DE202010017770U1 - Monitoring device for monitoring a room - Google Patents

Abstract

Monitoring device (20 to 25) for monitoring a room, namely fire detector for monitoring a room and triggering a fire alarm, with at least one sensor and with a first radio means (11), a smoke sensor (2) being provided, the monitoring device (20 to 25) can be configured with further monitoring devices (20 to 25) after a first start-up via the first radio means (11) to a radio network, a measured value being detectable by the sensor, a smoke density being measurable by the smoke sensor (2), and wherein if a certain threshold value is exceeded or undershot, a message can be sent to at least one target address, a second radio means (7) being provided, the message being able to be sent to the target address via the second radio means (7), the second radio means (7) is designed for communication with a base station of a mobile radio network (26), a memory (10) being provided can be seen and the monitoring device (20 to 25) is assigned a unique identification feature, where ...

Description

The invention relates to a monitoring device, namely a fire detector with the features of the preamble of the protection claim. 1

In the prior art smoke detectors are known, which usually measure the smoke density and give a time-limited, audible alarm when exceeding a preset value, even those who also issue a wireless alarm to adjacent smoke detectors, which then also give an audible alarm and also which then forward this information to a single connected transmission unit, such as a telephone or a GSM mobile network, or a proprietary cable or network connection. If this audible alarm can not be heard due to absence, a causal fire continues to spread; If this single connected transmission unit is disturbed, a transmission does not take place.

From the US 6,624,750 B1 is a monitoring device, namely a smoke detector for monitoring a room and for triggering a fire alarm known. The smoke detectors have a photoelectric smoke sensor and a temperature sensor. An alarm is triggered if a specified smoke density threshold is exceeded or the ambient temperature exceeds 57 ° C. Each smoke sensor has a piezo loudspeaker with which an audible alarm can be generated. The smoke detectors are each equipped with a first radio, namely a transceiver for transmitting and receiving information by radio. The smoke detectors form a radio network. Furthermore, a transmission unit is also equipped with a first radio. The transmission unit can be connected via a telephone connection with a destination address, namely a monitoring center. Within the network, messages and information can either be forwarded directly to the transmission unit or forwarded from one smoke detector to the next smoke detector until the transmission unit is reached. The transmission unit sends the messages to the monitoring center. The existing smoke detectors network can therefore be connected via the individual transmission unit with the monitoring center.

The known from the prior art monitoring device is not yet optimally formed. If the transmission unit fails, no alarm signal can be sent to the monitoring center. The connection of the network to the monitoring center is therefore susceptible to interference.

From the generic DE 10 2006 041 363 A1 For example, a monitoring device in the form of an information transmission column is known. The column can thus be used as an emergency call device. The pillar has an emergency call button, a microphone and at least one speaker for passing information. Audio information can be recorded. The column has a camera, whereby the images recorded by the camera are transmitted to a central office when the emergency call button is pressed. The column has several sensors for detecting variations in environmental parameters. The sensors may be motion sensors, vibration sensors, smoke sensors, odor sensors, noise sensors, humidity sensors, inclination sensors or similar sensors. After detection of deviations from target values by the sensors, an alarm can be generated automatically via the loudspeaker. The column also has a warning light system. As a result, the column can serve as a fire detector. To carry out the communication, provision is made for the pillar to be provided with a radio installation for transmitting information between the column and an external central unit. The radio operation takes place via mobile radio or by means of a self-configuring ad-hoc radio network. If several columns are used by the same operator in spatial radio neighborhood, so are vzw for radio communication. self-configuring ad-hoc wireless networks.

