JP2024016274A - booster - Google Patents

Abstract

An object of the present invention is to enable fire monitoring using all fire detectors even if a disconnection fault occurs in a loop transmission line connected in a loop to a receiver or a repeater connected to the receiver. [Solution] In a fire alarm system equipped with an input/output switching type booster on a loop transmission line, an input/output switching type booster 16 is inserted and connected in the middle of a loop transmission line 12 connected to a receiver 10 in a loop shape. At the same time, an operation test is performed in which a signal input from one side is amplified and outputted to the other side, and the receiver 10 transmits a signal from the end side of the loop transmission line 12 without transmitting a signal from the start end side. 10 performs an operation test in which a signal is transmitted from the starting end side of the loop transmission line 12, and the amplification direction is switched. [Selection diagram] Figure 1

Description

The present invention relates to a booster used in fire alarm equipment that monitors fire by connecting a fire detector to a loop transmission path from a receiver.

Conventionally, in fire alarm equipment known as type R, a terminal device such as a fire detector equipped with a transmission function is connected to a transmission line led out from a receiver, and when a fire is detected, the fire alarm Based on the fire interrupt from the system, a search command is issued to identify the address of the fire detector that triggered the alarm, display the address where the fire occurred, and collect and monitor fire data from the identified fire detector. There is.

In this way, knowing the address of the fire detector that detected the fire makes it possible to carry out appropriate evacuation guidance and fire extinguishing activities, making it an essential function especially for fire monitoring in large-scale facilities.

In addition, in order to ensure reliability against disconnection failures in the transmission line led out from the fire receiver, fire alarm equipment is installed that monitors fires by connecting a fire detector to the loop transmission line connected to the receiver in a loop. It has been known.

FIG. 6 is an explanatory diagram of a conventional fire alarm system using a loop transmission line. FIG. 6(A) shows a normal monitoring state, and FIG. 6(B) shows a case where a disconnection fault occurs.

As shown in FIG. 6(A), a transmission path 12 using a pair of signal lines is led out from a transmission section 22 provided in the receiver 10, and after being led out from the receiver 10, the transmission path 12 receives signals again. They are arranged in a loop that returns to the machine 10. In the following description, the transmission line 12 connected in a loop to the receiver 10 will be referred to as the loop transmission line 12.

A fire detector 18 with a transmission function is connected between the signal lines of the loop transmission line 12, and a unique detector address is set for the fire detector 18, and the line voltage can be changed from the transmission section 22. Fires are monitored by transmitting a downstream signal that changes the line current, and from the fire detector 18 transmitting an upstream signal that changes the line current.

A disconnection monitoring control unit 28 is provided at the end of the loop transmission line 12 led into the fire receiver 10, and detects disconnection failures in the loop transmission line 12 based on the line voltage supplied from the transmission unit 22 to the loop transmission line 12. is being monitored. Furthermore, switching circuit sections 30a and 30b are provided at the ends of the loop transmission line 12 to switch and connect the terminal signal line to the transmission section 22. In the normal monitoring state, the switching circuit sections 30a and 30b are connected to the transmission section 22. It is in a disconnected state.

As shown in FIG. 6(B), if a disconnection 31a occurs in the middle of the loop transmission line 12 during operation, the disconnection monitoring control unit 28 detects that the line voltage at the end of the loop transmission line 12 is disconnected. When a disconnection fault is detected, the switching circuit sections 30a and 30b are activated to connect the terminal end of the loop transmission line 12 to the transmission section 22.

Therefore, the signal from the transmission unit 22 is transmitted from the termination side of the loop transmission line 12 to the location where the disconnection 31a occurs via the switching circuit units 30a and 30b, and between the location where the disconnection 31a occurs and the termination of the loop transmission line 12. It becomes possible to send and receive signals to and from the fire detector 18 connected to the loop transmission line 12, and even if a disconnection fault occurs, the fire monitoring function by the fire detector 18 connected to the loop transmission line 12 will be lost. High reliability can be obtained.

