KR101249463B1 - Detecting Device for Temperature of Terminal - Google Patents

Abstract

The present invention relates to a temperature sensing device for a terminal block, and more particularly to a temperature sensing device capable of detecting a heat generation problem of a terminal block in advance.
The temperature sensing device according to the present invention includes a terminal block connected to a circuit breaker; A temperature sensing unit connected to the terminal block and configured to detect a temperature change of the terminal block; A calculation processing unit calculating a temperature of the terminal block based on the signal detected by the temperature sensing unit; And a display unit for displaying the temperature of the terminal block to the user according to the result of the calculation processing unit, wherein the temperature sensing unit is connected one-to-one with the terminal block, and the calculation processing unit calculates the temperature of each terminal block.

Description

Detecting Device for Temperature of Terminal

The present invention relates to a temperature sensing device of a terminal block, and more particularly, to a temperature sensing device capable of detecting heat generated by an increase in contact resistance of an electrical device and a connecting terminal block.

In general, the surface of the metal is finely curved. Because of this, even in precision machined conductors, the front faces do not touch when they are in contact with each other, but the protrusions on the surface of the conductor make point contacts, and current flows through these point contacts.

Therefore, in general, when constructing a terminal block (terminal connection part), mechanical contact is applied to these contact portions to cause elastic deformation or plastic deformation at the contact interface to obtain a certain contact area. This contact area is called an intrinsic contact area. Current flows through this intrinsic contact area, where a contact resistance occurs. And heat is generated by contact resistance at the time of energization. Therefore, as the contact resistance increases, the heating problem becomes worse. In the terminal block, such contact resistance is increased due to the loosening of the fixing means such as bolts, and heat generation due to the increase in the contact resistance generally occurs continuously, which may cause a fire.

The increase in contact resistance of the terminal block is not easy to grasp, and the method of shutting off the power due to the increase in contact resistance is inevitable.

Accordingly, the present invention has been made to solve the above-described problems, the temperature sensing device for connecting with the electrical device to easily identify the heat generation problem of the terminal block due to the increased contact resistance, and to be able to cope before an emergency situation The purpose is to provide.

In order to solve the above problems, the temperature sensing device according to the present invention includes a terminal block connected to a breaker or the like; A temperature sensing unit connected to the terminal block and configured to detect a temperature change of the terminal block; A calculation processing unit calculating a temperature of the terminal block based on the signal detected by the temperature sensing unit; And a display unit for displaying the temperature of the terminal block to the user according to the result of the calculation processing unit, wherein the temperature sensing unit is connected to the terminal block one-to-one, and the calculation processing unit calculates the temperature of the terminal block.

The temperature sensing unit is a rig for electrically connecting with the terminal block; Temperature sensors inherent to the rig; And an insulation part formed between the rig and the temperature sensor to insulate the rig and the temperature sensor.

Insulation part non-woven fabric surrounding the temperature sensor; And an insulating resin surrounding the nonwoven fabric.

The insulating resin may include at least one of teflon or epoxy.

Through the temperature sensing unit according to the present invention, it is possible to easily grasp the temperature change of the terminal block, and accordingly, it may be possible to take proactive measures before causing a problem due to the temperature increase before the limit temperature.

1 is a block diagram showing the configuration of a temperature sensing device according to the present invention.
2 is a perspective view illustrating an embodiment of a temperature sensing unit.
3 is a cross-sectional view illustrating a connection between a temperature sensing unit and a terminal block.
Figure 4 is a block diagram showing the configuration of a temperature sensing device according to another embodiment of the present invention.

DETAILED DESCRIPTION Hereinafter, embodiments of the present invention in which the above object can be specifically realized are described with reference to the accompanying drawings. In describing the embodiments, the same names and symbols are used for the same components, and additional description thereof will be omitted below.

1 is a block diagram showing the configuration of a temperature sensing device according to the present invention. The temperature sensing device is electrically connected to a breaker (not shown) and the like, and is for sensing a temperature of a connection terminal when the breaker is connected to the breaker.

Referring to FIG. 1, the temperature sensing device according to the present invention includes a calculation processor 300 that calculates a temperature of the terminal block 100 based on the signals of the terminal block 100, the temperature sensor 200, and the temperature sensor 200. And a display unit 400 for displaying the temperature to the user.

The terminal block 100 may be a means for electrically connecting a breaker or the like.

The temperature sensing unit 200 is for sensing the temperature of the terminal block 100 and may be a connection device incorporating a temperature sensor. The temperature sensor may use an element whose resistance value changes with temperature, and details thereof will be described later. The temperature sensing unit 200 may be connected to a load (not shown) while being electrically connected to the breaker (). In this case, a plurality of temperature sensing units 200 are formed corresponding to the quantity of the terminal blocks 100, and each temperature sensing unit 200 is individually connected to the terminal blocks 100. For example, in the case of a three-phase circuit breaker, when four terminal blocks including N phases are required, the temperature sensing unit 200 is composed of four, and each temperature sensing unit 200 is a first to fourth temperature sensors. It may be formed to include the sensors (211,212,213,214), respectively. Accordingly, each temperature sensor may be individually connected to each of the phases R, S, T, and N of the breaker.

