JP2003132450A - Measured data transmitter and fire alarm supporting system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a compact measured data transmitter to be easily set at low costs capable of intermittently transmitting measured data for a long period, especially, a temperature data transmitter for supporting a fire alarm and a fire alarm supporting system. SOLUTION: This fire alarm supporting system 10 is provided with a measurement mode for acquiring measured data, a transmission mode for wireless transmission of the acquired measured data, and a stand-by mode for switching to the measurement mode or the transmission mode. This system is provided with a sensor tag 12 for transmitting the acquired measured data in the measurement mode and the transmission mode as a transmitter, and the sensor tag 12 is provided with a power supply part having a solar battery 32 for supplying power in the measurement mode and a battery 34 being a primary battery for mainly implementing power supply in the transmission mode.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a measurement data transmitting device for performing measurement by a sensor, obtaining measurement data, and intermittently wirelessly transmitting the obtained measurement data. For example, a fire may occur in a room. TECHNICAL FIELD The present invention relates to a transmitter for intermittently wirelessly transmitting temperature data for fire alarm support for detecting fire and alarming the fire, and a fire alarm support system using this device.

[0002]

2. Description of the Related Art Today, it is obligatory to install a fire alarm in a building or the like. Further, in the case of a room where a plurality of server computers are arranged, it is necessary to perform strict and sufficient room temperature monitoring in order to minimize the loss of information stored in the computer. Therefore, fire alarms are installed in every corner of the room to monitor abnormalities before a fire occurs.
Early detection of fire is desired.

By the way, as for the fire alarm to be installed at present, it is obligatory to install a wired fire alarm, so when installing the fire alarm in a room,
The fire alarm signal cable must be laid.
Particularly in the case of a room where a plurality of server computers are arranged, it is necessary to install a large number of fire alarms in every corner of the room in order to perform strict monitoring. In such a case, a large number of fire alarm cables are bundled and become very complicated, and in addition, cable laying work must be performed in response to a change in computer arrangement.

[0004]

Under such circumstances, not only in single-family homes that are not required by law for fire prevention and early detection of fire, but also in places where fire alarms are obligatory by law. In addition to the fire alarm, it is desired to provide a fire alarm support system capable of finely monitoring the possibility of fire occurrence. For example, a telemeter system with a temperature sensor has been proposed. However, in this telemeter system, since the occurrence of a fire is notified by using the wireless transmission device, if the power of the wireless transmission device is supplied through the power cable, the complicated work of laying the power cable is required. On the other hand, in the case of the conventional telemeter system that wirelessly transmits the battery as electric power, it does not require the installation of a power cable, which can greatly reduce the labor of installation, but the battery life is extremely short and the battery is frequently used. There was also the problem that it would have to be stretched if it was not replaced. In particular, it is not possible to secure the life of the battery for at least one year as a transmitter that supports fire notification. Such a problem is a problem common to measurement data transmitters that measure data for a long time and intermittently wirelessly transmit the measurement data.

Therefore, in order to solve the above problems, the present invention is capable of wirelessly transmitting measurement data intermittently for a long period of time, can be easily installed, and is a compact measurement data transmission device, for example, An object of the present invention is to provide a temperature data transmission device for supporting fire notification and a fire notification support system.

[0006]

To achieve the above object, the present invention provides a measurement mode for acquiring measurement data, a transmission mode for wirelessly transmitting the acquired measurement data, and the measurement mode or the transmission mode. A measurement data transmitting device which has a standby mode for waiting for switching of the measurement data, and which transmits the acquired measurement data intermittently in the measurement mode and the transmission mode, wherein A measurement data acquisition unit that acquires measurement data output by this sensor; a transmission unit that wirelessly transmits at least a part of the measurement data acquired by the measurement data acquisition unit in the transmission mode; Mainly for the power supply in the measurement mode and the standby mode. Nau and the solar cell, providing a measurement data transmission apparatus, characterized in that it comprises a power supply unit and a mainly conducts primary battery supplying power in the transmission mode.

At this time, the sensor is a temperature sensor that outputs temperature data, and the measurement data acquisition unit, the transmission unit, and the control unit are constituted by a circuit formed on one surface of the mounting board. The temperature sensor is preferably provided on the other surface of the mounting board and integrated with the mounting board.