Japanese Patent Application Publication No. 2008-004033 Japanese Patent Application Publication No. 2010-114632 Japanese Patent Application Publication No. 1-297931 Microfilm of Jitsugan No. 59-156218 Japanese Unexamined Patent Publication No. 2-28798

By the way, when monitoring a fire using a fire detector connected to a loop transmission line from the receiver, the transmission line drawn out to the warning area is returned to the receiver, so the line is drawn out from the receiver towards the warning area. The loop transmission line is approximately twice as long as a normal transmission line, and the line resistance at the end of the loop transmission line also increases. For example, if the transmission line resistance that allows the transmission unit and fire detector to receive downstream and upstream signals is 30 ohms, the end of the loop transmission line will have a resistance of 60 ohms, and it will not be possible to connect to a transmission line range that exceeds 30 ohms. It becomes impossible to send and receive data to and from the fire detector located in the fire detector. For this reason, it is conceivable to provide a booster in the middle of the loop transmission path.

FIG. 7 is an explanatory diagram showing a conventional fire alarm system in which a booster is installed on a loop transmission line. FIG. 7(A) shows a normal monitoring state, and FIG. 7(B) shows a case where a disconnection fault occurs. It shows.

As shown in FIG. 7(A), the booster 100 is inserted and connected, for example, at a folded position that is a half of the loop transmission line 12. Here, the space between the starting end of the loop transmission line 14 drawn out from the receiver 10 and the booster 100 is referred to as the starting end side transmission line 12a, and the space between the booster 100 and the terminal end of the loop transmission line 12 returned to the receiver 10 is referred to as the starting end side transmission line 12a. It is called a termination side transmission line 12b.

The booster 100 amplifies the down signal inputted from the start end transmission line 12a in the voltage boost circuit section 102 and outputs it to the end side transmission line 12b, and also amplifies the uplink signal input from the end side transmission line 12b to the current boost circuit section 104. Even if the line length of the loop transmission line 12 increases, the signal level between it and the fire detector 18 connected to the terminal side of the loop transmission line 12 will decrease. It is possible to reliably transmit and receive signals to and from the transmitting section 22 by suppressing this.

However, even if the booster 100 is provided in the loop transmission line 12, as shown in FIG. When the terminal side of the loop transmission line 12 is connected to the transmission section 22 by the operation of the circuit sections 30a and 30b, the booster 100 transmits the down signal and the up signal only in one direction by the voltage boost circuit section 102 and the current boost circuit section 104, respectively. For amplification, the downlink signal transmitted from the terminal side of the loop transmission line 12 via the switching circuit units 30a and 30b cannot pass through the booster 100, and the signal between the booster 100 and the point where the disconnection 31b occurs The upstream signal from the fire detector 18 also cannot pass through the booster 100, and there is a problem that the fire monitoring function of the fire detector 18 connected between the booster 100 and the point where the disconnection 31b occurs is lost. be.

The present invention provides a fire alarm system that enables fire monitoring by all fire detectors even if a disconnection fault occurs in a loop transmission line connected in a loop to a receiver or a repeater connected to the receiver. The purpose is to provide used boosters.

(Booster that switches the amplification direction based on operation tests)
The present invention is a booster used in fire alarm equipment that connects a fire detector to a loop transmission line connected in a loop to a receiver or a repeater connected to the receiver,
The booster is
It is inserted and connected in the middle of a loop transmission line, and amplifies the signal input from one side and outputs it to the other side.
It is characterized by switching the amplification direction based on an operation test using a signal transmitted from the receiver.

(Operation test for switching booster amplification direction)
The switching of the amplification direction was performed through an operation test in which the receiver did not transmit a signal from the start end of the loop transmission line but instead sent a signal from the end side, and an operation test in which the receiver transmitted a signal from the start end of the loop transmission line. conduct.

