KR200203192Y1 - System monitoring over-heat - Google Patents

Abstract

The present invention is a linear heat sensing cable for detecting heat generated by the facility in contact with the facility, a voltage / current conversion unit for converting the electromotive force generated by the heat detection of the heat sensing cable into a current signal, and the voltage / current It receives the current signal output from the converter and converts it into the corresponding digital signal, and compares the input current data with temperature data set in advance in the memory to determine the current temperature state of the facility and converts the current into temperature data. Modulation and demodulation transmission means for amplifying and modulating data corresponding to a unique number of a heat sensing cable outputted from the processing control unit, a current temperature of a heat source, an overheat state, and a degree of fire, and transmitting the wires or wirelessly, and the modulation and demodulation. Heat sensing data transmitted from modulation and demodulation transmission means connected to transmission means by wire or wireless network The system is equipped with a control computer that collects and analyzes the collected temperature data and alerts or displays them step by step according to the overheating or fire state of the facility. By collecting and storing the status of facilities by hour, day, month, and year, they periodically search and check for abnormalities and deterioration status by facility to predict the time of repair and replacement of facilities at an appropriate time. It provides a remote heat monitoring system that can prevent the damage caused by fire in advance.

Description

Remote heat monitoring system {System monitoring Over-heat}

The present invention relates to a heat or fire monitoring system. In particular, when a heat is sensed, a linear sensing cable that generates a constant voltage according to semiconductor characteristics can be used to rapidly generate heat in a step-by-step manner in all areas where a cable is installed, not in a local area. The present invention relates to a remote thermal monitoring system that can detect and monitor a fire occurrence rate and status more quickly by detecting and transmitting data for each step to a control computer.

In general, fire detectors must be highly reliable and capable of identifying fires and many different types of stimuli. For example, if a fire does not occur, the fire detector system should not release the extinguishing product and should not sound an alarm bell.

Currently used fire detectors include a heat detector using heat generated by a fire and a smoke detector that captures smoke.

Examples of the thermal sensor include a bimetal type, and a photoelectric type such as a photosensitive type and a scattered light type is used as a smoke detector to capture smoke.

Other methods used for early detection of fires include infrared and ultraviolet detectors.

The bimetal type of the thermal sensor is operated by heat, and uses a displacement that is converted in proportion to temperature in a structure in which a low expansion metal and a high expansion metal are bonded.

Fire detection devices such as those described above are generally used in buildings and the like, it is difficult to detect fires environmentally in places such as engine rooms, boiler rooms or special vehicles underground, where communication, power cables, gas pipes, etc. are buried. There is a problem.

Conventionally, in order to solve such a problem, Korean Patent Publication No. 99-78477 discloses an 'automatic re-detection device using a coaxial cable' using an impedance variable according to ambient temperature as a fire detection signal. Is automatically activated when the fire extinguisher is detected. By comparing the duty cycle between the fire detection signal and the reference signal, the fire extinguisher is detected by detecting only the occurrence of a fire and the fire or fire detection point must be set somewhat higher. Early fire suppression can be rather difficult.

In addition, since a constant power must be continuously applied to the coaxial cable for detecting a fire, it consumes a lot of power. Due to the characteristics of the coaxial cable, the current heat temperature cannot be detected. There is a problem in that it is not possible to perform a proper response to the fire because it is limited to.

Therefore, the purpose of the present invention is to quickly detect the degree of fire for the entire area where the cable is installed by using a linear heat sensing cable that generates a constant voltage corresponding to the heat temperature when the heat is detected. In order to provide a remote heat monitoring system that can detect the overheating level of the facility, whether the fire is present, and the status of the facility more quickly, and respond more appropriately according to the overheating and the fire occurrence of the facility. have.

Technical means of the present invention for achieving the above object is a linear heat sensing cable for sensing the heat generated in the facility in contact with the facility; A voltage / current converter configured to convert the electromotive force generated by the heat sensing of the heat sensing cable into a current signal; It receives the current signal output from the voltage / current converter and converts it into a digital signal corresponding thereto, and compares the input current data with temperature data set in advance in the memory to determine the current temperature state of the facility, and then converts the current into temperature. A processing control unit for converting the data into data; Modulation and demodulation means for amplifying and modulating data corresponding to a unique number of a heat sensing cable output from the processing control unit, a current temperature of a heat source, an overheating state, and a degree of fire, and transmitting the wires or wirelessly; And a control computer connected to the modulation / modulation transmission unit by wire or wireless network to collect heat sensing data transmitted from the modulation / modulation transmission unit, analyze the collected temperature data, and alarm or display step by step according to an overheating or fire occurrence state of the facility. Characterized in that made.

1 is a view showing a remote thermal monitoring system according to an embodiment of the present invention,

2A and 2B are flowcharts illustrating an operating process of FIG. 1.

Explanation of symbols on the main parts of the drawings

10: thermal sensing cable 30: voltage / current conversion unit

50: processing control unit 70: modulation demodulation transmission means

90: control computer

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

1 is a schematic view showing a remote thermal monitoring system according to the present invention, a thermal sensing cable 10, voltage / current conversion unit 30, processing control unit 50, modulation demodulation transmission means 70 and control computer ( 90).