Further, the present invention provides a plurality of the measurement data transmitting devices, one receiving device for receiving the temperature data transmitted from the measurement data transmitting device, and notification of the risk of fire occurrence from the received temperature data. There is provided a fire notification support system characterized by comprising:

At this time, it is preferable that the control unit switches to the transmission mode at a time interval that randomly changes around a predetermined time interval. Further, the control unit has, as the predetermined time interval, a first time interval and a second time interval shorter than the first time interval, and the temperature data or the time change of the temperature data. Is less than or equal to a predetermined value, the control unit selects the first time interval,
More preferably, the control unit selects the second time interval when the temperature data or the time change of the temperature data exceeds a predetermined value. Further, it is preferable that the measurement data transmission device transmits at least the unique identification data assigned to each device together with the temperature data.

[0010]

BEST MODE FOR CARRYING OUT THE INVENTION A fire alarm support system of the present invention using the measurement data transmitting device of the present invention will be described below.
A detailed description is given based on the preferred embodiments shown in the accompanying drawings.

FIG. 1 is a conceptual diagram of a fire alarm support system (hereinafter referred to as this system) 10 which is an example of the fire alarm support system of the present invention. The system 10 is
A plurality of thin plate-shaped sensor tags 12 (sensor tags 12a to 12c are shown in the figure) attached to a desired installation location in a room and intermittently wirelessly transmitting measured temperature data, and a plurality of sensors. A receiver 14 that receives the temperature data transmitted from the tag 12, a computer 16 that classifies the received temperature data into each of the plurality of sensor tags 12 and monitors the temperature at the measured position and the temperature change.
It has a buzzer 18 for notifying the degree of danger of fire occurrence according to the measured temperature or temperature change.

As shown in FIG. 2, each of the sensor tags 12 has a temperature sensor 20 and A / A that acquires the temperature data output from the temperature sensor 20 as digital data.
A D conversion circuit 22 (measurement data acquisition unit), a control circuit 24 (control unit) that generates a timing signal for transmitting A / D converted temperature data, and controls wireless transmission of temperature data, and temperature data. Oscillator circuit 26 for transmitting
The power supply control circuit 30 includes a (transmission unit), an antenna 28, and a power supply control circuit 30 for driving the above circuit.
It is connected to a power supply unit including a solar cell 32 and a battery 34 that is a primary cell.

Here, the A / D conversion circuit 22 and the control circuit 2
4, oscillator circuit 26, antenna 28 and power supply control circuit 3
0 is a known monolithic microwave integrated circuit (MMI) which is a well-known IC design technology on a chip such as a Ga-As substrate.
Each circuit is formed into an IC by using the technique C). Then, this chip is mounted on a circular mounting substrate 36 having a diameter of, for example, 25 mm, and its mass is also very light, for example, 5 g, and it is made compact. From the viewpoint of realizing a compact structure, such a mounting board 36 preferably has a diameter of 50 mm or less, more preferably 30 mm or less, and the mounting board 36 and the A / D conversion circuit 22. , Control circuit 24, oscillator circuit 2
6, the mass including the antenna 28 and the power supply control circuit 30 is preferably 10 g or less, more preferably 7 g.
It should be: On the other hand, the temperature sensor 20 is attached to the surface opposite to the circuit formed on the surface of the mounting board 36, and is connected to the circuit of the mounting board 36 through a hole 38 drilled at substantially the center of the mounting board 36. It is fixed. That is, the temperature sensor 20 is integrated with the mounting board 36. In this way, the temperature sensor 20 is provided on the surface opposite to the surface of the mounting substrate on which the circuit is formed, because the temperature on the circuit side still rises due to the heat generated from the circuit despite the compact circuit configuration. Is. Accordingly, the temperature sensor 20 can accurately measure the temperature.

The temperature sensor 20 is a sensor that outputs temperature data for detecting a temperature rise and a temperature change due to a fire, and has a size of several mm capable of measuring temperature in the range of -40 ° C to + 120 ° C. It is formed by a semiconductor temperature sensor or a resistance element type temperature sensor. The temperature data output by the temperature sensor 20 is used as the A / D conversion circuit 22.
Is supplied to.