(Effect of a booster that switches the amplification direction based on operation tests)
The present invention is a booster used in fire alarm equipment that connects a fire detector to a loop transmission line connected in a loop to a receiver or a repeater connected to the receiver, the booster having a loop transmission line. The loop transmission line If a disconnection occurs in the loop transmission line and it becomes necessary to switch the amplification direction of the booster, it is possible to ensure highly reliable fire alarm by confirming that the switch can be made normally while no disconnection occurs in the loop transmission line. This makes it possible to secure equipment and enable fire monitoring using all fire detectors when a disconnection fault occurs in the loop transmission line.

An explanatory diagram showing an overview of a fire alarm system equipped with an input/output switching type booster on the loop transmission line Block diagram showing an embodiment of an input/output switching type booster Block diagram showing the operation of the input/output switching type booster when a disconnection fault occurs on the transmission line at the start end A block diagram showing the operation of the input/output switching type booster in the normal monitoring state and when a disconnection fault occurs on the terminal side transmission line. Block diagram showing another embodiment of the input/output switching type booster Explanatory diagram showing a fire alarm system equipped with a conventional loop transmission line Explanatory diagram showing a fire alarm system with a booster installed on a conventional loop transmission line

[Fire alarm equipment]
(Summary of fire alarm equipment)
FIG. 1 is an explanatory diagram showing an outline of a fire alarm system equipped with an input/output switching type booster on a loop transmission line. As shown in FIG. 1, for example, an R-type receiver 10 is installed in a manager's room on the first floor of a building where fire alarm equipment is installed, and a pair of signal lines 14a, A loop transmission line 12 using 14b is drawn out.

A plurality of fire detectors 18 each having a transmission function and each having a unique address are connected to the loop transmission line 12 . An input/output switching type booster 16 is inserted and connected at an intermediate position of the loop transmission line 12.

Here, the maximum number of addresses set for the terminal including the fire detector 18 connected to the loop transmission line 12 is, for example, 255, and since the input/output switching type booster 16 also has a transmission function, A maximum of 254 fire detectors 18 can be connected.

(Functional configuration of receiver)
The receiver 10 includes a reception control section 20, a transmission section 22, an operation section 23, a display section 24, an alarm section 25, a transmission section 26, a disconnection monitoring control section 28, and switching circuit sections 30a and 30b.

The reception control unit 20 is a computer circuit or the like including a CPU, memory, various input/output ports, and the like. The transmission unit 22 transmits and receives signals to and from the fire detector 18 connected to the loop transmission line 12 according to a predetermined communication protocol.

The downstream signal from the transmission section 22 to the fire detector 18 is transmitted in voltage mode. This voltage mode signal is transmitted as a voltage pulse that varies the line voltage of the loop transmission line 12, for example between 18 and 30 volts.

On the other hand, the upstream signal from the fire detector 18 to the receiver 10 is transmitted in current mode. In this current mode, a signal current is passed through the loop transmission line 12 at the timing of bit 1 of the transmission data, and an upstream signal is transmitted to the receiver as a so-called current pulse train.

The monitoring control by the reception control unit 20 of the receiver 10 is as follows. During normal monitoring, the reception control unit 20 instructs the transmission unit 22 to transmit a broadcast batch AD conversion signal including a batch AD conversion command at regular intervals, and this batch AD conversion signal The fire detector 18 that has received this detects and holds the smoke density or temperature as sensor data. Subsequently, the reception control unit 20 transmits a paging signal including a polling command that sequentially specifies terminal addresses.

When the fire detector 18 receives a call signal having an address that matches its own address, it transmits a response signal containing the sensor data held at that time to the receiver 10. When the fire detector 18 detects a fire, it transmits a fire interrupt signal to the receiver 10. When the reception control unit 20 receives the fire interrupt signal via the transmission unit 22, it transmits a group search command signal to identify the group that includes the fire detector 18 that is detecting a fire, and then sends an intra-group search command signal. The address of the fire detector 18 that is detecting the fire is specified by transmitting the address, and the fire occurrence address is displayed, and fire data is collected from the specified fire sensor and monitored.

