KR100682014B1 - System for sensing early overheat using bimetal - Google Patents

Abstract

According to the present invention, a bimetal is directly contacted and installed on the surface of a monitoring object such as a cable or a connection part of a cable disposed in a power device, but when the monitoring object is overheated above the response temperature of the bimetal, the monitoring circuit is triggered to cause an overheating abnormality through wired / wireless. The present invention relates to an early detection system for abnormal heat generation using bimetal, which can be notified in advance. The configuration of the fire monitoring system of a power device includes: a connection part in the surface of each cable or terminal block disposed inside / outside the power device. If the bimetals are installed in direct contact with the bimetals to detect abnormal heat and are supplied with a predetermined DC power supply, the bimetals are electrically connected in parallel with each of the bimetals to detect an overheat of a predetermined range. RF transmission to generate unique ID and overheat detection radio signal The RF receiver receives an overheat detection radio signal from the RF transmitters, amplifies and converts it into a wired signal, and converts it into a wired signal and displays an overheat detection alarm, and an overheat detection signal connected to the RF receiver and a wired network, but transmitted from the RF receiver. Receiving the ID of the RF transmitter to receive and display the ID and overheating information, and includes a monitoring computer for generating an alarm signal.

Description

Early detection system for abnormal heat generation using bimetals {SYSTEM FOR SENSING EARLY OVERHEAT USING BIMETAL}

1 is a conceptual diagram illustrating a fire monitoring system of a power device according to the present invention.

2 is a diagram illustrating a detailed configuration of an RF transmitter applied to the present invention.

3 is a view showing a detailed configuration of the RF receiver applied to the present invention.

* Explanation of symbols for the main parts of the drawings

1: monitoring object (cable or connector) 10: bimetal

30: RF transmitter 31: input unit

35: control unit 37: wireless transmitter

39: power supply means 50: RF receiver

51: radio receiver 53: control unit

55: timer 57: alarm signal generating means

59: communication unit 70: monitoring computer

The present invention relates to an abnormal heat generation monitoring system. In particular, when the bimetal is contacted and installed on the surface of a cable or a connection part disposed inside / outside of a power device, the cable triggers a monitoring circuit when the cable is overheated above the operating temperature of the bimetal. The present invention relates to an early detection system for abnormal heat generation using bimetals for early notification of overheating abnormal conditions.

In general, it is a fire-related monitoring system that monitors the overheating state of the object and detects the outbreak of the fire at an early stage. Usually, development is focused on the fire detector rather than the overheat detector. There is a method of detecting heat accompanying a fire, a method of detecting smoke, and a method of detecting infrared rays.

Such a fire detector has the advantage of detecting the fire early and extinguishing the fire early, but there are fundamental limitations such that the reliability of the detection performance is ensured only when the detector is installed in an enclosed space. There was a great deal to pinpoint or fundamentally resolve.

For example, as in Korean Patent Publication No. 2003-88898, an electrolyte solution is contained in a glass ampoule and separated from an active material, and when a temperature rises in a fire, a thermally bonded solder is melted and a fixed intermittent cracker is usually fixed based on elastic force. In this case, a fire detection device having a built-in storage battery capable of driving a circuit part with a power source generated by contact with a leaked electrolyte solution and an active material is disclosed. It has the advantage of being able to extinguish fires, but it is very difficult to pinpoint or fundamentally solve the cause of fire.

In addition, there are detection systems such as detecting a gas emitted by destroying the can when the temperature rises in a fire after accumulating gas in a predetermined can and generating a fire alarm. However, a fire detector including the glass ampoule or can is somewhat used. It is expensive and it is quite burdensome to install a large number, and it is quite burdensome to install the detector directly on the monitoring object instead of installing it directly. In addition, since the detector must be installed in an enclosed space, there are limitations due to the installation and detection space, and various problems such as the maximum effect can be achieved only when combined with various systems such as a fire extinguisher for fire suppression.

Accordingly, an object of the present invention is to install a direct contact with the bimetal on the surface of the monitoring object, such as the cable or the connection portion of the cable disposed in the power equipment, but if the monitoring object is overheated above the response temperature of the bimetal, trigger the monitoring circuit to wire / wireless It is to provide an early detection system for abnormal heat generation using bimetal that can notify the overheat abnormal condition early.

