JP2020170883A - Emergency broadcast device - Google Patents

Abstract

To improve accuracy of determining a state of an emergency broadcast line.SOLUTION: Disclosed is an emergency broadcast device 1 which generates a broadcast sound transmitted to a speaker 2 which is connected via wiring L. This device includes: a signal generation part 162 which generates a plurality of test signals of a plurality of frequencies usable for testing a state of the wiring L; a variation amount specifying part 167 which specifies a variation amount of electric characteristics of the wiring L while applying each of a plurality of test signals to the wiring L; a selection part 168 for selecting a use frequency used for testing from a plurality of frequencies based on a plurality of variation amounts corresponding to each of a plurality of test signal; and a signal control part 169 for applying a test signal of the use frequency selected by the selection part 168 to the wiring L when a state of the wiring L is tested.SELECTED DRAWING: Figure 2

Description

The present invention relates to an emergency broadcasting device having a function of performing emergency broadcasting.

Emergency broadcasting devices that can perform emergency broadcasting in the event of a fire are known. Patent Document 1 discloses a function of detecting a disconnection or short circuit of an emergency broadcasting line by detecting a current level when a sound signal is output from an emergency broadcasting facility.

Japanese Unexamined Patent Publication No. 2001-155266

When monitoring a wire break or short circuit to maintain the reliability of the emergency broadcast line, it is detected that external noise is superimposed on the emergency broadcast line while a test current is applied to the wiring to monitor the wire break or short circuit. There is an error in the current level to be generated. As a result, there has been a problem that the state of the emergency broadcasting line may not be correctly determined.

Therefore, the present invention has been made in view of these points, and an object of the present invention is to provide an emergency broadcasting device capable of improving the accuracy of determining the state of an emergency broadcasting line.

The emergency broadcasting device of the present invention is an emergency broadcasting device that generates broadcast sound transmitted to speakers connected via wiring. In this emergency broadcasting device, a signal generator that generates a plurality of test signals of a plurality of frequencies that can be used for testing the state of the wiring, and the wiring while applying each of the plurality of test signals to the wiring. Selection to select the frequency to be used for the test from the plurality of frequencies based on the fluctuation amount specifying unit for specifying the fluctuation amount of the electrical characteristics of the above and the plurality of the fluctuation amounts corresponding to the plurality of test signals. It has a unit and a signal control unit that applies the test signal of the operating frequency selected by the selection unit to the wiring when testing the state of the wiring.

The selection unit uses the frequency corresponding to the minimum fluctuation amount among the plurality of fluctuation amounts specified by the fluctuation amount specifying unit while applying the plurality of test signals to the wiring as the frequency used. You may choose.

Further, the smoothing unit for smoothing the current flowing through the wiring while the plurality of test signals are applied to the wiring is further provided, and the fluctuation amount specifying unit is the fluctuation of the current smoothed by the smoothing unit. The amount of fluctuation in the electrical characteristics may be specified based on the amount.

The fluctuation amount specifying unit is in an abnormal state when the electrical characteristics are out of a predetermined range while the test signal of the operating frequency is applied to the wiring to perform the test. And the result of the determination may be output.

According to the present invention, there is an effect that the accuracy of determining the state of the emergency broadcasting line can be improved.

It is a figure which shows typically the structure of the emergency broadcasting system. It is a figure which shows the broadcasting circuit configuration. It is a figure for demonstrating the operation of the smoothing part. It is an operation flowchart of a broadcasting circuit. It is a figure which shows the measured value of the signal output from a smoothing part.

[Outline of emergency broadcasting system S]
FIG. 1 is a diagram schematically showing the configuration of the emergency broadcasting system S. The emergency broadcasting system S includes an emergency broadcasting device 1 and a plurality of speakers 2 connected to the emergency broadcasting device 1. The emergency broadcasting device 1 generates an AC signal corresponding to an emergency broadcasting sound indicating that a fire has occurred in response to the fire detector (not shown) detecting the fire. The AC signal generated by the emergency broadcasting device 1 is transmitted to the speaker 2 by the wiring L, and the emergency broadcasting sound based on the transmitted AC signal is output from the speaker 2.