The disconnection monitoring control unit 28 detects and monitors the signal voltage obtained at the end of the loop transmission line 12, and when a disconnection occurs in the loop transmission line 12, the disconnection is detected because the signal voltage is disconnected and cannot be detected. By turning on the switching circuit parts 30a and 30b using relay contacts and switch elements, the transmission part 22 is connected to the end of the loop transmission line 12, and the transmission from both ends of the loop transmission line 12 to the disconnection position is performed. By transmitting and receiving signals in parallel to the line, it recovers from disconnection failures.

In the normal monitoring state, the input/output switching type booster 16 amplifies the voltage of a downlink signal (voltage pulse signal) input from the start-side transmission line 12a and outputs it to the termination-side transmission line 12b, and also outputs the amplified down signal (voltage pulse signal) input from the termination-side transmission line 12b. The current upstream signal (current pulse signal) is amplified and output to the start-side transmission line 12a, and when a disconnection fault occurs in the start-side transmission line 12a, the disconnection monitoring control unit 28 switches the switching circuit units 30a and 30b. On the condition that the end of the loop transmission line 12 is connected to the transmission section 22 by the operation of , the downlink signal (voltage pulse signal) input from the termination side transmission line 12b is voltage amplified and output to the start side transmission line 12a. In addition, a configuration is provided for switching input and output so that an upstream signal (current pulse signal) input from the start-end transmission line 12a side is amplified and output to the termination-side transmission line 12b.

The input/output switching type booster 16 operates by being supplied with commercial power, and further includes an emergency battery that is supplied with power during normal times and functions as an operating power source during a power outage.

The input/output switching type booster 16 operates by being supplied with power from a commercial power source, and includes an indicator light that displays status information such as the power supply state and signal amplification direction.

The input/output switching type booster 16 has a unique address, and when it recognizes a signal applied to itself from a receiver, it performs operations corresponding to the signal, such as replying status information and switching the signal amplification direction.

The input/output switching type booster 16 includes a circuit for short circuit protection.

[Input/output switching type booster]
FIG. 2 is a block diagram showing an embodiment of the input/output switching type booster. As shown in FIG. 2, the input/output switching type booster 16 includes a down signal boost circuit section (voltage boost circuit section) 32, an up signal boost circuit section (current boost circuit section) 46, a booster control section 34, a transmission section 36, It is composed of a first voltage detection section 38, a second voltage detection section 40, down signal input/output switching circuit sections 42, 44, and up signal input/output switching circuit sections 48, 50. Note that the down signal boost circuit section 32 functions as a voltage boost circuit section, and the up signal boost circuit section 46 functions as a current boost circuit section.

The downlink signal boost circuit unit 32 is a circuit unit that unidirectionally amplifies the voltage of a voltage pulse signal that is an input downlink signal and outputs the amplified voltage pulse signal, and includes a voltage amplifier and a waveform shaping circuit.

The upstream signal boost circuit section 46 is a circuit section that unidirectionally amplifies and outputs a current pulse signal, which is an input upstream signal, and includes a current amplifier and a waveform shaping circuit.

The downlink signal input/output switching circuit units 42 and 44 are composed of switching relay contacts or switching elements such as FETs. The downlink signal input/output switching circuit unit 42 is provided on the input side of the downlink signal boost circuit unit 32, and the positive side of the starting transmission line 12a is connected to the switching terminal a, and the positive side of the terminating transmission line 12b is connected to the switching terminal b. The common terminal c is connected to the input of the downlink signal boost circuit section 32.