From the DE 20 2008 012 528 U1 a robot system is known. The robot system serves as a monitoring device and as a fire detector. The robot system consists of several modules that are installed on the wall or on the ceiling. The individual robot modules are connected to each other via wireless communication. The robot system has a movable camera system. Each robot module has a computer unit, a CPU or a memory. The robot module is equipped with one or more sensors, for example a smoke, gas, acoustic, temperature, humidity, brightness, blast, motion or infrared sensor. Further, a microphone and a speaker may be provided. Via electrical lines or via radio signals, electrical devices, for example, lights or radio, stereos, fans, air conditioners, heaters, television, monitor can be controlled or regulated by the respective ceiling robot. The single robot module has a telephone module, the telephone module is able to call emergency numbers or other stored numbers in events. The phone module has an internal memory and can automatically run previously recorded texts and in an emergency call centers announce where and what an emergency it is. Further can be sent with the phone module SMS. It is possible to remotely manage the heating via the Internet. The robot system can take over a variety of functions, such as lighting management, door control, weather station, baby monitor, remote maintenance access, room monitoring or the function of a smoke detector. Alarm signals are forwarded to all robot modules via a radio link.

The connection of the network of monitoring devices to the monitoring center is not yet optimally formed.

The invention is therefore based on the object to design a monitoring device such and further, so that the susceptibility of the connection of the monitoring devices is reduced to a network external destination, in particular to a monitoring center.

This object is achieved for the monitoring device a monitoring device with the features of the protection claim 1. A second radio is provided, wherein the message on the second radio to the destination address is sendable. The second radio is designed for communication with a base station or a BTS. This has the advantage that the monitoring devices themselves act as a transmission unit. A separate transmission unit for sending the message to the destination address is no longer necessary. By sending the alarm information to the destination address, the message vzw. forwarded to a monitoring center. The destination address may be the address of the monitoring center or the address of a mobile telephone, landline telephone, an IP address or the like. The messages may be data, text, voice or video messages. Since all monitoring devices can provide a connection with the monitoring center via the second radio, the susceptibility of the connection of the network to the monitoring center is minimized. Even if one or more monitoring devices can not establish a connection to the monitoring center via the second radio, a message or alarm information about the first radio to the other monitoring devices are forwarded, so that the other monitoring devices via the second radio forward the message to the monitoring center can. A multiplicity of radio devices automatically interconnected to form a meshed network, which also function as transmission relays for each other, results in a lower susceptibility to interference in comparison to a single transmission unit. The system presented here is also designed in such a way that it checks itself periodically for its functional reliability. The entirety of the monitoring devices constitute a self-organizing monitoring and alarm system consisting of at least one, but in practice a plurality of similar monitoring devices, which are designed to be commissioned within a room unit to be secured - eg a dwelling or a building - Configure automatically to a meshed ad-hoc radio network with the aim of monitoring these premises for undesirable conditions arbitrarily metrologically, but also at the same time both acoustically and visually and chemically and when exceeding or falling below preset values, this state to a or several preset destination addresses or to report to the monitoring center. Such a monitoring device or such a monitoring and alarm system can also forward individually and periodically recurring measured values of other systems as relays such. As of electricity meters, water meters or thermocouples of heaters. The first radio is designed for local communication with the other monitoring devices. The first radio is vzw. designed as an ISM module. The second radio is designed for communication with an external base station of a particular public mobile radio network. In particular, the second radio means has a higher maximum transmission power than the first radio. The first radio is designed in particular as a short-range radio to short-range radio. Such short-range radio resources are also referred to as SRD (Short Range Device) or LPD (Low Power Device). The maximum transmission power of short-range radio is regulated in national regulations. For example. in Germany the maximum transmission power is 10 mW in the frequency range 433.05 to 434.79 MHz. The second radio is vzw. as a GSM module and / or formed as a UMTS module. The maximum transmission power of a GSM radio in the uplink is, for example, 2 watts. The aforementioned disadvantages are therefore avoided and corresponding advantages are achieved.

There are now a variety of ways to design and further develop the monitoring device according to the invention in an advantageous manner. For this purpose, reference may first be made to the claims subordinate to claim 1. In the following, a preferred embodiment of the invention will now be explained in more detail with reference to the drawing and the accompanying description. In the drawing shows:

1 in a very schematic representation an overview of the essential components of a monitoring device,

2 in a highly schematic representation of several connected to a wireless network monitoring devices, and

3 in a schematic diagram, a temperature-smoke density matrix.

In 2 are several monitoring devices 20 . 21 . 22 . 23 . 24 and 25 shown. The monitoring devices 20 . 21 . 22 . 23 . 24 and 25 are designed in particular identical. In 2 are six monitoring devices 20 to 25 shown. The number of monitoring devices 20 to 25 however, it can be less than or greater than six.