The speaker 2 is connected to the emergency broadcasting device 1 via the wiring L. In FIG. 1, as wiring L, a wiring pair of wiring Lp1 and wiring Ln1, a wiring pair of wiring Lp2 and wiring Ln2, and a wiring pair of wiring Lpm and wiring Lnm (m is an integer of 3 or more) are shown. , The number of wires connected to the emergency broadcasting device 1 is arbitrary. The speaker 2 is connected between the two wirings L of the wiring Lp and the wiring Ln, and emits an emergency broadcast sound based on the AC signal applied between the wirings L.

The emergency broadcasting device 1 has a function of applying a test signal to the speaker 2 in order to detect a defect such as a short circuit or disconnection of the wiring L to which the speaker 2 is connected. The emergency broadcasting device 1 measures the electrical characteristics (for example, impedance) of the wiring L while applying the test signal. The emergency broadcasting device 1 determines, for example, that the wiring L is broken when the measured impedance is equal to or higher than the first threshold value, and the measured impedance is equal to or less than the second threshold value (however, the second threshold value <first threshold value) or less. If, it is determined that the wiring L is short-circuited.

If noise (for example, hum noise of a commercial power source) is input from the outside while the emergency broadcasting device 1 is applying the test signal, the noise is superimposed on the test signal, resulting in an error in the measured impedance. As a result, the emergency broadcasting device 1 may erroneously determine the state of the wiring L. Therefore, the emergency broadcasting device 1 selects a frequency that is less affected by noise as the frequency of the test signal in order to make the measurement result less susceptible to noise. Details of the method by which the emergency broadcasting device 1 selects the frequency of the test signal will be described later.

[Configuration of emergency broadcasting device 1]
As shown in FIG. 1, the emergency broadcasting device 1 includes a display unit circuit 11, an operation unit circuit 12, a control circuit 13, a fire information receiving circuit 14, a power supply circuit 15, and a broadcasting circuit 16. The emergency broadcasting device 1 has a plurality of broadcasting circuits 16 connected to a plurality of wirings L.

The display unit circuit 11 includes a display for displaying various kinds of information and a driver for driving the display. The display unit circuit 11 displays, for example, information indicating a broadcast output destination or information indicating a test result of the wiring L under the control of the control circuit 13.

The operation unit circuit 12 includes an operation device for receiving an operation by a user such as a security guard who operates the emergency broadcasting device 1. The operation unit circuit 12 accepts, for example, an operation for setting the operation mode of the emergency broadcasting device 1 and an operation for testing the wiring L.

The control circuit 13 has a processor that controls each part of the emergency broadcasting device 1. The control circuit 13 includes, for example, a CPU (Central Processing Unit) and a storage medium such as a ROM (Read Only Memory) and a RAM (Random Access Memory). The control circuit 13 executes various operations by the CPU executing a program stored in the ROM.

For example, when the control circuit 13 receives a notification from the fire information receiving circuit 14 that a fire has occurred, the control circuit 13 causes the display unit circuit 11 to display information indicating the broadcast output destination, or makes an emergency broadcast to the speaker 2 via the broadcast circuit 16. It makes a sound. Further, the control circuit 13 determines the frequency of the test signal applied to the wiring L by the plurality of broadcasting circuits 16, and executes the test of the wiring L using the test signal of the determined frequency.

The fire information receiving circuit 14 receives fire information indicating that a fire has occurred from the fire receiver. The fire information receiving circuit 14 notifies the control circuit 13 that the fire information has been received.
The power supply circuit 15 supplies electric power to each part of the emergency broadcasting device 1.

The broadcasting circuit 16 transmits the emergency broadcast sound emitted by the speaker 2 to the wiring L based on the control of the control circuit 13. The details of the broadcasting circuit 16 will be described below.