The downlink signal input/output switching circuit section 44 is provided on the output side of the downlink signal boost circuit section 32, the positive side of the termination side transmission line 12b is connected to the switching terminal a, and the positive side of the starting end side transmission line 12a is connected to the switching terminal b. The common terminal c is connected to the output of the downlink signal boost circuit section 32.

In the downlink signal input/output switching circuit units 42 and 44, the switching terminal a side is at the first switching position, and the switching terminal b side is at the second switching position. Therefore, when the downlink signal input/output switching circuit sections 42 and 44 are in the first switching position where the switching terminal a is shown, the start end side transmission line 12a is input connected to the downlink signal boost circuit section 32, and the downlink signal boost circuit section 32 In the case of the second switching position, where the output of The output will be connected to the starting end side transmission line 12a.

The upstream signal input/output switching circuit units 48 and 50 are composed of switching relay contacts or switching elements such as FETs. The upstream signal input/output switching circuit unit 48 is provided on the input side of the upstream signal boost circuit unit 46, the positive side of the termination side transmission line 12b is connected to the switching terminal a, and the positive side of the starting side transmission line 12a is connected to the switching terminal b. The common terminal c is connected to the input of the upstream signal boost circuit section 46.

The upstream signal input/output switching circuit unit 50 is provided on the output side of the upstream signal boost circuit unit 46, and the positive side of the starting transmission line 12a is connected to the switching terminal a, and the positive side of the terminating transmission line 12b is connected to the switching terminal b. The common terminal c is connected to the output of the upstream signal boost circuit section 46.

In the uplink signal input/output switching circuit units 48 and 50, the switching terminal a side is at the first switching position, and the switching terminal b is at the second switching position. Therefore, when the upstream signal input/output switching circuit sections 48 and 50 are in the first switching position where the switching terminal a is shown, the termination side transmission line 12b is input connected to the upstream signal boost circuit section 46 and the upstream signal boost circuit section 46 In the case of the second switching position, in which the output of The output will be connected to the terminal side transmission line 12b.

The first voltage detection section 38 detects the line voltage of the starting end side transmission line 12a and outputs it to the booster control section 34. The second voltage detection section 40 detects the line voltage of the termination side transmission line 12b and outputs it to the booster control section 34.

The booster control unit 34 is composed of a computer circuit including a CPU, memory, and various input/output ports, and performs input/output switching control by executing a program by the CPU. The input/output switching control by the booster control unit 34 is performed when a predetermined line voltage is detected by the first voltage detection unit 38 and the second voltage detection unit 40 (the loop transmission line 12 is normal or the terminal side transmission line 12b is disconnected). ), switch the downlink signal input/output switching circuit units 42, 44 and the upstream signal input/output switching circuit units 48, 50 to the first switching position on the switching terminal a side shown in the figure, and input from the starting end side transmission line 12a. The downlink signal is amplified in voltage by the downlink signal boost circuit section 32 and output toward the termination side transmission line 12b, and the upstream signal inputted from the termination side transmission line 12b is current amplified by the upstream signal boost circuit section 46 and output to the start end side. The signal is output toward the transmission path 12a.

In addition, the input/output switching control by the booster control unit 34 is performed when the first voltage detection unit 38 does not detect a predetermined line voltage due to a disconnection of the starting end side transmission line 12a, and the disconnection monitoring control unit 28 controls the switching circuit unit 30a, 30b is activated to connect the end of the loop transmission line 12 to the transmission section 22, and when a predetermined line voltage is detected by the second voltage detection section 40, the downstream signal circuit sections 42, 44 and the upstream signal The input/output switching circuit units 48 and 50 are switched to the second switching position on the switching terminal b side, and the downlink signal input from the termination side transmission line 12b is voltage amplified and output towards the start side transmission line 12a, and The upstream signal inputted from the transmission line 12a is current-amplified and output toward the terminal side transmission line 12b.