The monitoring devices 20 to 25 are used to monitor a room (not shown) and to trigger an alarm. The monitoring devices 20 to 25 are designed in particular as fire detectors for monitoring a room and triggering a fire alarm. Every monitoring device 20 to 25 is preferred for monitoring fires, but not mandatory to install centrally on each ceiling of a room to be monitored.

Based on 1 The following are the essential components of the monitoring devices 20 to 25 be explained:
Each of the monitoring devices described here 20 to 25 has vzw. a housing and a board (not shown).

The monitoring devices 20 to 25 have vzw. one controller each 1 on. The controller 1 serves to control and regulate the monitoring devices 20 to 25 , The monitoring devices 20 to 25 can each have an operating system and programs, with the operating system and the programs with the controller 1 are executable.

Every monitoring device 20 to 25 has at least one sensor. The sensor can be used in particular as a smoke sensor 2 be educated. As a measured value is with the smoke sensor 2 a smoke density detectable. The smoke sensor 2 can in particular be designed as an optical sensor (not shown in detail) and be arranged in a measuring chamber. In the measuring chamber light pulses are generated. These light pulses do not hit the optical sensor in the smokeless state of the measuring chamber. When smoke enters the measuring chamber, the light pulse is scattered by the smoke. The scattered light then falls on the optical sensor. The scattered light intensity is used to determine the smoke density.

The monitoring devices 20 to 25 have vzw. as another sensor a temperature sensor 3 on. As a measured value is with the temperature sensor 3 the ambient temperature of the monitoring devices 20 to 25 detectable.

The monitoring devices 20 to 25 have a piezoelectric element 4 on. About the piezo element 4 An audible alarm signal can be output if an alarm is triggered by exceeding or falling below a limit value.

The monitoring devices 20 to 25 have vzw. a speaker 5 on. The monitoring devices 20 to 25 have vzw. a microphone 6 on. Through the microphone 6 The rooms can be monitored acoustically. The monitoring devices 20 to 25 are with the speaker 5 and the microphone 6 used as a transmitting and / or receiving part of a baby monitor. Furthermore, with the speaker 5 and the microphone 6 provided a voice connection. It is conceivable a voice connection between different monitoring devices 20 to 25 and / or between one of the monitoring devices 20 to 25 and the destination address.

The monitoring devices 20 to 25 in particular, have a light source 8th on. The light source 8th is particularly switchable when an alarm is triggered. The light source 8th then illuminates the room to be monitored. The switched on light source 8th facilitates orientation especially when smoke has already entered the room. The linkage of the light source 8th Alarming makes it easier to find an escape route and therefore increases safety.

The monitoring devices 20 to 25 have a power source 9 , The power source 9 can be formed by batteries or rechargeable batteries.

The monitoring devices 20 to 25 have a first radio 11 on. The monitoring devices 20 together with the other monitoring devices 21 to 25 configure themselves after a first commissioning via the first radio 11 to a wireless network. This is in 2 through the connecting lines between the monitoring devices 20 to 25 indicated. The first radio 11 is vzw. for local communication with the other monitoring devices 20 to 25 educated. The first radio 11 is as a short-range radio vzw. designed as an ISM module. The first radio 11 has in particular a synchronization unit, so that the monitoring devices 20 to 25 immediately after switching vzw. synchronize via ISM band. When the monitoring devices 20 to 25 be turned on in turn, so within a certain initialization period, the send and Receive cycles of the first radio 11 coordinated.

The monitoring devices 20 to 25 have a memory 10 on. In the storage room 10 is a routing table storable. Furthermore, in memory 10 Preset thresholds are stored. Each of the monitoring devices 20 to 25 In particular, an individual identification feature is assigned. Within the initialization period, the identifier becomes with all neighbor monitors 20 to 25 to which about the first radio 11 a radio link of sufficient quality is possible, exchanged. In every monitoring device 20 to 25 a routing table is set up. The routing table is stored in memory 10 stored. The routing table contains information about all connection possibilities in the local radio network.