[Detailed configuration of broadcasting circuit 16]
FIG. 2 is a diagram showing the configuration of the broadcasting circuit 16. The broadcasting circuit 16 includes a control unit 161, a signal generation unit 162, a current measurement unit 163, a smoothing unit 164, an A / D conversion unit 165, and a storage unit 166. The control unit 161 includes a fluctuation amount specifying unit 167, a selection unit 168, and a signal control unit 169.

The control unit 161 controls each unit of the broadcasting circuit 16. The control unit 161 has, for example, a CPU, and functions as a fluctuation amount specifying unit 167, a selection unit 168, and a signal control unit 169 by executing a program stored in the storage unit 166.

The signal generation unit 162 generates an electric signal corresponding to a siren sound or voice, which is an example of an emergency broadcast sound. Further, the signal generation unit 162 generates a plurality of test signals having a plurality of frequencies that can be used for testing the state of the wiring L. The signal generation unit 162 generates, for example, a test signal including a single frequency sine wave, but may generate a test signal including a plurality of frequency components.

The characteristics of the speaker 2 for signals in the non-audible frequency band are not guaranteed. Therefore, in order to properly test the electrical characteristics while the speaker 2 is connected to the wiring L, it is necessary to use a test signal at a frequency at which the speaker 2 can operate (that is, a frequency at which sound can be emitted). is there. Therefore, the signal generation unit 162 may generate a test signal having a frequency in the audible frequency band (about 20 Hz to 20 kHz) near 60 Hz, which is relatively difficult for humans to recognize.

For example, the signal generator 162 generates a test signal having a frequency between the lower limit frequency of the audible frequency band and the frequency of a commercial power source (for example, 50 Hz), such as frequencies of 42 Hz, 44 Hz, 46 Hz, 48 Hz, and 50 Hz. be able to. The signal generation unit 162 may generate a test signal having a frequency higher than the frequency of the commercial power supply (for example, 51 Hz).

Further, when a signal in the audible frequency band is superimposed on the wiring L as a test signal, there is a concern that the sound emitted from the speaker 2 may be offensive to people around. Therefore, the signal generation unit 162 prevents the harshness by generating a test signal having a size corresponding to a sound pressure level that does not harsh the ears.

The signal generation unit 162 selects one frequency from these plurality of frequencies based on the instruction from the signal control unit 169, generates a test signal of the selected frequency, and transmits the generated test signal to the current measurement unit 163. input. The signal generation unit 162 has, for example, a frequency synthesizer, and generates a test signal in the frequency synthesizer. The signal generation unit 162 may generate a test signal by reading waveform data in which time and amplitude are associated from the storage unit 166 and converting the read waveform data into an analog signal.

The current measuring unit 163 causes the test signal input from the signal generating unit 162 to flow through the wiring L, and measures the current flowing through the wiring L while applying the test signal to the wiring L. The current measuring unit 163 measures the current based on, for example, the voltage between both ends of a predetermined resistor. The current measuring unit 163 inputs a signal corresponding to the measured current (for example, a potential difference signal between both ends of the resistor) to the smoothing unit 164. The current measuring unit 163 applies the emergency broadcasting sound signal input from the signal generating unit 162 to the wiring L as it is while the emergency broadcasting sound signal is applied.

The smoothing unit 164 smoothes the signal input from the current measuring unit 163. The smoothing unit 164 has, for example, a low-pass filter that smoothes the current flowing through the wiring L while applying a plurality of test signals to the wiring L. The cutoff frequency of the low-pass filter is set to a frequency sufficiently lower than the frequency of the test signal, for example, 1 Hz. Since the smoothing unit 164 has a low-pass filter having such characteristics, the smoothing unit 164 receives an AC signal when a signal including only the frequency component of the test signal generated by the signal generating unit 162 is input. Outputs a signal that does not contain components. On the other hand, since the noise signal is superimposed on the test signal, the signal input from the current measuring unit 163 contains a component (groaning sound component) having a difference frequency corresponding to the difference between the frequency of the test signal and the frequency of the noise signal. If so, the smoothing unit 164 outputs a signal including a component of the difference frequency. The smoothing unit 164 inputs the signal after passing through the low-pass filter to the A / D conversion unit 165.