The A / D conversion circuit 22 is a known conversion circuit that converts temperature data into, for example, an 8-bit digital signal at predetermined time intervals. As will be described later, the control circuit 24 is a device that generates a timing signal for switching to the transmission mode and controls the timing of temperature data transmission. As shown in FIG. 3, the control circuit 24 generates a timing signal that generates a timing signal for driving the A / D conversion circuit 22 and the oscillation circuit 28 by randomly varying the signal generation time interval around a predetermined time interval. Circuit 40
And the I assigned uniquely to each of the sensor tags 12.
An identification signal generation circuit that stores an identification ID signal corresponding to the identification data representing the D number and an identification signal such as a word signal for preventing malfunction and calls the identification signal according to the timing signal to generate the identification signal. 42 and a CPU (central processing unit) 44 that controls these circuits. Here, the timing signal generation circuit 40 generates two kinds of predetermined time intervals T ₁ by generating random numbers.
The timing signal is generated at random time intervals centered on one of T ₂ and T ₂ . Here, the time intervals T ₁ and T ₂ are, for example, 10 minutes for T _{1 and 1} for T _2.
5 seconds.

The CPU 44 obtains the temperature and the time change of the temperature from the temperature data supplied from the A / D conversion circuit 22. When the temperature and the time change of the temperature are less than a predetermined value, the CPU 44 determines that the state is normal, and When the temperature or the time change of the temperature exceeds a predetermined value, it is determined as an abnormal state, and the timing signal generation circuit 4
The timing signal generation time interval at 0 is randomly varied as described above in the normal state, for example, at intervals of T ₁ = 10 minutes, and in the abnormal state, as described above,
For example, the timing signal generation circuit 40 is controlled so as to randomly fluctuate around an interval of T ₂ = 15 seconds. The identification signal such as the identification ID signal and the word signal stored in the identification signal generation circuit 42 is a signal in which 0 and 1 having a specific bit number are continuously arranged according to a predetermined rule. The word signal is, for example, a signal in which 0s are arranged in 10 bits and then blocks in which 1s are arranged in 10 bits are repeatedly arranged 3 blocks. Since such a signal is a signal that is hardly transmitted in communication, it is possible to reduce erroneous recognition as to which temperature sensor the received signal is.

The oscillation circuit 26 starts driving based on the timing signal to generate a carrier wave, and at the same time, A / D
Temperature data sent from the conversion circuit 22 and the control circuit 2
4 is a circuit that uses the identification signal sent from the transmission signal No. 4 as a transmission signal, modulates a carrier signal based on this transmission signal, and sends the modulated carrier signal to the antenna 28 to be radiated as a radio wave. As the antenna 28, various antennas such as a loop antenna having a conductor formed in a loop shape, a linear antenna, a microstrip antenna, and a slot antenna are used. In this way, the timing signal generation circuit 4
The timing signal generated at 0 is a predetermined time interval, for example, 10 minutes interval (T ₁ ) in the normal state, 15 in the abnormal state.
Since the random fluctuation occurs around the second interval (T ₂ ), the transmission timings of the transmission signals transmitted from the sensor tags 12a to 12c are different, and the transmission signals do not interfere with each other.

The power supply control circuit 30 includes the A / D conversion circuit 2
2. A circuit that controls electric power for driving the control circuit 24 and the oscillation circuit 26.
And a battery 34, which is a primary battery composed of a button battery, are used together with a smoothing circuit, a full-wave rectifying circuit, or a half-wave rectifying circuit.

The solar cell 32 and the battery 34 form a compact power supply unit corresponding to the above compact circuit configuration. For example, the battery 34 is, for example, CR-
2032 (coin type lithium manganese dioxide battery) is used. On the other hand, the solar battery 32 is a compact battery that generates an electromotive force by lighting or outside light in the room where the sensor tag 12 is attached and supplies a current of, for example, 100 μA, and is composed of a photocell of, for example, about 10 mm × 10 mm. Has been done.