The monitoring devices 20 to 25 each have at least one control element 12 , vzw. several controls 12 on. With the control 12 An alarm can be switched off.

The monitoring devices 20 to 25 each have an internal bus system 13 on. The bus system is used for data transfer between several modules and the controller 1 , The bus system 13 in particular connects several slots, with additional modules can be added to the slots. The monitoring devices 20 to 25 can be individually adapted and retrofitted or upgraded with additional modules. This opens up a variety of uses for the monitoring devices 20 to 25 ,

The monitoring devices 20 to 25 have vzw. a camera 14 on. Through the camera 14 the room to be monitored can be viewed. That from the camera 14 recorded image can be over the first radio 11 be forwarded within the radio network. The camera 14 is vzw. via a slot with the bus system 13 connected. The camera 14 can be used to monitor the burglary of the room.

Furthermore, the monitoring devices 20 to 25 a motion detector 15 exhibit. Furthermore, the monitoring devices 20 to 25 a light sensor 16 exhibit. The motion detector 15 is vzw. via a slot with the bus system 13 connected.

Furthermore, the monitoring devices 20 to 25 a gas sensor 17 exhibit. A fire creates carbon dioxide. The gas sensor 17 can be designed for the detection of carbon dioxide. It is conceivable that the monitoring devices 20 to 25 additional sensors 18 exhibit. The gas sensor 17 and / or the other sensors 18 are vzw. via a slot with the bus system 13 connected.

If it exceeds or falls below a certain threshold value, a message with alarm information can be sent to at least one destination address. This is in 2 by the one of the monitoring device 21 outgoing arrow (unspecified) indicated.

The aforementioned disadvantages are now avoided by having a second radio 7 is provided (cf. 1 ), wherein the alarm information about the second radio 7 can be sent to the destination address. This has the advantage that the monitoring devices 20 to 25 all can separately send the alarm information of the ad hoc network to the destination address. The second radio 7 is designed in particular as a GSM module and / or as a UMTS module. The second radio 7 has a SIM card. The second radio 7 sends the alarm information to an external base station (not shown) of a mobile network 26 , About the mobile network 26 becomes the alarm information 26 to the monitoring center 50 forwarded.

The monitoring center 50 has vzw. a mobile phone access 51 , in particular a GSM / UMTS access. About the mobile network 26 and the mobile phone access 51 are the alarm information and other messages, for example. By SMS and / or MMS the monitoring center 50 be fed. Furthermore, a voice connection can be made to each of the monitoring devices 20 to 25 over the mobile network 26 being constructed. Every monitoring device 20 to 25 is assigned a unique identification feature (not shown). Every monitoring device 20 to 25 has a SIM card with a phone number. The phone number serves vzw. as an identification feature.

The monitoring center 50 has internet access 52 on. The internet access 52 can be provided through a DSL connection and a computer. The second radio 7 can send a message over the mobile network 26 and via a suitable interface to the Internet 27 and continue via the Internet access 52 the monitoring center 50 forward.

The monitoring center 50 has a fixed telephone network access 53 also known as Public Switched Telephone Network (PSTN) access. The telephone landline access 53 can via the second radio 7 and corresponding interfaces are contacted. The second radio 7 can have a voice connection over the mobile network 26 and the PSTN network 28 to the monitoring center 50 produce.

By sending the alarm information to the destination address, the alarm information vzw. to the monitoring center 50 forwarded (cf. 2 ). Because all monitoring devices 20 to 25 a connection to the monitoring center 50 over the second radio 7 can provide, is the susceptibility of the connection of the network to the monitoring center 50 minimized. Even if one or more monitoring devices 20 to 25 no connection to the monitoring center 50 over the second radio 7 may provide an alarm information or other message about the first radio 11 to the other monitoring devices 20 to 25 be forwarded so that the other monitoring devices 20 to 25 over the second radio 7 the alarm information to the monitoring center 50 can forward. Due to the large number of each other, radio technology automatically combined into a meshed radio network monitoring devices 20 to 25 , which also act as a relay for each other, results in a lower susceptibility to interference compared to a single transmission unit. The system presented here is vzw. It is also designed to periodically check itself for its functional safety.