[Operation when the loop line is disconnected]
(Disconnection of the transmission line on the start end side)
FIG. 3 is a block diagram showing the operation of the input/output switching type booster when a disconnection fault occurs in the transmission line on the starting end side, and shows the booster control section 34, transmission section 36, and first voltage detection section 38 shown in FIG. 2. and the second voltage detection section 40 are omitted.

In the normal monitoring state where there is no disconnection in the loop transmission line 12, as shown in FIG. It has been switched to the first switching position which is the a side, and the downlink signal input from the start side transmission line 12a is voltage amplified by the downlink signal boost circuit section 32 and output towards the end side transmission line 12b. The upstream signal inputted from the transmission path 12b is current-amplified by the upstream signal boost circuit section 46, and is outputted toward the starting end side transmission path 12a.

In this state, as shown in FIG. 3, if a disconnection 52 occurs in the start-end transmission line 12a, the disconnection monitoring control unit 28 of the receiver 10 shown in FIG. When it is detected that the line voltage is cut off, the switching circuit sections 30a and 30b are turned on, and the transmission section 22 is connected to the terminal end of the loop transmission line 12. Therefore, with respect to the location where the disconnection 52 in FIG. 3 occurs, the downlink signal output from the transmission section 22 is transmitted from both the start and end ends of the loop transmission line 12.

At this time, the first voltage detection section 38 of the input/output switching type booster 16 no longer detects the predetermined line voltage due to the disconnection 52, and the second voltage detection section 40 detects that the end of the loop transmission line 12 is connected to the transmission section 22. As a result, as shown in FIG. 3, the booster control section 34 switches the down signal input/output switching circuit sections 42, 44 and the up signal input/output switching circuit sections 48, 50. The switch is switched to the second switching position, which is the switching terminal b side, and the downlink signal input from the termination side transmission line 12b is voltage amplified by the downlink signal boost circuit section 32, and is directed toward the start side transmission line 12a where the disconnection 52 has occurred. Furthermore, the upstream signal inputted from the starting transmission line 12a where the disconnection 52 has occurred is amplified by current in the upstream signal boost circuit section 46, and is output toward the terminal transmission line 12b.

Therefore, even if a disconnection 52 occurs in the transmission line 12a on the starting end side of the loop transmission line 12, the downlink signal will be transmitted between all the fire detectors 18 connected to the loop transmission line 12 and the transmission section 22 of the receiver 10. This makes it possible to transmit and receive upstream signals, and the fire monitoring function of the fire detector 18 is not lost.

Note that the disconnection 52 is a disconnection in the signal cable used in the loop transmission line 12, and although it is shown as a disconnection 52 in the positive side signal line in FIG. The above effect can be produced even if both signal lines are disconnected.

(Disconnection of transmission line on the terminal side)
FIG. 4 is a block diagram showing the operation of the input/output switching type booster in the normal monitoring state and when a disconnection fault occurs in the terminal side transmission line, and shows the booster control section 34, transmission section 36, and first The voltage detection section 38 and the second voltage detection section 40 are omitted.

As shown in FIG. 4, in the normal monitoring state in which the downlink signal input/output switching circuit units 42, 44 and the upstream signal input/output switching circuit units 48, 50 are switched to the first switching position, which is the switching terminal a side, the terminal side Assuming that a disconnection 54 occurs in the transmission line 12b, the disconnection monitoring control unit 28 of the receiver 10 shown in FIG. The circuit sections 30a and 30b are turned on, and the transmission section 22 is connected to the terminal end of the loop transmission line 12. Therefore, with respect to the location where the disconnection 54 in FIG. 3 occurs, the downlink signal output from the transmission section 22 is transmitted from both the start end and the end end of the loop transmission line 12.

