KR100921673B1 - Temperature detection device of bus duct system - Google Patents

Abstract

PURPOSE: A temperature detection device of a bus duct system is provided to allow a user to prepare a fire in advance and to control the device in remote by detecting the temperature of the bus duct system in real time. CONSTITUTION: A temperature detection device of a bus duct system is composed of the top(11), the bottom(13), and the side(15) of a duct, a plurality of bus bar, a connection unit(10a), and a temperature alarm system(200). The top and the bottom of the duct are faced with each other by a certain space and the side of the duct is between them vertically. The busbar is installed at a space which is formed by the top, the bottom, and side of the duct. The connection unit is protruded to the both end of the busbar so that it is connected to the bus duct(10).

Description

Temperature detection device of bus duct system

The present invention relates to a booth duct system, and more particularly, to a temperature detection device of a booth duct system capable of detecting and sending a temperature in real time.

In general, a bus duct is a duct used to supply a large amount of power used in a factory or a building. Inside the booth duct, busbars made of conductors are installed.

In the past, it was common to use electric wire cable as a power wiring method, but booths equipped with a bus bar inside a wiring method such as a high-rise building or a large factory due to an increase in power to be delivered and a change in the power installation structure. Wiring system by duct is adopted. In other words, a method of connecting and wiring a plurality of booth ducts of a predetermined length is adopted.

Compared with booth ducts and cables, booth ducts can deliver a lot of power to conductors of the same volume, protect the conductors and insulators as metal ducts, expand and relocate, and handle accidents in the event of an accident. And it has the advantage of easy management of the system.

1 is a partial perspective view showing a connection portion of a booth duct system composed of a booth duct for power wiring according to the prior art, and FIG. 2 is a booth duct 110 constituting the booth duct system 100 shown in FIG. 1. A partially omitted perspective view is shown.

1 and 2, the booth duct 110 constituting the booth duct system 100 according to the prior art has a body portion 113 with a bus bar for delivering power, and the body portion 113 It is formed of both ends are connected to the connecting portion (110a, 110b) connected to the neighboring booth duct, the connecting portion (110a, 110b) may be formed of a female connecting portion (110a) and a male connecting portion (110b) in order to be firmly connected to each other. do.

Meanwhile, in FIG. 1, reference numeral 115 denotes a bolt for forming the body portion 113, and 117 illustrates a reinforcing bolt installed through the body portion 113.

However, the booth duct system according to the prior art configured as described above does not have a means for monitoring the temperature and thus cannot prepare for the booth duct system, in particular, the fire caused by the temperature rise and the temperature rise of the booth duct connecting part constituting the booth duct system. There was a problem, and there was a problem that it was not easy to install a means for monitoring the temperature in preparation for a fire.

An object of the present invention is to provide a temperature detection apparatus for a booth duct system that is prepared for fire and the like by detecting the temperature of a booth duct connection part in real time.

The temperature detection device of the booth duct system according to the present invention for achieving the above object has a predetermined space and the upper and lower ducts disposed corresponding to each other, and the side duct vertically installed between the upper and lower ducts And a plurality of busbars installed in the space formed by the upper and lower ducts and the side ducts, and connecting portions for protruding and extending to both ends of the busbars so as to be connected to neighboring booth ducts. It is configured to include a temperature alarm system which is installed in the connection unit and detects the temperature in real time and transmits the position of the bus bar to the outside in accordance with the detected information, wherein the temperature alarm system is installed in the bus bar or the connection unit One that senses the temperature at the point and has a unique address for each sensor Reads the temperature sensor and the temperature detected by the temperature sensor and displays it to the user, and the detected temperature is out of the temperature range preset by the user or the rate of temperature rise exceeds the temperature set by the user. And a thermal contact alarm for generating an alarm, wherein the thermal contact alarm sets a sensor communication control unit for controlling data transmission and reception between the temperature sensor and the alarm, and a user sets a temperature range or temperature increase rate at which the alarm is generated. And a control unit for inputting or deleting a unique address of each of the temperature sensors, a data storage unit for storing the user's set value and the unique address of each of the temperature sensors, a set value input from the control unit, and the temperature detection unit. The temperature value detected by the sensor is displayed on the display means. Supplying power to the display unit, an alarm unit for generating an alarm when the detected temperature is out of the set temperature range or the temperature increase rate exceeds the set temperature increase rate, a central processing unit for integrating and controlling the respective components. Characterized in that comprises a power supply.