The monitoring devices 20 to 25 are turned on after the installation in sequence. After switching on, a predefined initialisation period begins. The initialization period can be, for example, about 5-10 minutes. Within the initialization period, after switching on, all monitoring devices synchronize 20 to 25 in turn via the first radio 11 , So in particular by ISM band so that they tune the transmission and reception cycles to each other, the respective once assigned identification feature vzw. the SIM card numbers with all neighbor monitoring devices 20 to 25 , to which a radio link of sufficient quality is possible, exchange and store in their routing table.

After completing this procedure vzw. over the controller 1 the second radio 7 , in particular the GSM / UMTS modules switched on and causes to connect with the respective BTS of the mobile network operator. Vzw. In the process, the connection quality is achieved via the second radio 7 destined for BTS. The connection quality via the second radio 7 is verifiable, namely whether a direct connection to a base station of the mobile network 26 consists. The connection quality is vzw. to the controller 1 and to the store 10 passed. The memory 10 is vzw. designed as a flash memory. This has the advantage of having data in memory 10 , For example, the routing table and the matrix are stored non-volatile, ie storable without permanent supply voltage.

Vzw. represents each monitoring device 20 to 25 Notice how good their connection is via the second radio 7 or their GSM / UMTS connection in the respective mobile network 26 is. The quality of the connection is due to the spatially different location in the apartment or building due to the associated greater or lesser attenuation by the building better or worse, or even completely insufficient for any GSM / UMTS connection to the BTS.

In the event that one of the second radio 7 or a GSM / UMTS module of a monitoring device 20 to 25 can not establish a sufficient connection to a BTS, shares this monitoring device 20 to 25 vzw. the other monitoring devices 20 to 25 to which this monitoring device 20 to 25 a good connection via the first radio 11 or via the ISM connection according to the routing table, this with.

Vzw. the neighbor monitor turns on 20 to 25 with the best connection via the first radio 11 or with the best ISM connection (high signal level, low bit error rate) to the monitoring device 20 to 25 that do not connect via the second radio 7 or can not establish a GSM / UMTS connection, as a relay for this one.

This has the consequence that all messages such as a cyclically queried function check result of the own system, the battery state of charge, the exceeding of a preset measured value, the bidirectional voice transmission, the image transmission of the camera 14 and other readings about the first radio 11 - by ISM band - from the "connectionless" monitoring device 20 to 25 that does not have a GSM / UMTS connection, this "connected" neighbor monitor 20 to 25 that has "relayed" as a relay relayed to this neighbor monitoring device 20 to 25 then these messages to the monitoring center 50 transmitted.

Vzw. shows each monitoring device 20 to 25 after completing the configuration of any number of installed monitoring devices 20 to 25 to a meshed radio network optically by indicating cyclic lighting od. Like. At whether the meshed radio network is fully configured or not yet.

Vzw. measures every surveillance device 20 to 25 After successful configuration of the meshed radio network, the respective smoke density should be determined at sufficiently short intervals via the specially designed smoke sensor 2 and at the same time the respective temperature via the temperature sensor 3 , When a temperature threshold is exceeded and a smoke threshold value is exceeded, an alarm can be triggered.

It is particularly advantageous that the temperature threshold value is dependent on the smoke density and / or the smoke density threshold value is dependent on the temperature. This has the advantage that false alarms are significantly reduced.

The monitoring device 20 to 25 has a memory 10 on, being in memory 10 a matrix is stored. The matrix contains combination values, whereby one of the combination values can be assigned by means of the matrix to the measured temperature and the measured smoke density. The combination value indicates the overshoot or undershoot of the temperature threshold and / or the smoke density threshold value.

The measured temperature and the measured smoke density are compared with temperature and smoke density dependent thresholds. The measured temperature and smoke density are thereby correlated with each other. The measured temperature and smoke density are correlated with each other in their dynamic course. The correlation is vzw. by means of in 3 represented matrix.

The combination values provide a measure of the fire probability taking into account the correlation of the temperature and the smoke density. By means of the matrix, the measured temperature and the measured smoke density can each be assigned to one of the combination values. Depending on the coordination value, an alarm can be triggered.