At this time, the first voltage detecting section 38 of the input/output switching type booster 16 detects a predetermined line voltage without being affected by the disconnection 54 of the termination side transmission line 12b, and the second voltage detecting section 40 detects the voltage falling from the booster. Since the voltage is being applied because the signal is being output in the direction, the open end has simply changed from the switching circuit section 30a to the disconnection point, and a predetermined line voltage is detected, which means that the loop transmission line 12 This is the same as a normal state with no disconnection, and therefore the booster control unit 34 switches to the first switching terminal a side of the downlink signal input/output switching circuit units 42, 44 and the upstream signal input/output switching circuit units 48, 50. The switching of positions will be maintained.

That is, the disconnection 54 of the termination side transmission line 12b can be recovered by only controlling the disconnection monitoring control unit 28 of the receiver 10 to turn on the switching circuit units 30a and 30b to connect the transmission unit 22 to the termination side of the loop transmission line 12. can do.

[Other embodiments of input/output switching type booster]
FIG. 5 is a block diagram showing another embodiment of the input/output switching type booster. As shown in FIG. 5, the input/output switching type booster 16 of this embodiment has a first downlink signal boost that unidirectionally amplifies the voltage of the downlink signal input from the start end transmission line 12a and outputs it to the end end transmission line 12b. A circuit section 32a and a second downlink signal boost circuit section 32b are provided which amplify the voltage of the downlink signal input from the termination side transmission line 12b in the opposite direction and output it to the start side transmission line 12a. A first upstream signal boost circuit section 46a that amplifies the input upstream signal in one direction and outputs it to the starting end side transmission line 12a, and a first upstream signal boost circuit section 46a that current amplifies the inputted upstream signal in one direction and outputs it to the starting end side transmission line 12a, and a first upstream signal boost circuit section 46a that current amplifies the inputted upstream signal in the opposite direction and outputs it to the starting end side transmission line 12a. It is characterized by providing a second upstream signal boost circuit section 46b that outputs to the transmission line 12b.

Downlink signal input/output switching circuit units 42 and 44 are provided for the first downlink signal boost circuit unit 32a and the second downlink signal boost circuit unit 32b, and the first uplink signal boost circuit unit 46a and the second uplink signal boost circuit Upstream signal input/output switching circuit sections 48 and 50 are provided for the section 46b.

When there is no disconnection in the loop transmission line 12 or when a disconnection occurs in the termination side transmission line 12b, the booster control unit 34 operates based on the detection of a predetermined line voltage by the first voltage detection unit 38 and the second voltage detection unit 40. The downlink signal input/output switching circuit sections 42, 44 and the upstream signal input/output switching circuit sections 48, 50 are switched to the first switching position, which is the switching terminal a side, and the first downlink signal boost circuit section 32a is inserted into the loop transmission line 12. The downlink signal inputted from the start-side transmission line 12a is voltage amplified and outputted to the termination-side transmission line 12b, and the first upstream signal boost circuit section 46a is inserted and connected to the loop transmission line 12 for termination-side transmission. The upstream signal input from the line 12b is current-amplified and output to the start-end transmission line 12a.

On the other hand, when a disconnection occurs in the start-end transmission line 12a, the first voltage detection section 38 no longer detects the predetermined line voltage, and the second voltage detection section 40 detects the predetermined line voltage, and based on this, The booster control unit 34 switches the downlink signal input/output switching circuit units 42, 44 and the upstream signal input/output switching circuit units 48, 50 to the second switching position, which is the switching terminal b side, and loops the second downlink signal boost circuit unit 32b. It is inserted and connected to the transmission line 12, voltage amplifies the down signal input from the termination side transmission line 12b and outputs it to the start side transmission line 12a, and the second upstream signal boost circuit section 46b is inserted and connected to the loop transmission line 12. Then, the upstream signal inputted from the start-side transmission line 12a is current-amplified and output to the termination-side transmission line 12b.

Since the other configurations and functions are the same as those of the embodiment shown in FIG. 2, the same reference numerals are given and explanations thereof will be omitted.

