20 and/or by means of at least one additional fastening element (not shown here) of the fastening unit 20 . Furthermore, it is alternatively also conceivable that the fastening unit 20 is designed in such a way that the housing 42 is arranged between the smoke alarm device 14 and the building structure 22 when the housing 42 and the smoke alarm device 14 are fastened to the building structure 22 .

The sensor unit 12 and/or the communication unit 16 are/is arranged on, in particular at least partially in, the housing 42 . The communication unit 16 is provided for contactless data communication with the at least one external unit 18 . Alternatively or additionally it is also conceivable that the communication unit 16 is provided for contact-based data communication with the at least one external unit 18 . The communication unit 16 is designed as a radio-based communication unit. Alternatively, it is also conceivable for the communication unit 16 to be embodied as an induction-based communication unit, as a contact-based electrical communication unit, as an optical communication unit, in particular a contact-based and/or contactless one, or as another communication unit that appears sensible to a person skilled in the art. The external unit 18 is designed, for example, as a smartphone, as a laptop, as a computer, as a server, as a cloud, as a gateway, in particular as a smart home gateway, or as another external unit that a person skilled in the art considers useful.

The sensor unit 12 is intended to optically, acoustically or haptically detect a warning signal from the smoke alarm device 14 . The sensor unit 12 includes at least one acoustic sensor (not shown here), in particular a microphone, which is set up to detect an acoustic warning signal from the smoke alarm device 14 . The communication unit 16 is provided to transmit information about a warning signal of the smoke alarm device 14 detected by the sensor unit 12 to the at least one external unit 18 .

The sensor unit 12 includes a vibration sensor 24 which is intended to detect vibrations which can be generated by a warning signal, in particular an acoustic warning signal, from the smoke alarm device 14 . The vibration sensor 24 is set up to detect vibrations that can be generated by the warning signal of the smoke alarm device 14 and can be transmitted, for example, from the smoke alarm device 14 to the housing 42 . The smoke alarm device 10 comprises at least one control or regulation unit 28. The control or regulation unit 28 is set up to evaluate sensor signals of the sensor unit 12, in particular at least the vibration sensor 24 and/or the acoustic sensor. The control or regulating unit 28 is set up to determine, depending on sensor signals from the sensor unit 12, in particular at least the vibration sensor 24 and/or the acoustic sensor, whether the smoke alarm device 14 outputs a warning signal. The control or regulation unit 28 comprises at least one processor (not shown here) and a memory element (not shown here) and a operating program stored on the memory element. The storage element is designed as a digital storage medium, for example as a hard disk or the like. The vibration sensor 24 is arranged on, in particular in, the housing 42 in such a way that the vibration sensor 24 is arranged on a side of the housing 42 facing the smoke alarm device 14 at least when it is arranged on the smoke alarm device 14 .

The sensor unit 12 comprises at least one optical sensor 26 which is intended to detect an optical warning signal from the smoke alarm device 14 . The smoke alarm device 14 comprises, for example, at least one output element for optically outputting the warning signal, with the output element being designed as an LED, an incandescent lamp or another output element for optically outputting a warning signal that appears sensible to a person skilled in the art. The optical sensor 26 is designed as a preferably flexible light guide which can be connected to the output element of the smoke alarm device 14 in particular for detecting the warning signal, preferably without obscuring the output element. It is alternatively or additionally conceivable that the optical sensor 26 comprises a camera sensor, a CMOS sensor, a CCD sensor, a photocell, a photodiode or the like.