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The temperature detection device of the booth duct system according to the present invention has the following effects.

That is, by detecting and sending the temperature of the booth duct connection in real time, it is possible to remotely control and to prepare for a fire and the like.

Hereinafter, with reference to the accompanying drawings will be described in more detail the temperature detection device of the booth duct system according to the present invention.

3 is a partially omitted perspective view showing a booth duct forming a temperature detection device of the booth duct system according to the present invention.

As shown in FIG. 3, the booth duct 10 constituting the booth duct system 1 according to the present invention includes an upper surface duct 11 and a lower surface duct 13 which are disposed to face each other with a predetermined space, and the upper surface duct 11. And a side duct 15 installed vertically between the bottom surface duct 13 and the power supply to the inner space formed by the top surface duct 11 and the bottom surface duct 13 and the side duct 15. It is comprised including the busbar 17 which is a conductor.

Here, it is preferable that the bus bar 17 is firmly fixed to the side duct 15 by the reinforcing bolt 19 installed to be spaced apart at predetermined intervals through the side duct 15.

In order to allow the booth duct 10 to be connected to the neighboring booth duct 10, the bus bar 17 protrudes to both ends to form a connection portion 10a.

The connection part 10a and the bus bar 17 are fixedly provided with the temperature alarm system 200 which detects and transmits the temperature of the bus bar 17 and the connection part 10a in real time.

Meanwhile, in the embodiment of the present invention, although the temperature alarm system 200 is attached to or inserted into the duct of one side of the busbar 17, the present invention is not limited thereto, and may be attached to the busbar connecting portion 10a. have.

Therefore, the present invention detects the temperature of the busbar 17 or the connecting portion 10a in real time using the temperature alarm system 200, and controls the cooling fan and power factor control through remote control based on the detected result. Can be carried out.

The temperature alarm system 200 is composed of a plurality of magic sensors are connected by 1-wire, the magic sensor is a device for detecting the temperature by detecting the temperature of the attachment portion, and notify the alarm when abnormal overheat occurs.

In this case, the 1-Wire communication method is characterized in that the parallel communication method and the DC power supply to the communication line to bring the data quickly to 115200bps, there is a feature that does not require a separate power supply to the temperature alarm system 200.

In addition, the family code (family code) of the temperature alarm system 200 is MAC coded to manage the family code as an ID.

In addition, the temperature detected by the temperature alarm system 200 may be transmitted to the outside through a thermal contact alarm (not shown).

The characteristic of the temperature alarm system 200 is to read the data of the thermal contact sensor and compatible with the temperature data management, since the thermal contact sensor does not require a separate power supply because it is a sensor that communicates with only two cables It can be installed efficiently, and it is possible to output the buzzer and alarm contact when the temperature measured by the thermal contact sensor is measured above the alarm set value (video, minus).

In addition, there is a function to automatically cancel the alarm when the temperature is restored normally and to maintain the alarm even if the temperature is restored normally, the alarm can be released during the alarm, the specification of the magic sensor is 0.1 ℃ / ID built-in type.

For example, when the limit temperature value of the bus bar 17 is generally 65 ° C, the first warning temperature according to the temperature rise may be set to 60 ° C and the second warning temperature may be set to 72 ° C. In this case, when the temperature of the bus bar 17 reaches these primary and secondary warning temperatures, the buzzer and the alarm contact point are output.

In addition, the temperature alarm system 200 detects and transmits the temperature of the busbar 17 connection portion, the busbar peak temperature, and the busbar ambient temperature, respectively.

The temperature alarm system 200 is installed at the connection portion 10a of the busbar that is the object of temperature sensing, senses the temperature of the installed point, and assigns a unique address to each sensor.

The temperature alarm system 200 has a structure for transmitting and sensing the temperature by the built-in semiconductor temperature sensor and processor, and is small and light size of about 50g and can be directly attached to a heating part such as a bus bar through which current flows. Very easy.

In addition, since it can operate with weak current, it can operate with voltage generated by diode and capacitor installed in communication line, so it doesn't need separate power supply, and only two cables (2C RS485 Shield Cable) Up to 1000 can be installed in parallel per converter.

And since communication is performed at low voltage level of 5V, it can transmit the detected temperature up to 300meters through the line. The data communication speed is 115200bps, and the temperature can be measured within the range of -55 ~ 125 ℃.