FIG. 3 is a diagram for explaining the operation of the smoothing unit 164. FIG. 3A is a waveform of a signal input to the smoothing unit 164 when noise is not superimposed while the current measuring unit 163 applies a test signal having a single frequency to the wiring L. FIG. 3B is a waveform of a signal output from the smoothing unit 164 when the signal shown in FIG. 3A is input to the smoothing unit 164. As described above, when noise is not superimposed on the test signal, the signal output by the smoothing unit 164 does not fluctuate.

FIG. 3C is a waveform of a signal input to the smoothing unit 164 when noise is superimposed while the current measuring unit 163 applies a test signal having a single frequency to the wiring L. FIG. 3D is a waveform of a signal output from the smoothing unit 164 when the signal shown in FIG. 3C is input to the smoothing unit 164. In this way, when noise is superimposed on the test signal, the signal output by the smoothing unit 164 fluctuates. The selection unit 168, which will be described later, selects the frequency at which this fluctuation is the smallest as the frequency of the test signal.

The A / D conversion unit 165 converts the signal input from the smoothing unit 164 into a digital value. The A / D conversion unit 165 inputs digital data indicating the converted digital value to the fluctuation amount specifying unit 167.

The storage unit 166 includes a storage medium for storing various types of data. The storage unit 166 includes, for example, a ROM and a RAM. The storage unit 166 stores, for example, a program executed by the control unit 161. The storage unit 166 may store the waveform data used by the signal generation unit 162 to generate the test signal.

The fluctuation amount specifying unit 167 specifies the fluctuation amount of the electrical characteristics of the wiring L while applying each of the plurality of test signals to the wiring L. The fluctuation amount specifying unit 167 specifies, for example, the fluctuation amount of electrical characteristics such as the current flowing through the wiring L, the voltage between the two wires of the wiring L, and the impedance of the wiring L. The fluctuation amount specifying unit 167 specifies the fluctuation amount of the electrical characteristics based on the fluctuation amount in the waveform after the smoothing unit 164 is smoothed. That is, the fluctuation amount specifying unit 167 specifies the fluctuation amount of the signal input from the A / D conversion unit 165 as the fluctuation amount of the electrical characteristics of the wiring L. The amount of fluctuation is represented by, for example, the difference value between the maximum value and the minimum value of the signal input from the A / D conversion unit 165. The fluctuation amount specifying unit 167 notifies the selection unit 168 of the specified fluctuation amount.

The selection unit 168 selects a frequency to be used for the test from a plurality of frequencies based on a plurality of fluctuation amounts corresponding to each of the plurality of test signals. For example, the selection unit 168 selects as the frequency to be used the frequency corresponding to the minimum fluctuation amount among the plurality of fluctuation amounts specified by the fluctuation amount specifying unit 167 while applying the plurality of test signals to the wiring L. .. Specifically, the selection unit 168 conducts electricity while the respective test signals of 42 Hz, 44 Hz, 46 Hz, 48 Hz, 50 Hz, and 52 Hz, which are set as frequencies of test signals that can be used in advance, are applied to the wiring L. Compare the amount of fluctuation of the target characteristics and select the frequency with the smallest amount of fluctuation. The selection unit 168 notifies the signal control unit 169 of the selected frequency. The selection unit 168 executes a frequency selection process for each of the plurality of wirings L, and stores the frequency used in the storage unit 166 in association with each of the plurality of wirings L.

When testing the state of the wiring L, the signal control unit 169 controls the signal generation unit 162 so that the test signal of the frequency used selected by the selection unit 168 is applied to the wiring L. For example, when the selection unit 168 selects 48 Hz, the signal control unit 169 notifies the signal generation unit 162 to use the test signal of 48 Hz.