The control or regulation unit 28 comprises at least one machine learning module 30 which is set up to carry out an alarm detection learning process. The control or regulation unit 28 can be trained by means of the alarm detection training process of the machine learning module 30 to determine a warning signal of the smoke alarm device 14 from sensor signals detected by the sensor unit 12, preferably using test warning signals that can be output in particular by the smoke alarm device 14. The machine learning module 30 trains the execution of the alarm detection learning process. The alarm detection learning process can be activated by the at least one external unit 18 by means of a control signal that can be transmitted by means of the communication unit 16 . Alternatively or additionally, it is also conceivable that the smoke alarm device 10 has at least one input element (not shown here), for example a key, a knob, a switch, a touch screen or the like, wherein the alarm recognition learning process can be activated in particular by actuating the input element. It is also conceivable that the smoke alarm device 10 includes at least one output element (not shown here). The output element of the smoke alarm device 10 is preferably arranged on the housing 42 . The output element of the smoke alarm device 10 is embodied, for example, as a loudspeaker, as an LED, as an incandescent lamp or as another output element that appears sensible to a person skilled in the art. The output element of the smoke alarm device 10 is preferably provided at least to signal to a user acoustically, optically and/or haptically that the alarm recognition learning process has been completed. Furthermore, it is also conceivable that the output element of the smoke alarm device 10 is provided to output another warning signal when a warning signal of the smoke alarm device 14 is determined by the control or regulating unit 28 based on sensor signals determined by the sensor unit 12 . The control or regulation unit 28 is set up to trigger the output element of the smoke alarm device 10 to output a further warning signal if the control or regulation unit 28 receives a corresponding control signal from the at least one external unit 18 via the communication unit 16.

The smoke alarm device 10 includes an energy generation unit 32 which is intended to generate electrical energy from the warning signal of the smoke alarm device 14 . The energy generation unit 32 is intended to generate electrical energy from the warning signal of the smoke alarm device 14 for data transmission between the smoke alarm device 10 and the at least one external unit 18 . The energy generation unit 32 is set up to generate electrical energy from sound waves, vibrations and/or electromagnetic radiation that can be generated by the warning signal of the smoke alarm device 14 . The energy generation unit 32 comprises at least one nanogenerator. The smoke alarm device 10 includes in particular at least one energy storage element (not shown here), which is preferably provided for the control or regulation unit 28, the sensor unit 12 and / or the communication unit 16 with electrical energy to supply. The energy storage element is designed, for example, as a battery, as an accumulator pack or the like. The energy generation unit 32 is set up to feed electrical energy generated from the warning signal into the energy storage element.

figure 3 12 shows a schematic sequence of a method for operating and/or calibrating the smoke alarm device 10. In a method step 36, the control or regulation unit 28 is calibrated as a function of the smoke alarm device 14, in particular as a function of warning signals from the smoke alarm device 14. It is conceivable for the smoke alarm device 10 to be calibrated to the smoke alarm device 14 , in particular to a warning signal from the smoke alarm device 14 , during production of the smoke alarm device 10 . It is also conceivable that the smoke alarm device 10 is calibrated by a user before the smoke alarm device 10 is put into operation. The control or regulation unit 28 is set up to calibrate itself as a function of a warning signal from the smoke alarm device 14 detected by the sensor unit 12 . In method step 36, an alarm recognition learning process is carried out by means of the machine learning module 30 of the control or regulation unit 28 of the smoke alarm device 10. The control or regulation unit 28 is trained by means of the alarm detection training process of the machine learning module 30 in method step 36 to determine a warning signal of the smoke alarm device 14 from sensor signals detected by the sensor unit 12, preferably using test warning signals that are output by the smoke alarm device 14. The alarm detection learning process is activated by a control signal that can be transmitted by the communication unit 16 from the at least one external unit 18 in method step 36 or by actuating the input element. In method step 36, information about a status, preferably a conclusion, of the alarm detection learning process is output acoustically, optically and/or haptically via the output element of the smoke alarm device 10 . Alternatively, it is also conceivable for data from an external unit 18, in particular the previously mentioned external unit 18, to be transmitted, in particular wirelessly or with a cable, to the smoke alarm device 10, preferably to the control or regulation unit 28, in order to calibrate the smoke alarm device 10.

