KR100668991B1 - Building alarm device - Google Patents

Abstract

Disconnection detection of the telephone line in the alarm device is performed at low cost without a bad decision. The line voltage monitoring circuit 23 monitors the voltage between the telephone lines when the telephone line 5 is opened. Since the voltage is monitored by a very small current, there is a possibility of abnormal detection failure due to noise. Therefore, when an abnormality is detected, the line closing means 13 closes the telephone line, and the line current monitoring circuit 24 monitors the line current. Since the line current is monitored by a relatively large current, the possibility of a defective judgment due to noise is reduced. If an abnormality is detected during monitoring by this line current, the telephone line is determined to be disconnected, and the notification means 25 outputs a disconnection signal. In the present invention, since the number of line closures is not large, an increase in system cost may be limited.

Description

Building alarm device

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an alarm reporting apparatus used in an alarm system using a telephone line, and more particularly to an alarm apparatus capable of monitoring disconnection of a telephone line.

Various alarm systems for centrally monitoring the building by installing an alarm device in a building, a condo, connecting the alarm device to a remote central monitoring center, and monitoring the building at the central monitoring center have been applied in real life. Various sensors, such as security sensors and disaster prevention sensors, are connected to the alarm device of such an alarm system, and when any one of these sensors detects an abnormality, an alarm is given to the monitoring center via the telephone line. In this alarm system, if the telephone line is disconnected for some reason or the like, the alarm system does not operate even when the sensor detects an abnormality and the alarm does not reach the central monitoring center.

Therefore, a signal is periodically transmitted from the alarm device to the monitoring center at a time interval of, for example, one to two hours, and the monitoring center monitors the periodic transmission of this signal. If this signal is not received periodically, the monitoring center determines that the telephone line is disconnected and sends a security guard to the building to confirm safety and take the necessary action according to the situation.

On the other hand, on the alerting device side, the current flowing through the telephone line is monitored at the time of transmission of the aforementioned periodic signal. At this time, if the current is not detected, the alarm device determines that a disconnection exists in the telephone line, and notifies the surrounding person that the telephone line is disconnected by ringing a buzzer. Between transmissions of the periodic signals, since the telephone line is open, detection of disconnection by line current is not performed. Therefore, the voltage between the lines is monitored while the telephone line is open, and if no voltage is detected, the telephone line is determined to be disconnected.

However, the detection of the line voltage is done by providing a high resistance between the telephone lines so that a very small current flows and detecting this very low current. In other words, since the detection of the disconnection made by monitoring the line voltage is performed by detecting a lower current than the monitoring of the line current, it is susceptible to noise, and thus there is a possibility of failure determination. In contrast, disconnection monitoring performed by using line current is less susceptible to noise by using a larger current value, so that disconnection can be detected more reliably. Therefore, it is conceivable to shorten the transmission interval of the periodic signal and increase the number of times of monitoring by the line current. However, in this case, another problem arises that the operating cost of the system increases as the number of transmissions increases.

SUMMARY OF THE INVENTION An object of the present invention is to detect disconnection of a telephone line at low cost without a bad decision in an alarm device that notifies the destination of an abnormality occurrence through a telephone line.

The present invention has been accomplished to achieve the above object. Upon detection of such an abnormality, in an alarm device that notifies the predetermined destination of the occurrence of an abnormality, the device monitors the voltage applied between these telephone lines when the telephone line is opened. When an abnormality is detected by monitoring using the line voltage, the telephone line is closed and the line current is monitored. If any abnormality is detected during monitoring of this line circuit, the apparatus determines whether the telephone line is closed and outputs a disconnection signal.

In order to achieve the above object, the alarm apparatus includes line voltage monitoring means for monitoring a line voltage when the telephone line is opened to detect an abnormality in the line voltage; Line current monitoring means for monitoring a line current when the telephone line is closed to detect an abnormality in the line current; D.C. of the telephone line Line closing means for performing a closing operation of the circuit; And disconnection determination means connected to said line voltage monitoring means, said line current monitoring means and said line closing means.

If the line voltage monitoring means detects an abnormality, the disconnection determination circuit determines that the line closing means is set to D.C. When the line current monitoring means detects an abnormality when the line is closed, the judging means determines whether a disconnection has occurred in the telephone line and outputs a disconnection signal. If no abnormal input is given by the line current monitoring means and the line is closed, the determination means determines that no disconnection exists in the telephone line.

According to this configuration, if disconnection occurs while the telephone line is open, the line voltage is lowered, and the line voltage monitoring means detects an abnormality. Next, even if the telephone line is closed, if the line current does not flow, the line current monitoring means detects an abnormality. As a result, the disconnection determination means outputs a disconnection signal. On the other hand, if the line voltage monitoring means detects an abnormal voltage due to noise even when no disconnection has occurred, a line current flows when the telephone line is closed, and the line current monitoring means detects this line current. When the line current is detected, the disconnection determination means determines that disconnection does not occur. Therefore, the disconnection signal is not output, and bad operation due to noise can be prevented.