The solar cell 32 is mainly in a measurement mode for acquiring measurement data and other operations except for the generation of the clock signal of the CPU 44 of the control circuit 24 in a sleep state, and waits for switching to the measurement mode or transmission mode. Used in standby mode. The measurement mode is a mode in which the output from the temperature sensor 20 is A / D converted to obtain temperature data, and the A / D conversion circuit 22 and the control circuit 24 may be driven, and the oscillation circuit 36 is driven to generate a carrier signal. It requires less power than the transmission mode for generating and transmitting radio waves. Further, even in the standby mode, it is sufficient to drive only the control circuit 24, and thus less electric power is required than in the transmission mode. For example, in the measurement mode and the standby mode, only a current of several tens of μA is required at most. Therefore, 1
It is sufficient to use the solar cell 32 that supplies a current of about 00 μA. The battery 34 mainly includes the A / D conversion circuit 2
2 is used in a transmission mode in which the measurement data acquired in 2 is wirelessly transmitted, and is used when driving the oscillation circuit 26 that requires relatively large power.

Since the oscillation circuit 26 transmits temperature data and identification signals using radio waves, it requires relatively large electric power that cannot be supplied by the solar cell 32.
Current of the antenna 28 as described above.
Since it suffices to radiate the radio wave intermittently, the electromotive force of the battery 34 can be restored during the period when the radio wave is not radiated. For example, when a CR-2032 coin-type battery, which has only about 1 hour when using a current of 200 mA, is used as a power supply unit of the oscillation circuit 26, it does not emit radio waves, that is, a measurement mode or a standby mode period. Since the solar cell 32 is used inside, a life of 1 to 2 years can be secured.

As described above, the various circuits mounted on the mounting substrate 36, the temperature sensor 20, and the solar cell 32 and the battery 34 for supplying electric power to the various circuits are housed in the housing to form the thin plate-shaped sensor tag 12. To do. Of course, in the case,
Holes are formed so that the temperature sensor 20 can directly contact the outside air and the solar cell 32 can receive light.

As shown in FIG. 4, the receiving device 14 is composed of an antenna 50, an amplifying circuit 52 and a demodulating circuit 54. As the antenna 50, various antennas such as a loop antenna in which a radiated electric body is formed in a loop, a linear antenna, a microstrip antenna, or a slot antenna are used. The amplifier circuit 52 is a circuit that amplifies a signal received by the antenna, and is an FET or the like.
Is a circuit having a filter for detecting the received signal and reproducing the temperature data and the identification signal. The reproduced temperature data and the identification signal are sent to the computer 16.

Here, the electric wave radiated from the antenna 28 is a weak electric wave whose power consumption is 200 mW, for example, and the range in which transmission and reception is possible is within several tens of meters. The radio wave radiated from the antenna 28 is, for example, 2.4.
Microwaves or 3 in the frequency band of 5 GHz to 5.8 GHz
It is an ultra-high frequency wave having a center frequency of 15 MHz. By using the radio waves in the ultra-high frequency band or the microwave band, the size of the antenna and various circuits can be reduced, and the compact sensor tag 12 can be formed.

The computer 16 classifies the temperature data for each sensor tag 12 based on the temperature data reproduced by the receiving device 14 and the identification signal, and obtains the temperature at the installation position of each sensor tag 12 and the time change of the temperature. Based on this temperature and the change in temperature over time, the current risk is determined from the risk of fire occurrence divided into multiple stages. When the degree of risk is high to some extent, the position of the sensor tag 12 having a high degree of danger is displayed using the monitor of the computer 16 according to the degree of the degree of danger, and the degree of danger is notified, and the degree of danger further increases. When it is determined that a fire is extremely high, the buzzer 18 is configured to give an alarm sound. Moreover, you may notify by light. That is, the computer 16 and the buzzer 18 form a notification means. Further, even in the normal state, the temperature data is transmitted from the sensor tag 12 at random time intervals centered on, for example, 10-minute intervals.
The computer 12 can determine the presence or absence of the failure of item 2, and the failed sensor tag 12 can be displayed on the screen of the computer 12.

In the present system 10 as described above, the sensor tag 12 in which the temperature sensor 20 is integrated with the mounting substrate 36 is installed at a desired position. Of course, the temperature sensor 20 is installed so as to come into contact with the outside air.