In a further method step 34, in particular when the smoke alarm device 10 is attached to the building structure 22 with the smoke alarm device 14, a warning signal of the smoke alarm device 14 is detected in an operating state of the smoke alarm device 10 by means of the sensor unit 12, in particular at least by means of the acoustic sensor. In the further method step 34 , vibrations that can be generated by a warning signal, in particular an acoustic one, from the smoke alarm device 14 are detected by means of the vibration sensor 24 of the sensor unit 12 of the smoke alarm device 10 . In the further method step 34 an optical warning signal of the smoke alarm device 14 is detected by the optical sensor 26 of the sensor unit 12 of the smoke alarm device 10 . In the further method step 34, the control or regulating unit 28 uses sensor signals determined by the sensor unit 12 to determine whether the smoke alarm device 14 emits a warning signal. It is also conceivable that in further method step 34, when a warning signal from smoke alarm device 14 is determined by control or regulating unit 28 based on sensor signals determined by sensor unit 12, another warning signal is output via the output element of smoke alarm device 10. It is conceivable for the output element of the smoke alarm device 10 to be actuated to output a warning signal by the control or regulation unit 28 if the control or regulation unit 28 receives a corresponding control signal from the at least one external unit 18 via the communication unit 16.

In the further method step 34, electrical energy is obtained from the warning signal of the smoke alarm device 14 by means of the energy generation unit 32 of the smoke alarm device 10. In the further method step 34 , electrical energy for data transmission between the smoke alarm device 10 and the at least one external unit 18 is obtained from the warning signal of the smoke alarm device 14 by means of the energy generation unit 32 . In the further method step 34, electrical energy obtained by means of the energy generation unit 32 is fed into the energy storage element.

In an additional method step 38 , information about a warning signal from the smoke alarm device 14 detected by the sensor unit 12 is transmitted to the at least one external unit 18 . It is conceivable that the external unit 18 comprises at least one output means, for example a screen, a loudspeaker, an LED, an incandescent lamp or the like, for outputting information about the detected warning signal, preferably to a user.

Claims (11)

Smoke alarm device (10) with at least one sensor unit (12) for detecting a warning signal of a smoke alarm device (14), with at least one communication unit (16) for data-technical communication with at least one external unit (18), in particular different from a smoke alarm device (14), and with at least one attachment unit (20) for an, in particular detachable, attachment to the smoke alarm device (14). Smoke alarm device (10) according to Claim 1, characterized in that the fastening unit (20) is intended for fastening the smoke alarm device (14) to a building structure (22). Smoke alarm device (10) according to Claim 1 or 2, characterized in that the sensor unit (12) has a vibration sensor (24) which is intended to detect vibrations which can be generated by an, in particular acoustic, warning signal of the smoke alarm (14). Smoke alarm device (10) according to one of the preceding claims, characterized in that the sensor unit (12) comprises at least one optical sensor (26) which is intended to detect an optical warning signal of the smoke alarm (14). Smoke alarm device (10) according to one of the preceding claims, characterized by a control or regulation unit (28) which comprises at least one machine learning module (30) which is set up to carry out an alarm recognition learning process. Smoke alarm device (10) according to one of the preceding claims, characterized by an energy generation unit (32) which is provided to generate electrical energy from the warning signal of the smoke alarm device (14). Method for operating and/or calibrating a smoke alarm device (10), in particular a smoke alarm device (10) according to one of the preceding claims, having at least one sensor unit (12) for detecting a warning signal of a smoke alarm device (14). Method according to Claim 7, characterized in that in a method step (34) vibrations which can be generated by an in particular acoustic warning signal from the smoke alarm device (14) are detected by means of a vibration sensor (24) in the sensor unit (12) of the smoke alarm device (10). Method according to claim 7 or 8, characterized in that in a method step (34) an optical warning signal of the smoke alarm device (14) is detected by an optical sensor (26) of the sensor unit (12) of the smoke alarm device (10). Method according to one of Claims 7 to 9, characterized in that in a method step (36) a machine learning module (30) of a control or regulation unit (28) of the smoke alarm device (10) carries out an alarm recognition learning process. Method according to Claim 10, characterized in that in a method step (34) electrical energy is obtained from the warning signal of the smoke alarm device (14) by means of an energy generation unit (32) of the smoke alarm device (10).

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