The monitoring by the line current is performed only when it is determined that disconnection has occurred by monitoring the line voltage. Therefore, the number of closures of the line is reduced and the increase in operating cost of the alarm system is prevented.

In the present invention, it is also possible to accumulate a very small current in the capacitor, and to monitor the discharge current of the capacitor instead of detecting a very small current due to the line voltage to monitor the line voltage. In this case, the influence of noise on the discharge current becomes smaller, and thus the line voltage can be monitored in a state where the influence of noise is small. Therefore, the occurrence of malfunction due to the noise can be reduced, and the number of times of closing the line to monitor the line current can also be reduced.

The above objects and features of the present invention will become apparent from the following description of the preferred embodiments made with reference to the accompanying drawings.

DESCRIPTION OF THE PREFERRED EMBODIMENTS A preferred embodiment of the present invention will be described with reference to the accompanying drawings.

1 is a block diagram showing the configuration of an alarm system to which an alarm device is applied.

In Fig. 1, reference numerals 3, 3 ... denote buildings to be monitored, in which the alarm device 4 is installed. The alarm device 4 provided in each building 3 is connected to the central monitor 2 of the monitoring center 1 via the telephone line 5 and the switch board 8 at a remote place. Reference numeral 10 denotes a waiting station for the guard. This waiting station 10 is connected to the central monitor 2 of the central monitoring center 1 via the telephone line 5 and the switch 8.

Various sensors 6, 6,..., Such as security alarm sensors, disaster prevention alarm sensors, etc., installed at predetermined locations of the building under surveillance, are connected to the alarm device 4. In addition, the telephones 7 and the facsimile 9 are connected to the telephone line 5 via the alarm device 4.

When a sensor 6 outputs an alarm signal in the alarm system shown in FIG. 1, the alarm device 4 notifies the central monitor 2 of the alarm. Upon receiving this alert, the central monitor 2 displays the occurrence of the alert to the person in the monitoring center 1. The monitoring center 1 notifies the waiting station 10 according to its type and sends security guards to the building where the alarm is detected.

The alarm device 4 transmits a predetermined signal periodically (e.g. every hour) to the central monitor 2. The central monitor 2 monitors the reception of this signal and determines that a disconnection has occurred in the telephone line 5 when periodic transmission is interrupted and sends security guards to the building.

Security guards sent to the monitoring building will check safety and take the necessary action based on the given situation.

2 shows the configuration of the alarm device 4.

In the alarm device 4 of this embodiment, the disconnection determination circuit 21 is inserted between the alarm monitoring circuit 12 and the phone line 5 to detect the disconnection of the phone line 5 on the alarm device 4 side. do. Various sensors 6, 6,... And facsimile 9 are connected to the alarm monitoring circuit 12.

Typically, the alarm monitoring circuit 12 connects the telephone line 5 to the telephone 7 and the facsimile 9. If some sensors 6 and 6 detect an abnormality and output a signal, the telephone line is closed by the circuit closing means 13 and an alarm signal is transmitted to the central monitor 2. In order to detect the disconnection of the telephone line 5, the alarm monitoring circuit 12 periodically closes the telephone line and transmits a predetermined signal to the central monitor 2. Since the configuration and operation of this alarm monitoring circuit 12 are well known in the art, detailed description thereof will be omitted.

The disconnection determination circuit 21 is provided for detecting the disconnection of the telephone line 5 in the alarm device. Input terminals L1 and L2 of the disconnection determination circuit 21 are connected to the telephone line 5, and output terminals L1 'and L2' are connected to the alarm monitoring circuit 12. As shown in FIG. One input terminal of the input terminals L1 is connected to the output terminal of one of the output terminals L1 'by the line current monitoring circuit 24, and the other input terminal L2 is connected to the other output terminal (L). L2 ') directly. The line voltage monitoring circuit 23 is inserted between the input terminal L1 and the input terminal L2. The output signal of the line current monitoring circuit 24 and the output signal of the line voltage monitoring circuit 23 are input to the CPU (central processing unit) 22.

A notification circuit 25 having a buzzer or a light emitting lamp is connected to the CPU 22. The CPU 22 is connected to the line closing circuit 13 inside the alarm monitoring circuit 12 and outputs a line closing command signal to detect a line closing state.

Referring to Fig. 3, the configuration of the line voltage monitoring circuit 23 is shown.