Another object of the present invention is to install the bimetal directly in the monitoring object located inside and outside the power equipment such as switchboard, distribution panel, transformer, etc., it is possible to accurately determine the heat abnormality state of the monitoring object to take action or replace the component early It is to provide an early detection system for abnormal heat generation using bimetal that can prevent fire at the source.

Technical means of the present invention for achieving the above object, in the fire monitoring system of the power device: installed in direct contact with the surface of each cable or terminal block disposed on the inside / outside of the power device to detect abnormal heat generation Bimetals; It operates by receiving a predetermined DC power, and is electrically connected in parallel with each of the bimetals, and when any one of the plurality of bimetals detects overheating over a preset range, it generates and transmits its own ID and an overheating detection radio signal. RF transmitter; An RF receiver for receiving and amplifying an overheat detection wireless signal from the RF transmitters, converting the amplification signal into a wired signal, and displaying an overheat detection alarm; And a monitoring computer connected to the RF receiver and a wired network, receiving an overheat detection signal transmitted from the RF receiver, identifying an ID of the RF transmitter, displaying an ID and overheating information, and generating an alarm signal. do.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a conceptual diagram showing a fire monitoring system of a power device according to the present invention, Figure 2 is a view showing a detailed configuration of the RF transmitter applied to the present invention, Figure 3 is a detailed configuration of the RF receiver applied to the present invention As shown in the figure, the bimetal 10, the RF transmitter 30, the RF receiver 50, the monitoring computer 70, and the like.

The bimetal 10 is a sensor that is installed in contact with the surface of each cable (3) disposed in the inside / outside of the power device or the connecting portion 5 in the terminal block, respectively, to detect abnormal heat generation, the RF transmitter 30 is the bimetal 10 and current paths are connected to each other, but when any one of the plurality of bimetals (10 to 10n) detects overheating over a preset range, it is configured to generate and transmit an overheat sensing radio signal with a unique ID, and RF receiver 50 is configured to receive and amplify the overheat detection wireless signal from the RF transmitter 30, convert it into a wired signal, and display an overheat detection alarm, and the monitoring computer 70 displays the RF receiver 50. Connected to the wired network with the overheat alarm signal transmitted from the RF receiver 50 to identify the ID of the RF transmitter 30 and then display the ID and overheating status information and alarm signal. It is configured to occur.

In addition, the RF transmitter 30 is connected in parallel with each of the plurality of bimetals 10 to 10n in a wired manner, and the RF receiver 50 is configured to wirelessly communicate with the plurality of RF transmitters 30 to 30n. The monitoring computer 70 is connected to the plurality of RF receivers 50, ... through a wired communication network.

The bimetal 10 has various types according to the response temperature. For example, the bimetal 10 may be appropriately used according to the superheat determination reference temperature (60 ° C., 80 ° C., 100 ° C., etc.) of the monitoring object 1. .

That is, the monitoring object 1 such as a cable 3 located inside / outside of a power device such as a distribution board, a distribution board, a transformer, a capacitor, a motor, or the like, or a connection part 5 of the cable (a bolt or a screw connected to the cable). The bimetal 10 is directly contacted and installed on the surface, and the RF transmitter 30 connected to the plurality of bimetals 10 to 10n is installed for each power device.

In this state, when the monitoring object 1 is overheated above the sensitive temperature of the bimetal 10, the corresponding RF transmitter 30 is triggered to generate an overheat detection signal, and the RF receiver matched with the RF transmitter 30 ( 50) is to receive the overheat detection signal over the air to notify the monitoring computer 70 of the overheat abnormality condition over the wire.

When any one of the plurality of bimetals 10 to 10n detects an overheating state of the monitoring object 1, the RF transmitter 30 notifies the RF transmitter 30, and the RF transmitter 30 of the bimetal 10 notifies the overheating state. The overheat detection message including the serial number and the ID of the RF transmitter 30 stored in advance in the memory 33 is transmitted to the RF receiver 50 to be notified.

The bimetal 10 is installed using a predetermined tie on the surface of the cable 3 or the connecting portion 5 (the bolt or screw portion to which the cable is connected) in the terminal block. The bimetal 10 is shown in FIG. As shown in FIG. 2, the input unit 31 of the RF transmitter 30 is connected in parallel.