The temperature threshold drops with increasing smoke density. The higher the measured smoke density, the lower measured temperatures are sufficient to trigger an alarm. The temperature threshold is a vzw. monotonically decreasing function of smoke density.

The smoke density threshold drops with increasing temperature. The higher the temperature, the lower the smoke density values are sufficient to trigger an alarm. The smoke density threshold is a vzw. monotonically decreasing function of temperature.

If the smoke density threshold and / or the temperature threshold are present as a mathematical function, they can be used with the monitoring device 20 to 25 calculated for each measured temperature and smoke density. In the following, however, a simpler method is described in which the threshold values do not have to be recalculated each time, but the overshoot and undershoot of the smoke density thresholds and the temperature threshold values can be determined using a matrix.

Each column of the matrix is assigned a ratio or ratio interval of the measured smoke density to a maximum smoke density threshold in percent. If this ratio is 100%, or the measured smoke density value exceeds the maximum smoke density threshold, an alarm is triggered.

If the measured smoke density is less than the maximum smoke density threshold, the correlation with the matrix is determined. Each line of the matrix is assigned a temperature or a temperature interval, for example 25 ° C to 27.5 ° C or 27.5 ° C to 30 ° C. Each pair value consisting of the measured smoke density and the measured temperature can thus be assigned a combination value. The matrix contains the combination values. The combination value indicates the overshoot or undershoot of the temperature threshold and / or the smoke density threshold value.

The combination values therefore depict the correlation of the smoke density with the temperature. In 3 is a boundary line (unspecified) drawn, this limit shows that the temperature threshold depends on the smoke density and the smoke density threshold is dependent on the temperature. All pair values consisting of the measured smoke density and the measured temperature below the limit line trigger an alarm. All pair values above the limit line do not trigger an alarm.

This matrix ( 3 ) maps the empirical smoke density values as well as the empirical temperature values to a combined value. From the combination value can be concluded with sufficient probability in each case on a fire. This matrix itself is a separate invention as well as a part of the invention described here.

Thus, fires are recognized by their increasingly dynamic heat development, even if the derivation from the smoke density alone still does not allow a sufficient maximum threshold for a fire, but the parallel actual development of the smoke density in comparison with the temperature development and vice versa.

Also, according to the invention, fires are recognized not only by their increasingly dynamic smoke density, but even before a maximum threshold value for smoke density is reached, since a sufficiently dynamic increase in temperature already indicates this in parallel.

Vzw. will also reach only a preset threshold when measured by one of the monitors 20 to 25 , queried as the measurements of the other, the radio cluster belonging monitoring devices 20 to 25 even if they have not yet reached a threshold value set there. At the same time a vzw. digital image of one of the ones with a camera 14 equipped monitoring devices 20 to 25 taken and sent to the monitoring center 50 for example, be sent by MMS. Should via the second radio 7 a GSM / UMTS connection or other connection of this monitoring device 20 to 25 in the mobile network 26 or another network does not exist, it will be over the first radio 11 (ISM module) or another cable to one or more monitoring devices 20 to 25 so clever that the monitoring devices 20 to 25 with a mobile connection via the second radio 7 (GSM / UMTS or similar) also make the image transmission (MMS).

The same applies to the case when a threshold value in one of the monitoring devices 20 to 25 is reached. For the monitoring devices 20 to 25 is vzw. adjustable, in which order individual actions are executed:
For example, initially an audible alarm about the / the piezo elements 4 in the one monitoring device 20 to 25 , which has measured this threshold exceeded triggered.

It can then do the others, via the first radio 11 reachable or by radio (ISM) controlled monitoring devices 20 to 25 to be notified to the unit of the local radio cluster, so that the other monitoring devices 20 to 25 also trigger an audible alarm.

If the audible alarm is not mechanical over any of the controls 12 within a predefined period z. B. 30 to 60 seconds is turned off, via the second radio 7 a GSM / UMTS alarm from one or all of the cluster belonging monitoring devices 20 to 25 discontinued. Alternatively, only predefined particular individual monitoring devices 20 to 25 the alarm via the second radio 7 drop.

These actions can also take place in reverse order of time or in parallel; this is individually scalable.