The voltage between the input terminal L1 and the input terminal L2 is rectified by the full-wave rectifier D1 and divided by the resistors R1 and R2. The voltage of the power supply V1 is divided by the resistors R3 and R4. These two divided voltages are input to the comparator CP1, and the transistor Tr is controlled on / off by the output of the comparator CP1. Photodiode PD1 of photocoupler PC1 is connected between transistor Tr and power supply V1. The photo transistor PT1 of the photo coupler PC1 is connected to the CPU 22.

Here, when the line voltage is a constant value, the output of the comparator CP1 is L (low), and the transistor Tr is turned off. Therefore, no current flows through the port diode PD1, and therefore the photo transistor PT1 is turned off. In contrast, when the line voltage decreases, the output of the comparator CP1 becomes H (high), so that the transistor Tr is turned on, so that current flows through the port diode PD1 to the port transistor PT1. Is turned on.

4 shows the configuration of the line current monitoring circuit 24.

The photodiode PD2 of photocoupler PC2 is connected between input terminal L1 and output terminal L1 '. The output of the photo transistor PT2 is connected to the CPU 22. Here, when current flows through the telephone line 5, the photo transistor PT2 is turned on, and when no current flows, the photo transistor PT2 is turned off.

The operation of the CPU 22 of the disconnection determination circuit 21 will be described with reference to the flowchart in FIG. 5. By the way, this disconnection determination circuit 21 is provided in order to detect the disconnection of the said telephone line 5 in the alert apparatus 3 side as already demonstrated. The process of detecting the disconnection of the telephone line 5 on the central monitoring center 1 side is performed by the alarm monitoring circuit 12 in the same manner as the conventional system.

First, whether the telephone line 5 is open or not is determined in step S1 of FIG. This determination checks the state of the circuit disconnection circuit 13 in the alarm monitoring circuit 12. If the result is found to be NO (closed), the flow proceeds to step S4, and if YES (open), the flow proceeds to step S2.

The line voltage is monitored at step S2. Here, the state of the photo transistor PT1 of the line voltage monitoring circuit 23 is checked. Since the telephone line 5 is opened under the state of step S2, the state is determined to be normal when the circuit voltage exceeds a predetermined value, and is determined to be abnormal when smaller than the predetermined value. In other words, the state is determined to be normal when the photo transistor PT1 is turned off and the flow proceeds to step S3.

In fact, even if there is no disconnection, there is a case where the state is determined to be abnormal due to the influence of noise. Therefore, the flow proceeds to the operation of confirming disconnection of step S3 described later.

In step S3, the CPU 22 transmits the signal to the line closing circuit 13 side of the alarm monitoring circuit 12 and the telephone line is closed inside the alarm monitoring circuit 12. In addition, when the line is closed, a predetermined signal is transmitted from the alarm device 3 side to the monitoring center 1 side whenever necessary.

In step S4, the line current is monitored. Here, the state of the photo transistor PT2 of the line current monitoring circuit 24 is checked. Since the telephone line 5 is closed in the state of the step S4, when the line current exceeds a predetermined value, the state is determined to be normal, and when lower than the predetermined value, it can be determined to be abnormal. In other words, the state is determined to be normal when the photo transistor PT2 is turned on, and the flow returns to step S1. When the transistor PT2 is turned off, the state is determined to be abnormal and the flow proceeds to step S5. If the monitoring of the line current is performed using a current larger than the monitoring of the line voltage, a judgment failure caused by noise does not occur.

In step S5, the notification circuit 25 outputs an alarm to complete the disconnection determination operation. As the alarm output, the buzzer rings and the lamp emits light, and the disconnection of the telephone line 5 can be determined on the alarm device 3 side.

As described above, if it is determined that the possibility of disconnection exists by monitoring the line voltage, the presence of the disconnection is determined by monitoring the line current. Therefore, if a determination failure occurs during the line voltage monitoring due to noise, the disconnection of the telephone line can always be determined accurately. Since the monitoring of the line current is performed only when the line is opened and when an abnormality in the line voltage is detected, the number of closings of the telephone line can be reduced, and the increase in the cost of system operation can be prevented.

In the embodiment described above, the disconnection determination circuit 21 is configured separately from the alarm monitoring circuit 12, but the disconnection determination circuit 21 may be assembled into the alarm monitoring circuit 12.

Next, a modified example of the line voltage monitoring circuit 24 will be described with reference to FIG. 6.

In Fig. 6, symbol C1 represents a capacitor for forming a very small current flowing due to the line voltage. A full-wave rectifier D3 for rectifying the line voltage D3, a constant voltage circuit CC1, a photo transistor PT3 of the photocoupler PC3 and a diode D4 are connected to the capacitor C1 as a charging circuit. The constant voltage circuit CC1 includes a transistor TR1, a zener diode ZD1, and resistors R5, R6, and R7. The discharge resistor R8, the photo transistor PT4 of the photo coupler PC4 and the photodiode PD5 of the port coupler PC5 are connected to the capacitor C1 as a discharge circuit. The photodiode PD3 of the photocoupler PC3 of the charging circuit and the photodiode PD4 of the photocoupler PC4 of the discharge circuit alternately turn at predetermined intervals by a control signal from the CPU 22. On / turn off.