In operation of the bimetal 10 according to overheating of the monitoring object 1, the contacts are connected (closed loop formation), and a predetermined detection signal is supplied to the input unit 31 to inform the input unit 31 of the abnormal state of overheating.

The input unit 31 amplifies the overheat detection signal transmitted from the bimetal 10 and outputs it to the control unit 35, and the control unit 35 outputs to the wireless transmitter 37 together with the ID stored in the memory 33. do.

Subsequently, the wireless transmitter 37 amplifies the overheat detection signal output to the controller 35, modulates the overheat detection signal into a predetermined wireless signal, and sends the same.

The RF transmitter 30 may be supplied with power using a commercial AC power source, but the circuit of the RF transmitter 30 is designed with only a minimum configuration so that the primary battery (for example, a small battery such as a battery) More preferably, it is configured to receive the operating power through the same power supply means (39).

In addition, when any one of the plurality of bimetals 10 to 10n connected to the input unit 31 detects overheating, the RF transmitter 30 generates an overheat detection message.

Then, the overheat detection radio signal transmitted from the radio transmitter 37 is received through the radio receiver 51 of the RF receiver 50 as shown in FIG. 3, but is down-converted to a predetermined signal and amplified and output to the controller 53. Done.

The controller 53 temporarily stores the overheat detection-related message received through the wireless receiver 51 in the memory 54 and then checks the ID of the RF receiver 50, the overheat detection message, and the timer 55. In addition to outputting the overheat alarm message to summarize the time and the like to the communication unit 59 and alarm signal generating means 57 by operating the alarm sound or alarm lamp to visually notify the overheating state.

The communication unit 59 amplifies the overheat alarm message output from the control unit 53 and outputs it to the monitoring computer 70 through a wired communication network such as a LAN.

The monitoring computer 70 collects the data transmitted from the RF receiver 50 and analyzes the overheating alarm message, stores and manages the overheating alarm message in the storage means, and identifies the ID of the monitoring object 1 according to a predetermined management program. Display the location and overheating detection time on the monitor and notify the administrator through the overheat alarm signal to take urgent action.

As described above, although a specific embodiment of the present invention has been described and illustrated, it is obvious that the present invention may be variously modified and implemented by those skilled in the art, such as by wirelessly connecting the RF receiver and the monitoring computer. Such modified embodiments should not be understood individually from the technical spirit or the prospect of the present invention, but should fall within the claims appended to the present invention.

Therefore, in the present invention, by directly installing a bimetal on the surface of the monitoring object such as a cable or a connection portion of the fire that is easy to fire, if the monitoring object is overheated above the response temperature of the bimetal, the monitoring circuit is triggered to overheat via wired or wireless In addition to the early notification of abnormal conditions, the low cost of bimetallic detectors significantly reduces installation costs, and by installing directly on the monitored object, it is possible to accurately identify the abnormality of heat generation, so that the corresponding parts can be taken early or There is an advantage to prevent the source by replacing the fire.

Claims (5)

In the fire monitoring system of power equipment: Bimetals that detect abnormal heat generation when directly overheated above a response temperature by being installed in direct contact with a surface of each cable disposed inside / outside the power device or a connection part in a terminal block; It operates by receiving a predetermined DC power, and is electrically connected in parallel with each of the bimetals, and when any one of the plurality of bimetals detects overheating over a preset range, the bimetal serial number and memory stored in advance are notified. An RF transmitter for generating and transmitting a unique ID of the RF transmitter and an overheat sensing radio signal; An RF receiver for receiving and amplifying an overheat detection wireless signal from the RF transmitters, converting the amplification signal into a wired signal, and displaying an overheat detection alarm; And Connected to the RF receiver and a wired network, receiving the overheat detection signal transmitted from the RF receiver, checking the ID of the RF transmitter, displaying the overheat abnormality information which summarized the overheat detection time checked through the ID, the overheat detection message, and the timer. A supervisory computer for notifying the manager through an overheat alarm signal to take an emergency action; Abnormal fever early monitoring system using a bimetal, characterized in that it comprises a. delete delete delete delete

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