In the sensor tag 20, first, the temperature data output from the temperature sensor 20 is digitized into 8 bits by the A / D conversion circuit 22 at a predetermined time interval, for example, every 15 seconds, and the temperature data is read each time. The data is sent to the CPU 44. The CPU 44 determines whether or not the absolute value of the 8-bit temperature data and the temporal change in temperature exceed a predetermined value (measurement mode). When the value is equal to or smaller than the predetermined value, it is determined that the state is normal, the timing signal generation circuit 40 does not generate the timing signal, and the temperature data is not supplied to the oscillation circuit 26. The A / D conversion circuit 22, the oscillation circuit 26, and the control circuit 24 are in a standby state (standby mode) until the timing signal is generated. After that, when the timing signal generation circuit 40 generates the timing signal at random time intervals centered on the predetermined time interval T ₁ , the control circuit 24 switches to the transmission mode.
Then, the temperature data acquired immediately before or immediately after the generation of the timing signal is sent to the oscillation circuit 26, and the identification signal is called from the identification signal generation circuit 42, so that the oscillation circuit 2
Sent to 6.

In the oscillating circuit 26, the temperature data and the identification signal are placed on the generated carrier wave signal to create and amplify a high frequency signal, and the radio wave is radiated from the antenna 28 (transmission mode). After that, the A / D conversion circuit 22 and the oscillation circuit 2
6 and the control circuit 24 are in a standby state until the timing signal is generated. That is, the sensor tag 12
In the transmission mode in the normal state, part of the temperature data obtained by A / D conversion is provided for wireless transmission.

As shown in FIG. 5 (a), the plurality of sensor tags 12 transmit the temperature data transmitted from the antenna 28 and the identification signal at random time intervals around a predetermined time interval T _1. T ₁ + Δt _i (i = 1, 2,
(3, ...) Transmits the transmission signal having the temperature data and the identification signal, so that even if 100 sensor tags 12 are arranged, there is no interference and each temperature data can be easily received. be able to. More specifically, the transmission signal including the temperature data and the identification signal is shown in FIG.
As shown in, the identification signal including the identification ID signal and the word signal, the temperature data, and the confirmation signal for confirming the transmission signal are transmitted as one set.

On the other hand, when the absolute value of the 8-bit temperature data acquired by the A / D conversion circuit 22 or the time change of the temperature exceeds a predetermined value, the CPU 44 determines that the state is abnormal, and the timing signal generation circuit 40 determines. The timing signal generation circuit 40 is controlled so that the timing signal is immediately generated, and the generation of the timing signal causes the control circuit 24 to switch to the transmission mode. Then, according to the generated timing signal, the temperature data acquired immediately before or immediately after the timing signal is generated is used as the oscillation circuit 26.
And the identification signal is supplied from the identification signal generation circuit 42 to the oscillation circuit 26. In the oscillating circuit 26, the temperature data and the identification signal supplied to the generated carrier signal are placed to create and amplify the transmission signal, and the radio wave is radiated from the antenna 28 (transmission mode).

At the same time, the time interval in which the timing signal is generated is changed from the time interval T ₁ , for example, 10 minutes interval,
A time interval T ₂ much shorter than this time interval, eg 1
The timing signal generation circuit 40 is controlled by the CPU 44 to change to a random time interval centered on the 5-second interval. As a result, as an abnormal state with a high risk of fire occurrence, the standby mode interval is shortened, and the temperature data obtained by intermittently switching to the transmission mode is transmitted at short time intervals. That is, when the CPU 44 determines that the state is abnormal, all the acquired temperature data are transmitted at random time intervals centered on the time interval T ₂ until the determination result is determined to be normal.

Here, the electric power in the transmission mode that requires the most electric power is supplied by the battery 34, and the electric power of the solar cell 32 is used in the measurement mode and the standby mode that do not require the electric power as compared with the transmission mode. This allows
Since the battery 34 does not always consume power,
The electromotive force can be restored during the measurement mode and the standby mode, the battery 34 can be retained for one year or more, and a long life can be realized.

In the receiving device 14, as described above, the temperature data and the identification signal are transmitted from the plurality of sensor tags 12 at random time intervals centered on the time intervals T ₁ and T ₂ , so that there is no interference. Absent. The received temperature data and the identification signal are sent to the computer 16, and the current risk is judged from the risk of fire occurrence divided into a plurality of stages based on the temperature and the time change of the temperature. When it is determined that the risk level is relatively high, the position of the high-risk sensor tag 12 is displayed on the monitor of the computer 16 in accordance with the risk level, and the risk level is notified. Further, when it is determined that the degree of danger is extremely high, an alarm sound is emitted via the buzzer 18.