The thermal sensing cable 10 may be divided into a flexible thermoelectric line detector (FTLD) and a continuous thermocouple cable (CT ² C), and the FTLD includes a chrome wire 11 (+) and an aluminum wire (12 ;-), respectively. Wrapped by an insulator 13, the insulator 13 is again wrapped by an NTC material 15, the NTC material 15 is wrapped by an aluminum film 17, and the aluminum film 17 is an outer teflon. (19; TEFLON) is wrapped in material.

In addition, although not shown, CT ² C has an outer shell of an inconel material covering an insulator NTC powder, and the NTC powder surrounds a chrommel wire (+) and an alumel wire (-), respectively. .

Looking at each of the unique characteristics of the thermal sensing cable 10 made of such a structure and the function applied to the present invention are shown in Table 1.

Specification Characteristics One Outer material Teflon (or Inconel) 2 Electromotive force generation -50㎷ to 50㎷ 3 Input voltage none 4 Current temperature indication function has exist 5 Temperature set value change function has exist 6 Thermal Point Ability Indefinite 7 Thermal range -40 ° C to 260 ° C (or 1200 ° C) 8 Max continuous length 150M 9 Self-healing at maximum temperature has exist 10 Compatibility with standard instruments has exist 11 life span 20 years

The thermal sensing cable 10 having the characteristics as shown in Table 1 is a kind of thermocouple sensor using a Zee Back effect, and when heat of a predetermined temperature is detected, the chromel wire (+) and the aluminum As the temperature difference occurs between the wires (-), free electrons are generated to generate an electromotive force corresponding to several to several tens of kilowatts.

In addition, the voltage / current converter 30 receives a signal of several to several tens of kV generated from the heat sensing cable 10 and converts the current into a current of several to several tens of kW corresponding to the input voltage. The unit 30 operates by being supplied with a power of approximately 18V to 48V DC, the input temperature is -20 ° C to 1200 ° C, the operable external temperature is 0 ° C to 70 ° C, and the load resistance is operated at 0 to 750Ω. It is a designed transmitter.

In addition, the processing controller 50 receives the current signal output from the voltage / current converter 30, converts it into a digital signal corresponding thereto, and then compares the temperature-sensing temperature data preset in the memory with the thermal sensing cable 10. Comprising the current temperature of the heat source detected in the), specifically, the connector connected to the output terminal of the plurality of voltage / current conversion unit 30, the user memory for storing the user's arbitrary reference data, and the control program The stored system memory, a key input unit for arbitrarily setting an abnormal reference temperature value, a counter for counting input / output data, and an external device 30 through a serial interface such as RS-232 or RS-485 or S-Bus. 70) are configured to be interconnected.

And, the modulation and demodulation transmission means 70 includes a wired communication module 71 and a wireless communication module 75, the installation position of the heat sensing cable 10 output from the processing control unit 50 and the current temperature and overheating of the facility It consists of a communication means such as a modem for modulating and amplifying data corresponding to the state and the degree of fire and transmitting it by wire or wirelessly, and the control computer 90 is connected to the modulation / modulation transmission means 70 by wire or wireless to modulate and demodulate. Collects the heat detection data transmitted from the transmission means 70 and analyzes the collected data consists of a system such as a PC that alerts or displays step by step depending on whether the facility is overheated or fired.

In addition, the control computer 90 is preferably implemented to be able to quickly inform the administrator of the occurrence of the fire when the fire call information is added to the demodulation and demodulation transmission means 70 is added to the radio call means (95).

Looking at the operation of the present invention configured as described above with reference to the flow chart of Figures 2a and 2b.

First, in a state in which the heat sensing cable 10 is installed in a facility that may cause a fire due to heat, if the facility is overheated at a predetermined temperature or more, between the chrommel wire and the alumel wire of the thermocouple cable 10, which is a thermocouple sensor, Electromotive force of several to several tens of kW is generated to detect an overheating state of the facility and whether a fire occurs (S11).

Subsequently, the voltage / current converting unit 30 converts the voltage signal detected by the thermal sensing cable 10 into a current corresponding to several to several tens of mA, and at the same time, a detection signal input to a specific input terminal among a plurality of input terminals. By recognizing the unique number which is the installation position of the heat sensing cable 10, and outputs the current and the unique number data to the processing control unit 50 (S12).

The processing controller 50 receives the current signal output from the voltage / current converter 30 and converts it into a digital signal corresponding thereto (S13), and compares the input current data with the temperature data compared with the preset current data in the memory. After determining the current temperature state of the facility to convert the current into temperature data (S14).

In addition, the process control unit 50 converts the demodulated demodulation after making the connection position data and the current temperature data of the heat sensing cable 10 and the call connection (S15) with the control computer 90 according to the preset call connection number in the memory. The heat sensing position and temperature data are modulated and amplified through the transmission means 70 to transmit the heat sensing related data to the control computer 90 through a wired or wireless network (S16).

Subsequently, the control computer 90 collects and stores various data from the plurality of heat sensing cables 10 (S17), and compares the collected heat sensing-related data with the alarm data for temperature set in advance in the memory (S18). .