When the broadcast circuit 16 receives an instruction from the control circuit 13 to perform the test of the wiring L after the frequency to be used is determined as described above, the broadcasting circuit 16 applies the test signal of the frequency to be used selected by the selection unit 168 to the wiring L. To do. The fluctuation amount specifying unit 167 is used when the electrical characteristics indicated by the signal input from the A / D conversion unit 165 are out of a predetermined range while the test signal of the operating frequency is applied to the wiring L for the test. It is determined that the wiring L is in an abnormal state, and the result of the determination is notified to the control circuit 13.

Specifically, the fluctuation amount specifying unit 167 determines that the wiring L is broken when the impedance is equal to or higher than the first threshold value, and notifies the control circuit 13 that the disconnection has occurred. Further, the fluctuation amount specifying unit 167 determines that the wiring L is short-circuited when the impedance is equal to or less than the second threshold value smaller than the first threshold value, and notifies the control circuit 13 that the short circuit has occurred. To do. In other words, the fluctuation amount specifying unit 167 determines that the wiring L is short-circuited when the current value is equal to or greater than the third threshold value, and performs wiring when the current value is equal to or less than the fourth threshold value smaller than the third threshold value. It may be determined that L is broken.

[Flow of operation of broadcasting circuit 16]
FIG. 4 is an operation flowchart of the broadcasting circuit 16. The flowchart shown in FIG. 4 starts from the time when an instruction for determining the frequency used for the test signal is input from the control circuit 13 to the broadcasting circuit 16.

In the broadcasting circuit 16, the signal control unit 169 sequentially applies test signals of a plurality of frequencies to the wiring L to the signal generation unit 162 in response to an instruction from the control circuit 13 (S1). During this time, the fluctuation amount specifying unit 167 measures the fluctuation amount of the electrical characteristics. The fluctuation amount specifying unit 167 stores the fluctuation amount in the storage unit 166 in association with the frequency of the test signal (S2).

Subsequently, the selection unit 168 reads out the fluctuation amount stored in the storage unit 166 in association with the frequency after the test signals of all frequencies are applied. The selection unit 168 selects the frequency associated with the smallest fluctuation amount among the plurality of frequencies as the frequency to be used. The selection unit 168 stores the selected frequency as the frequency to be used in the storage unit 166 (S3). After that, when the signal control unit 169 receives an instruction from the control circuit 13 to carry out the test of the wiring L, the signal control unit 169 reads out the used frequency stored in the storage unit 166 and sends the read test signal of the used frequency to the signal generation unit 162. By generating it, the wiring L is tested (S4). The fluctuation amount specifying unit 167 determines the state of the wiring L based on the impedance value, and notifies the control circuit 13 of the determined result.

The emergency broadcasting device 1 may measure the amount of fluctuation for the test signals of the plurality of frequencies described above every time the wiring L test is performed, and immediately after the power of the emergency broadcasting device 1 is turned on. It may be executed, or it may be executed by operating a switch or the like provided in the operation unit circuit 12. The emergency broadcasting device 1 may measure the fluctuation amount at predetermined time intervals, or may perform the measurement of the above various timings in combination. Further, the emergency broadcasting device 1 may execute the test by applying the test signal immediately after the power of the emergency broadcasting device 1 is turned on, and executes the test by operating a switch or the like provided in the operation unit circuit 12. May be good. The emergency broadcasting device 1 may perform a test by applying a test signal at predetermined time intervals, or may perform a combination of the above various timings.

[Experimental result]
FIG. 5 is a diagram showing actual measurement values of signals output from the smoothing unit 164 when a plurality of test signals having different frequencies are applied to the wiring L in a state where noise is applied. The horizontal axis of FIG. 5 represents time, and the vertical axis represents voltage. The frequency of noise is 50.1 Hz. FIG. 5A shows the waveform of the signal output from the smoothing unit 164 while the test signal having a frequency of 50.0 Hz is applied to the wiring L. In FIG. 5A, it can be confirmed that a beat of 0.1 Hz corresponding to the difference between the noise frequency and the frequency of the test signal is generated.