The alarm receives and displays the temperature of the busbar connection part from the temperature alarm system 200, and if the temperature is out of the temperature range preset by the user or if the temperature rises rapidly within a predetermined time, the alarm determines that it is abnormal overheating and generates an alarm. As a device, it is possible to manage temperature data with server which is remote by the compatibility with MODBUS communication protocol of RS485 communication.

One temperature alarm system 200 can be connected to one alarm, and the alarm has a flat panel mounting weight of about 800g.

4 is a configuration diagram schematically showing the temperature alarm system of FIG.

As shown in FIG. 4, the temperature alarm system 200 is installed in a bus bar or a connection unit that is subjected to temperature sensing, and includes a temperature sensor 310 for sensing a temperature, a sensor communication control unit 320, and a central processing unit 330. ), A data storage unit 340, a battery 350, an operation unit 360, a display unit 370, a remote server 380, a server communication control unit 381, an alarm unit 390, and a power supply unit 351. Part.

Looking at the operation of the temperature detection of the bus bar or the connection of the present invention, first, the user inputs the upper limit value and the lower limit value or the rate of increase of the temperature to be the reference value that can be determined as abnormal overheating through the operation unit 360. The input is made by a user pressing a button provided in the alarm, and the input data is simultaneously displayed on the display unit 370 for the user to check. The setting value input by the user is stored in the data storage unit 340 by the central processing unit.

The data storage unit 340 stores an address unique to each temperature sensor in addition to the set value, thereby storing the user input value for each temperature sensor.

The data storage unit 340 is composed of SRAM and is operated by a data storage battery.

The sensor communication control unit 320 receives the temperature of the heat generating part of the bus bar or the connecting unit transmitted by the temperature sensor 310 through the sensor communication circuit and transmits the temperature to the alarm. The transmitted temperature value is displayed on the display unit, and the central processing unit 330 checks the address of the temperature sensor 310 that has transmitted data, and then reads data set in the corresponding temperature sensor 310 from the data storage unit 340. Compare it with the temperature value you received. At this time, if it is determined that the received temperature value is abnormal overheating because it is outside the set value range, the central processing unit 330 issues an alarm command to the alarm unit 390.

The alarm unit 390 generates an alarm by a lamp or a buzzer according to the command of the central processing unit 330. In this embodiment, the alarm means is actuated by a buzzer or a relay with alarm contact output.

The temperature setting value of the user displayed on the display unit 370 and the temperature data of the bus bar or the connection unit measured by the temperature sensor 310 are sent to the server 380 remotely installed by the server communication control unit 320 and installed on the server. It can be displayed on the screen by the interface. In this embodiment, the alarm and the remote server transmits and receives data by RS-485, but various communication methods such as RS-232, CDMA, TCP / IP, UDP, FTP, and the like may be used.

The voltage required to operate the alarm is supplied by the power supply unit 351, and the power supply unit is a switching mode power supply (SMPS).

FIG. 5 is a circuit diagram schematically illustrating the temperature alarm system of FIG. 3.

As shown in FIG. 5, the temperature alarm system 200 is a device for remotely monitoring and diagnosing temperature data transmitted from each temperature sensor and generating an alarm when an abnormal condition occurs. The temperature sensor input unit 331 and MCU 332, the display unit 333, the operation unit 334, the communication converter 335, the auxiliary storage unit 336, the contact driver 337, and the power supply unit 338.

The temperature sensor input unit 331 is a circuit for inputting the temperature data sensed by the temperature sensor through the communication line 320, and is composed of a circuit for converting a 1-wire communication level to a DC5V TTL level.

The MCU 332 reads temperature data input through the temperature sensor input unit 331 to manage data, display, communication, and alarm functions.

The display unit 333 displays temperature and overheating, the operation unit 334 performs a task through manipulation of a keypad, and the communication conversion unit 335 outputs through the MCU 332. The temperature data is transmitted to the outside.

The auxiliary storage unit 336 stores a family code, various set values and data of the temperature sensor. On the other hand, since the power supply of the auxiliary storage unit 336 is supplied to the battery (battery), the data does not volatilize even during storage or power failure.

The contact driver 337 configures a buzzer sound and an alarm contact to be used in the alarm by the alarm function performed from the MCU 332, and the power supply 338 supplies power to the entire temperature controller 330. have.

6 is a flowchart illustrating a temperature detection method of a booth duct system according to the present invention.

As shown in FIG. 6, the temperature detection method of the bus duct system according to the present invention detects a temperature flowing through a plurality of bus bars or a connection part connected through a connection part using a plurality of temperature sensors (S110).