In the comparison, the alarm state of the facility may be classified in various degrees according to the detected temperature (S19), wherein the general alarm belonging to the first alarm, the emergency alarm belonging to the second alarm, and the fire alarm belonging to the third alarm And so on.

That is, for example, the primary alarm generates an alarm signal with a blue flashing light and a long alarm sound, the secondary alarm generates an alarm signal with a yellow flashing light and a normal length alarm sound, and the third alarm generates a red flashing light and a short alarm. It generates a warning signal negatively so that it is easy to know the urgency of the event both visually and audibly.

According to the heat detection analysis of the control computer 90, the normal alarm, the emergency alarm and the fire alarm can be distinguished from each other in a visually and audible alarm, and the position of the heat sensing cable 10 on the monitor, the current temperature and emergency After displaying the situation (S20) by calling to the administrator using the wireless communication means 95, to convey the emergency of the situation (S21).

On the other hand, the control computer 90 collects and analyzes various data transmitted from the heat sensing cable 10, when there is no detection signal or no change in electromotive force of the heat sensing cable 10, the heat sensing cable 10 It may be judged that the damaged cable is damaged, and the self-diagnosis alarm may be generated while indicating the location of the damaged cable.

The main functions of the remote thermal sensing system of the present invention operated as described above are as follows.

1) Heat detection function

It can automatically monitor and monitor the overheating condition and fire occurrence of each facility, and can detect and view the normal operation and temperature change by each part and section of the heat sensing cable, and immediately see the heat or operation state detected in the facility, It is sent to the control computer to provide the time of replacement or generate an alarm signal.

2) Data storage and retrieval function

The control computer can store and retrieve the heat generated by the facility in every minute, hourly, daily, weekly, monthly and yearly data, and the stored temperature data can identify the deterioration and bad condition of the facility and provide the data of the conversion point. It informs the optimal replacement time of the equipment so that the facility can be maintained and maintained in the best condition.

3) Alarm indication function

The indication of the alarm generates a visual audible function alarm and can be automatically notified to the emergency network in case of an emergency, and various alarm stages such as primary alarm (normal alarm) and secondary alarm (emergency alarm) according to temperature change It can be divided into 3rd alarm (fire alarm), system alarm (self-diagnosis alarm), etc. The generated alarm displays the situation occurrence area, point and temperature on the computer monitor, and sends alarm signal to the administrator through wireless communication. Sent.

4) Remote sensing function

It is possible to monitor a large number of plant facilities at the control computer collectively using communication lines, and to remotely monitor and control the state of heat change during operation of various facilities, so that it is possible to check the facilities at any time regardless of short distance and long distance. Minimizes management personnel, reducing management costs and increasing work efficiency.

5) Self diagnosis function

If the thermal sensing cable installed in the facility is damaged by mechanical shock (disruption, skin damage, etc.), the administrator will be alerted and the self-diagnosis alarm will automatically return to self-diagnosis mode after the cause is corrected.

The remote thermal monitoring system according to the present invention has the above functions, and since the normal temperature is different according to the function of each facility, it is possible to determine whether the heat sensing temperature is abnormal by using the key input unit of the processing control unit 50. It is possible to set the reference temperature arbitrarily.

Therefore, in the present design, the thermal sensing cable is contacted with facilities that may cause a fire accident due to heat generation of various power plants, heavy industry plants, transformers, power transmission systems, boilers, motors, pumps, underground tunnels, and contact parts of various electrical panels. By wiring in this way, it is not only possible to detect the overheating condition of a facility and whether it is a fire occurrence in detail, but also to detect and alarm each stage according to the degree of overheating and to deal with the situation appropriately. Can be prevented.

In addition, by collecting and storing the normal and overheated condition of the facility by hour, day, month, and year, it is possible to periodically search for and check the abnormality and deterioration status by facility, so that the facility can be repaired and replaced at an appropriate time. The fire damage can be prevented.

Claims (3)

A linear heat sensing cable contacting the facility and sensing heat generated by the facility; A voltage / current converter configured to convert the electromotive force generated by the heat sensing of the heat sensing cable into a current signal; It receives the current signal output from the voltage / current converter and converts it into a digital signal corresponding thereto, and compares the input current data with temperature data set in advance in the memory to determine the current temperature state of the facility, and then converts the current into temperature. A processing control unit converting the data; Modulation and demodulation means for amplifying and modulating data corresponding to a unique number of a heat sensing cable output from the processing control unit, a current temperature of a heat source, an overheating state, and a degree of fire, and transmitting the wires or wirelessly; And The control computer is connected to the modulation and demodulation transmission means by a wired or wireless network, collects heat sensing data transmitted from the modulation and demodulation transmission means, and analyzes the collected temperature data to alarm or display step by step according to the state of overheating or fire of the facility. Remote heat monitoring system. The method of claim 1, The heat sensing cable, Remote thermal monitoring system, characterized in that there is no input voltage, the cable using the thermocouple characteristics. The method of claim 1, The control computer, Remote call monitoring system, characterized in that it further comprises a wireless call means for calling the administrator wirelessly when the collected temperature data is urgent information.