The measurement data transmitting apparatus of the present invention has been described above by taking the sensor tag with the temperature sensor used in the fire alarm support system as an example. However, the measurement data transmitting apparatus of the present invention is used as a sensor for performing measurement. It may be a sensor tag using a pressure sensor, a load sensor, or the like. Further, the present invention is not limited to the above-described embodiments, and it goes without saying that various improvements and changes may be made without departing from the gist of the present invention.

[0035]

As described above in detail, since the solar cell supplies electric power in the measuring mode and the standby mode, even if the electric power of the battery is relatively large consumed in the transmitting mode, the measuring mode and the standby mode are used. The electromotive force can be restored during the mode period, the measurement data can be transmitted intermittently for at least one year, and the maintenance cost for battery replacement and the like can be reduced. Moreover,
Since the sensor and the circuit are integrated with the mounting board to have a compact structure, the installation work is unnecessary, the device can be easily installed at a desired position, and the cost is low. In particular, it is suitable for a transmitter of a fire notification support system that transmits temperature data intermittently to support fire notification.

[Brief description of drawings]

FIG. 1 is a configuration diagram showing a schematic configuration of a system of an example of a fire notification support system of the present invention.

FIG. 2 is a diagram illustrating an example of a configuration of a measurement data transmission device of the present invention.

3 is a block diagram showing a configuration of a main part of the measurement data transmitting apparatus shown in FIG.

FIG. 4 is a block diagram showing a configuration of a receiving device shown in FIG.

5A and 5B are examples of timing charts of signals transmitted in the system shown in FIG.

[Explanation of symbols]

10 Fire alarm support system 12, 12a-12c sensor tag 14 Receiver 16 computers 18 buzzer 20 temperature sensor 22 A / D conversion circuit 24 Control circuit 26 Oscillation circuit 28,50 antennas 30 power supply control circuit 32 solar cells 34 battery 36 mounting board 38 holes 40 Timing signal generation circuit 42 identification signal generation circuit 44 CPU 52 amplifier circuit 54 Demodulation circuit

   ─────────────────────────────────────────────────── ─── Continued front page    F-term (reference) 5G405 AA04 AA07 AB01 AC03 AC05                       AD05 BA08 CA18 CA55 DA21                       DA22 EA06 EA38                 5K060 CC04 CC11 DD01 HH39 JJ00                       MM00 MM03 PP01

Claims (6)

[Claims] 1. A measurement mode that has a measurement mode for acquiring measurement data, a transmission mode for wirelessly transmitting the acquired measurement data, and a standby mode for waiting for switching to the measurement mode or the transmission mode. And a measurement data transmitting device for intermittently transmitting the acquired measurement data in the transmission mode, the sensor performing measurement, and the measurement data acquisition unit for acquiring the measurement data output by the sensor in the measurement mode. A transmission unit that wirelessly transmits at least a part of the measurement data acquired by the measurement data acquisition unit in the transmission mode; a control unit that switches to the transmission mode; and a measurement unit in the measurement mode and the standby mode. The solar cell that mainly supplies power and the power supply in the transmission mode Measurement data transmission apparatus, characterized in that it comprises a power supply unit and a mainly conducts primary batteries. 2. The sensor is a temperature sensor that outputs temperature data, and the measurement data acquisition unit, the transmission unit, and the control unit are configured by a circuit formed on one surface of a mounting board. The measurement data transmission device according to claim 1, wherein the temperature sensor is provided on the other surface of the mounting board and is integrated with the mounting board. 3. A plurality of measurement data transmitting devices according to claim 2, one receiving device for receiving temperature data transmitted from the measurement data transmitting device, and a risk of fire occurrence from the received temperature data. A fire notification support system, comprising: a notification unit that notifies the degree. 4. The fire alarm support system according to claim 3, wherein the control unit switches to the transmission mode at a time interval that randomly changes around a predetermined time interval. 5. The control unit has a first time interval and a second time interval shorter than the first time interval as the predetermined time interval, and the temperature data or the temperature data. When the time change of is less than or equal to a predetermined value, the control unit selects the first time interval, and when the time change of the temperature data or the temperature data exceeds a predetermined value, the control unit determines the first time interval. The fire alarm support system according to claim 4, wherein the time interval of 2 is selected. 6. The measurement data transmission device, at least,
6. Unique identification data assigned to each device is transmitted together with the temperature data.
Fire alarm support system according to any one of.