Here, the temperature sensor is installed in a plurality of busbars to detect the temperature of each busbar. In other words, if the temperature occurs in any one of the plurality of busbars higher than the preset value, the temperature sensor is attached to each busbar to accurately identify the point where the temperature is detected. It is configured to detect.

Subsequently, the temperature information detected by each of the busbars is converted into a voltage signal (S120). Here, since the detected temperature information has an analog value, the detected temperature information is converted into a digital value.

Subsequently, the temperature information converted into the voltage signal is amplified (S130). Here, since it is difficult to confirm when the temperature information is minute, it is amplified using an amplification circuit or the like.

Next, it is determined whether the temperature information exceeds a prescribed value or less than a prescribed value (S140). Here, the prescribed value is a value determined arbitrarily, and is used as a reference for determining the detected temperature information.

If the detected temperature information is lower than the prescribed value, it means normal operation and continuously detects temperature information flowing through the busbar or the connecting portion.

Subsequently, when the temperature information is higher than a prescribed value, it is transmitted to the outside through communication that an abnormality has occurred (S150). Here, although the transmission to the outside through the communication has been described, it is not limited to this to enable the operator to check the occurrence of the abnormality according to the temperature rise in real time through the alarm sound or signal.

Meanwhile, as described above, it is determined which temperature bar is generated higher than a prescribed value in a bus bar among the plurality of bus bars and transmits the information to a worker (manager) through communication.

In addition, when a point of the busbar having high temperature information is transmitted through the communication, a buzzer such as an alarm sound may be generated to check for an abnormal occurrence due to a temperature rise in real time.

And based on the transmitted temperature information to repair the busbar to the temperature rises remotely or to deliver the point the temperature information is generated to the operator to repair the failure (S160).

The present invention described above is not limited to the above-described embodiments and the accompanying drawings, and various substitutions, modifications, and changes can be made without departing from the technical spirit of the present invention. It will be evident to those who have knowledge of.

1 is a partial perspective view showing a connection portion of a booth duct system composed of a booth duct for power wiring according to the prior art;

2 is a partially omitted perspective view showing a booth duct forming the booth duct system shown in FIG.

Figure 3 is a partially omitted perspective view showing a booth duct forming a booth duct system according to the present invention

4 is a configuration diagram schematically showing the temperature alarm system of FIG.

5 is a configuration diagram schematically showing the temperature alarm system of FIG.

6 is a flow chart schematically showing the temperature detection method of the booth duct system according to the present invention.

Explanation of symbols for the main parts of the drawings

10: booth duct 17: busbar

200: temperature alarm system

Claims (8)

An upper duct and a lower duct having a predetermined space and correspondingly arranged; A side duct vertically installed between the upper duct and the lower duct; A plurality of busbars installed in a space formed by the upper and lower ducts and the side ducts; A connecting portion for protruding and extending to both ends of each of the busbars so as to be connected to a neighboring booth duct; And a temperature alarm system installed in each of the busbars and the connection part to detect the temperature in real time and transmit the location of the busbar in which the abnormality occurred according to the detected information to the outside. The temperature alarm system detects the temperature of each point installed in the bus bar or the connection unit, and reads one or more temperature sensors and a temperature detected by the temperature sensor, each of which has a unique address. And a thermal contact alarm that displays and generates an alarm when the detected temperature is out of a preset temperature range by the user or when the temperature rise rate exceeds a preset temperature rise rate by the user. The thermal contact alarm is a sensor communication control unit for controlling data transmission and reception between the temperature sensor and the alarm, the user sets the temperature range or temperature rise rate which is the basis of the alarm generation and inputs a unique address of each temperature sensor An operation unit for deleting the data, a data storage unit for storing the user's set value and a unique address of each temperature sensor, a set value input from the operation unit, and a temperature value detected by the temperature sensor on the display means Supplying power to the display unit, an alarm unit for generating an alarm when the detected temperature is out of the set temperature range or the temperature increase rate exceeds the set temperature increase rate, a central processing unit for integrating and controlling the respective components. That includes a power supply to The temperature detection device of the booth duct system characterized in that. delete The apparatus of claim 1, wherein the temperature alarm system is a magic sensor that senses a temperature of an attachment part and detects a temperature and notifies an alarm when an abnormal overheat occurs. delete delete delete The booth duct system according to claim 1, further comprising a remote server for displaying data identical to the data displayed on the display unit, and a server communication control unit for controlling data transmission and reception between the alarm and the remote server. Temperature detection device. delete

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