FIG. 5B shows the waveform of the signal output from the smoothing unit 164 while the test signal having a frequency of 42.0 Hz is applied to the wiring L. In this case, in the signal input to the smoothing unit 164, a DC signal in which a low frequency signal of 8.0 Hz corresponding to the difference between the noise frequency and the frequency of the test signal is superimposed appears, but the frequency is 8.0 Hz. Since the AC component of is higher than the cutoff frequency of the smoothing section 164, it is removed by the smoothing section 164. As a result, when a frequency of 42.0 Hz is used as the test signal, it can be seen that the frequency is not affected by noise of 50.1 Hz.

[Effect of emergency broadcasting device 1]
As described above, in the emergency broadcasting device 1, the fluctuation amount specifying unit 167 specifies the fluctuation amount of the electrical characteristics of the wiring L while applying each of the plurality of test signals to the wiring L. Then, the selection unit 168 selects a frequency to be used for the test from a plurality of frequencies based on a plurality of fluctuation amounts corresponding to each of the plurality of test signals. After that, when testing the state of the wiring L, the signal control unit 169 controls the signal generation unit 162 so that the test signal of the frequency used selected by the selection unit 168 is applied to the wiring L. By operating the emergency broadcasting device 1 in this way, the emergency broadcasting device 1 is in a state of the wiring L without being affected by the noise even when the wiring L is installed in an environment that receives noise from the outside. Can be tested. As a result, the accuracy of determining the state of the emergency broadcast line can be improved.

Although the present invention has been described above using the embodiments, the technical scope of the present invention is not limited to the scope described in the above embodiments, and various modifications and changes can be made within the scope of the gist. is there. For example, all or part of the device can be functionally or physically distributed / integrated in any unit. Also included in the embodiments of the present invention are new embodiments resulting from any combination of the plurality of embodiments. The effect of the new embodiment produced by the combination has the effect of the original embodiment.

1 Emergency broadcasting device 2 Speaker 11 Display unit circuit 12 Operation unit circuit 13 Control circuit 14 Fire information receiving circuit 15 Power supply circuit 16 Broadcasting circuit 161 Control unit 162 Signal generation unit 163 Current measurement unit 164 Smoothing unit 165 Conversion unit 166 Storage unit 167 Fluctuation amount identification unit 168 Selection unit 169 Signal control unit

Claims (4)

An emergency broadcasting device that generates broadcast sound transmitted to speakers connected via wiring.
A signal generator that generates a plurality of test signals of a plurality of frequencies that can be used for testing the state of the wiring,
A fluctuation amount specifying unit that specifies the fluctuation amount of the electrical characteristics of the wiring while each of the plurality of test signals is applied to the wiring,
A selection unit that selects a frequency to be used for the test from the plurality of frequencies based on the plurality of fluctuation amounts corresponding to each of the plurality of test signals.
A signal control unit that applies the test signal of the operating frequency selected by the selection unit to the wiring when testing the state of the wiring.
Emergency broadcasting equipment with. The selection unit uses the frequency corresponding to the minimum fluctuation amount among the plurality of fluctuation amounts specified by the fluctuation amount specifying unit while applying the plurality of test signals to the wiring as the frequency used. select,
The emergency broadcasting device according to claim 1. Further having a smoothing unit for smoothing the current flowing through the wiring while applying the plurality of test signals to the wiring.
The fluctuation amount specifying unit specifies the fluctuation amount of the electrical characteristics based on the fluctuation amount of the current smoothed by the smoothing unit.
The emergency broadcasting device according to claim 1 or 2. The fluctuation amount specifying unit is in an abnormal state when the electrical characteristics are out of a predetermined range while the test signal of the operating frequency is applied to the wiring to perform the test. And output the judgment result,
The emergency broadcasting device according to any one of claims 1 to 3.

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