If the telephone line 5 is not disconnected and the line voltage is normal, the photodiode PD3 of the charging circuit is turned on, and then the photo transistor PT3 is turned on. During this ON period, the capacitor C1 is charged by a very small current due to the line voltage through the resistor R7. Next, when the photodiode PD4 of the discharge circuit is turned on, the phototransistor PT4 is turned on and the capacitor C1 is discharged through the discharge resistor R8. This discharge current turns on the photodiode PD5 of the output photo coupler PC5 and turns on the photo transistor PT5.

The CPU 22 determines that disconnection does not exist in the telephone line 5 when the turn-on of the photo transistor PT5 is detected at the time of discharge (when the photo transistor PT4 is turned on). On the other hand, when the telephone line 5 is disconnected, the line voltage no longer exists. Therefore, when the photodiode PD3 of the discharge circuit is turned on, the capacitor C1 is not charged, so that the output phototransistor PT5 is turned off during discharge. The CPU 22 determines whether the possibility of disconnection exists in the telephone line 5 when the turn-off of the output photo transistor PT5 is detected at the time of discharge. The flow proceeds to the processing of step S3 in the sequence of FIG. 5, where confirmation by line current is performed.

Even if the noise occurs, the influence of the noise is smaller than that of the discharge current of the capacitor C1 which generates a very small current. Therefore, the possibility of poor determination of the line voltage due to the noise is further reduced, and the number of times of closing the line to monitor the line current can also be reduced.

When the condition of the telephone line deteriorates and noise frequency appears on the telephone line, the line closing operation is frequently performed. In this case, the occurrence frequency of the abnormality determination by the line voltage monitoring circuit 26 and the next determination of the abnormality by the line current monitoring circuit 24 is monitored, and when the CPU 22 determines that the occurrence frequency is high, the CPU At 22, the charge / discharge interval of the capacitor C1 of the line voltage monitoring circuit 26 becomes longer. In this case, the generation frequency is calculated, for example, by counting the number of occurrences of such a phenomenon, and if this count exceeds five times within one hour, for example, the charge / discharge interval of the capacitor C1 is again from 30 ms to one second. Will be set.

According to the present invention, the disconnection of the telephone line can be monitored at all times in the alarm device which notifies the destination of the occurrence of the alarm, and the operation can be executed at low cost without causing a bad decision.

BRIEF DESCRIPTION OF THE DRAWINGS The figure which shows the structural example of the alarm system to which the alarm apparatus of this invention was applied.

2 is a circuit diagram showing an example of the alarm device of the present invention.

3 is a circuit diagram showing a line voltage monitoring circuit used in the alarm device shown in FIG.

4 is a circuit diagram showing a circuit current monitoring circuit used in the alarm device shown in FIG.

5 is a flowchart showing processing operations of the CPU shown in FIG.

6 is a circuit diagram showing a modification of the line voltage monitoring circuit shown in FIG.

* Explanation of symbols for main parts of the drawings

1: central monitoring center 2: central monitor

3: surveillance building 4: abnormal notification device

5: telephone line 7: telephone

8: exchanger 9: facsimile

10: waiting station 12: alarm monitoring circuit

13 circuit disconnection circuit 21 disconnection determination circuit

22: CPU 23, 26: line voltage monitoring circuit

24: line current monitoring circuit 25: notification circuit

Claims (2)

An alarm apparatus for notifying a predetermined destination via a telephone line when an abnormality is detected, Line current monitoring means for monitoring a line current when the telephone line is closed and detecting an abnormality in the line current; The line voltage is detected by connecting a high resistance between the telephone lines and flowing a current smaller than the line current, and detecting the abnormality of the line voltage by monitoring the line voltage when the telephone line is open. Monitoring means; D.C. of the telephone line Line closing means for closing the circuit; A disconnection determination means operatively connected to said line voltage monitoring means, said line current monitoring means and said line closing means, wherein said line closing means causes said D.C. And the disconnection determination means for determining that there is a disconnection on the telephone line when the circuit current monitoring means detects an abnormality under the circuit disconnection state and then outputs a disconnection signal. Device. The method of claim 1, The line voltage monitoring means, A capacitor charged by line current when the telephone line is opened; Means for repeatedly charging and discharging said capacitor in a predetermined cycle; Means for outputting an alarm signal when a discharge current is not detected at the time of discharge.

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