The same applies to the construction of a vzw. bidirectional voice connection via the second radio 7 or by GSM / UMTS to any presettable telephone line or even several, both temporally parallel and sequential and vzw. also by SMS or other digital transmission to an arbitrary presettable addressee such. B. also to one or more automatic devices for further cause.

In summary, the following can be stated:
In the basic equipment are monitoring devices 20 to 25 similarly formed. The monitoring devices 20 to 25 are used for smoke density monitoring in simultaneous comparison with temperature monitoring. The measured smoke densities and the measured temperatures are correlated with each other. In particular, a combination value is assigned to these pair values. Based on the combination value is initially an audible alarm and parallel or later on via a second radio 7 Radio alarm can be triggered. The second radio 7 can be designed as a GSM module.

It is envisaged that several of the monitoring devices 20 to 25 within a defined initialization period after the first startup with each other via a first radio 11 so communicate that in each monitoring devices 20 to 25 a routing table is generated. From the routing table, any monitoring devices 20 to 25 read off if this monitoring device 20 to 25 even directly via the second radio 7 can set off a (GSM) radio alarm or this - eg due to the damping by masonry - only via another monitoring device 20 to 25 can be done as a relay, from the routing table, any monitoring devices 20 to 25 also read for which other of the monitoring devices 20 to 25 of the resulting meshed radio cluster this monitoring device 20 to 25 may even have to act as a relay. The routing table contains information about all connections within the network via the first radio 11 and vzw. Information about all possible connections via the second radio 7 to the BTS.

These so radio technically interconnected to a meshed radio cluster or radio network monitoring devices 20 to 25 are specially designed so that in case of one to the monitoring center 50 outgoing alarm - vzw. GSM radio alarm - even one of the monitoring devices 20 to 25 also all other monitoring devices belonging to the cluster 20 to 25 such an alarm - vzw. GSM radio alarm - trigger. The respective measured values of the individual monitoring devices 20 to 25 be sent to this monitoring center 50 transfer. The network or cluster or radio cluster is replaced by the first radio 11 educated. The monitoring center 50 initiates an intervention, for example, by the fire brigade or the police and passes on the respective measured values from all rooms to the intervention forces.

Vzw. contains every monitoring device 20 to 25 a unique identification feature, for example. A SIM card or a SIM chip to the user in each case the exact position in the building immediately after installation to the monitoring center 50 is transmitted.

Every monitoring device 20 to 25 contains vzw. a speaker 5 and a microphone 6 , driven by either the second radio contained 7 - the GSM module - or where the second radio 7 no connection to the mobile network 26 has, driven by the first radio 11 - The ISM module - so that with all the cluster belonging to the monitoring device 20 to 25 a bi-directional voice connection to the monitoring center 50 or to another destination address is established.

The monitoring device 20 to 25 contains a light source B. The light source 8th can be designed in particular as an LED. In the event of an alarm, the LED or light source lights up 8th in each monitoring device belonging to the cluster 20 to 25 , Each of the monitoring devices 20 to 25 is vzw. scalable to accommodate additional modules such as the motion detector 15 and the camera 14 (for burglary monitoring) but also from the gas sensors 17 or from other sensors 18 suitable.

A remote control allows the switching on and off of individual modules and their functions such as a remote monitoring of a baby monitor via one or more mobile phones 54 and / or Internet-connected facilities. The remote control is vzw. as a radio remote control for communication via the first radio 11 educated. Vzw. the remote control is designed as an ISM remote control.

GSM

= Global System for Mobile Communication

GPRS

= General Packed Radio Service

UMTS

= Universal Mobile Telecommunication System

EDGE

= Enhanced Date Rates for GSM Evolution

ISM

= Industrial Scientific and Medical Band

SMS

= Short Message Service

MMS

= Multimedia Messaging Service

PSTN

= Public Service Telephone Network

IP

= Internet Protocol

DSL

= Digital Subscriber Line

BTS

= Base Transceiver Station

For the purpose of the present invention, the following abbreviations and expressions are to be understood as follows:

GSM

= Global System for Mobile Communication

GPRS

= General Packed Radio Service

UMTS

= Universal Mobile Telecommunication System

EDGE

= Enhanced Date Rates for GSM Evolution

ISM

= Industrial Scientific and Medical Band

SMS

= Short Message Service

MMS

= Multimedia messaging service

PSTN

= Public Service Telephone Network

IP

= Internet Protocol

DSL

= Digital Subscriber Line

BTS

= Base transceiver station

LIST OF REFERENCE NUMBERS

1

controller

2

smoke sensor

3

temperature sensor

4

piezo element

5

speaker

6

microphone

7

second radio

8th

light source

9

power source

10

Storage

11

first radio

12

controls

13

Bus system

14

camera

15

motion detector

16

light sensor

17

gas sensor

18

additional sensors

20

monitoring device

21

monitoring device

22

monitoring device

23

monitoring device

24

monitoring device

25

monitoring device

26

mobile network

27

Internet

28

PSTN

50

monitoring center

51

mobile access

52

Internet access

53

Fixed telephone access

54

mobile phone

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• US 6624750 B1 [0003]
• DE 102006041363 A1 [0005]
• DE 202008012528 U1 [0006]

Claims (8)

Monitoring device ( 20 to 25 ) for monitoring a room, namely fire alarm for monitoring a room and triggering a fire alarm, with at least one sensor and with a first radio ( 11 ), whereby a smoke sensor ( 2 ) is provided, wherein the monitoring device ( 20 to 25 ) with further monitoring devices ( 20 to 25 ) after a first startup via the first radio ( 11 ) is configurable to a radio network, wherein a measured value can be detected with the sensor, wherein with the smoke sensor ( 2 ) a smoke density is measurable, and wherein a message is sendable to at least one destination address if it exceeds or falls below a certain threshold value, wherein a second radio ( 7 ), the message about the second radio resource ( 7 ) is sendable to the destination address, wherein the second radio ( 7 ) for communication with a base station of a mobile radio network ( 26 ), wherein a memory ( 10 ) and the monitoring device ( 20 to 25 ) is assigned a unique identification feature, wherein a loudspeaker ( 5 ) and a microphone ( 6 ), wherein a bidirectional voice connection to the monitoring center ( 50 ) or to another destination, whereby a camera ( 14 ), wherein the messages are data, text, voice or video messages, characterized in that within an initialization period via the first radio ( 11 ) with further monitoring devices ( 20 to 25 ) the identification features are exchangeable, whereby a routing table can be generated and stored in the memory ( 10 ) is storable, wherein the monitoring device ( 20 to 25 ) for receiving messages from other monitoring devices ( 20 to 25 ) via the first radio ( 11 ) is formed and these messages via the second radio ( 7 ) are forwarded to the destination address, wherein the connection quality via the second radio ( 7 ) is verifiable, whereby it is verifiable whether a direct connection to a base station of the mobile network ( 26 ) consists. Monitoring device according to claim 1, characterized in that the first radio ( 11 ) is designed as a short-range radio means, in particular as an ISM module. Monitoring device according to claim 1 or 2, characterized in that the second radio ( 7 ) is designed as a GSM module and / or as a UMTS module. Monitoring device according to one of the preceding claims, characterized in that a temperature sensor ( 3 ) is provided, wherein with the temperature sensor ( 3 ) a temperature is measurable Monitoring device according to one of the preceding claims, characterized in that when a temperature threshold value is exceeded and / or when a smoke density threshold value is exceeded, an alarm can be triggered, the temperature threshold value being dependent on the smoke density and / or the smoke density threshold value being dependent on the temperature. Monitoring device according to one of the preceding claims, characterized in that in the memory ( 10 ) is stored a matrix, wherein the matrix contains combination values, wherein by means of the matrix of the measured temperature and the measured smoke density one of the combination values can be assigned, wherein the combination value indicates the exceeding or falling below the temperature threshold and / or the smoke density threshold value. Monitoring device according to one of the preceding claims, characterized in that a gas sensor ( 17 ) is provided. Monitoring device according to one of the preceding claims, characterized in that a light source ( 8th ), in particular an LED is provided, wherein the light source ( 8th ) can be activated by triggering the alarm.

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