In this way, the first downlink signal boost circuit section 32a, the second downlink signal boost circuit section 32b, the first uplink signal boost circuit section 46a, and the second uplink signal boost circuit section 46b are dedicated according to the transmission direction of the loop transmission line 12. By providing this, even if the input/output switching type booster 16 is not provided at the intermediate point of the loop transmission line 12, and the electrical characteristics including resistance of the start-end transmission line 12a and the termination-side transmission line 12b are different, Optimum signal amplification and transmission is possible by individually setting amplification factors that match the electrical characteristics of the output-side transmission path. The amplification factor may be set using a known variable resistor.

[Modification of the present invention]
The above embodiment takes a disconnection fault as an example, but even if the system intentionally causes a disconnection, such as in the operation of a short circuit isolator that disconnects a short circuit, the booster operates as if it were a disconnection. .

In the above embodiment, the loop wiring is drawn out from the receiver, but the sensor and the booster may be connected to the loop wiring drawn out from the repeater connected to the receiver.

In the above embodiment, the upstream signal and the downstream signal can be amplified at the same time, but it is also possible to amplify only one direction as long as the direction of amplification of the signal is switched in the event of a disconnection. For example, in the case of a fire alarm system in which both the voltage signal and the current signal are downlink signals, the downlink signal is normally amplified, and the amplification direction is changed when the wire is disconnected.

In addition to the embodiments described above, the input/output switching type booster 16 may be one that insulates the input/output. For example, the amplification section is insulated from the input terminal and the first voltage detection section 38 using a photocoupler or the like, and the output terminal and the second voltage detection section 40 are insulated from the amplification section using a photocoupler or the like. By insulating the input/output terminals, it is possible to prevent the signal output of the booster from colliding with the signal output of the receiver, which would occur if only the GND line was disconnected.

In addition to the embodiments described above, the fire alarm system may have an automatic test function. For example, it is confirmed that the signal amplification direction of the input/output switching type booster 16 is reversed when the output of the transmission section 22 is stopped only on the starting end side and the switching circuit sections 30a and 30b are turned on. Alternatively, a signal may be transmitted from the receiver to the input/output switching type booster 16 to switch the amplification direction.

The above embodiment takes as an example a fire alarm system in which an R-type fire detector is connected via a loop transmission path from an R-type receiver, but a loop-type detector connected from a P-type receiver is used as an example. The same applies to fire alarm equipment in which an address is set on a line and an addressable fire detector with a transmission function is connected.

Further, the present invention includes appropriate modifications without impairing its objects and advantages, and is not limited by the numerical values shown in the above embodiments.

10: Receiver 12: Loop transmission line 12a: Starting end side transmission line 12b: Terminating side transmission line 14a, 14b: Signal line 16: Input/output switching type booster 18: Fire detector 20: Reception control section 22, 36: Transmission section 28: Disconnection monitoring control section 30a, 30b: Switching circuit section 32: Downlink signal boost circuit section 32a: First downlink signal boost circuit section 32b: Second downlink signal boost circuit section 34: Booster control section 38: First voltage detection section 40: Second voltage detection section 42, 44: Downlink signal input/output switching circuit section 46: Upstream signal boost circuit section 46a: First upstream signal boost circuit section 46b: Second upstream signal boost circuit section 48, 50: Upstream signal input Output switching circuit section

Claims (2)

A booster used in fire alarm equipment that connects a fire detector to a loop transmission line connected in a loop to a receiver or a repeater connected to the receiver,
The booster is
It is inserted and connected in the middle of the loop transmission line, and amplifies the signal input from one side and outputs it to the other side,
A booster characterized in that the amplification direction is switched based on an operation test using a signal transmitted from the receiver.
The booster according to claim 1,
The amplification direction is determined by an operation test in which the receiver transmits a signal from the end side of the loop transmission path without transmitting a signal from the start end side, and an operation test in which the receiver transmits a signal from the start end side of the loop transmission path. A booster that is characterized by switching.

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