The calculation processor 300 calculates the temperature of the terminal block 100 based on the signal detected by the temperature sensor 200. That is, the calculation processor 300 may detect a voltage value that is changed due to a resistance value of the temperature sensor 200 that changes with temperature, and calculate the temperature of the temperature sensor 200 based on this. .

The display unit 400 displays the temperature of the terminal block 100 to the user according to the result of the calculation processing unit. The display unit 400 displays the numerical value of the temperature of the terminal block 100 calculated by the operation processor 300 using a light emitting diode (LED), a liquid crystal display (LCD), or the like. can do. In this case, the display unit 400 may be connected to correspond to the operation processing unit 300 in a 1: 1 correspondence. Accordingly, the temperatures of the terminals connected to the respective phases R, S, T, and N may be displayed. Alternatively, the display unit 400 may display a temperature of only a terminal block close to a specific terminal block, for example, a limit temperature among the terminal blocks 100, or may display the temperature of the terminal block 100 by a user's selection on one display window.

2 and 3 is a view showing an embodiment of the temperature sensing unit according to the present invention, Figure 2 is a perspective view of the temperature sensing unit, Figure 3 is a cross-sectional view showing the connection of the temperature sensing unit and the terminal block.

2 and 3, the temperature sensing unit 200 may be a connection device for electrically connecting the terminal block 100 and may include a temperature sensor 210. In addition, an insulation unit 220 may be formed between the temperature sensor 210 and the rig 230.

The rig 230 for electrically coupling with the terminal block 100 may include a connecting ring 234 and a cylindrical body 232. The body 232 may be implemented in a cylindrical shape having a space to include the temperature sensor 210 therein. The temperature sensor 210 is mounted inside the body 232 of the temperature sensing unit 200, and an insulation unit 220 for insulation is interposed between the temperature sensor 210 and the body 232, which is a conductor. The insulation unit () may be composed of a nonwoven fabric 222 surrounding the temperature sensor 210 and an insulation resin 224 interposed between the nonwoven fabric 222 and the body 232. The insulating resin 224 may be formed using Teflon, epoxy, or the like.

As the temperature sensor 210, a contact type temperature sensor may be used. The contact temperature sensor may use a thermistor, which is a device in which a resistance value of a material changes with temperature. The thermistor may be any one of a negative characteristic (NTC) thermistor whose resistance decreases as the temperature increases and a positive characteristic (PTC) thermistor whose resistance increases as the temperature increases.

According to the temperature sensing device according to the present invention, it is possible to detect in advance that a failure occurs due to heat generation due to an increase in contact resistance in the terminal block connected to the electrical device.

4 is a view showing a temperature sensing apparatus according to another embodiment.

Referring to FIG. 4, the temperature sensing device according to another embodiment of the present invention includes an operation processor 300 that calculates a voltage due to a change in resistance of the terminal block 100, the temperature sensor 200, and the temperature sensor 200. ) Of the terminal block 100 according to the result of the comparison unit 700 and the comparison unit 700 comparing the change of the voltage value of the reference voltage generator 500 and the operation processor 300 with the reference voltage. A display unit 400 for displaying a temperature range is provided. Hereinafter, detailed descriptions of components that are the same as or similar to those of the above-described embodiment will be omitted.

The terminal block 100 may be a connection device connected to a circuit breaker.

The temperature sensing unit 200 is for sensing the temperature of the terminal block 100 and may be a connection device incorporating a temperature sensor. The temperature sensor may use a thermistor whose resistance value changes with temperature, and may be configured to measure the change in the voltage value according to the change in the resistance value.

The calculation processing unit 300 calculates that the voltage value changes according to the change in the resistance value of the temperature sensing unit 200. That is, the voltage value by the temperature value of the temperature sensor 200 can be measured.

The reference voltage generator 500 generates a reference voltage corresponding to the limit temperature. The limit temperature means a temperature that may cause a heat generation problem due to an increase in contact resistance in the terminal block 100. The temperature sensing unit 200 is for detecting a voltage value that is changed due to a change in resistance value according to the temperature change of the terminal block 100, and accordingly, the temperature according to the voltage value is digitized. In other words, the reference voltage generator 500 may generate a voltage value corresponding to the limit temperature by using the voltage value according to the temperature. And the change of the voltage value by this temperature can vary depending on the temperature sensor element.

The comparator 700 compares the voltage value of the temperature sensor 200 calculated by the calculation processor 300 with the reference voltage generated by the reference voltage generator 500. The comparator 700 determines the compared voltage value and transmits a specific signal to the display unit 400 when the temperature of the temperature sensor 200 is higher than the temperature at which the reference voltage is set. Comparing the temperature by comparing the voltage value of the temperature sensing unit 200 with the reference voltage may vary according to the type of the temperature sensor of the temperature sensing unit 200. For example, if the temperature sensor is a device in which the resistance value increases as the temperature increases, it may be determined that the temperature is higher than the reference temperature when the voltage value of the temperature sensing unit 200 is higher than the reference voltage. On the other hand, if the temperature sensor is a device whose resistance value decreases as the temperature increases, it may be determined that the temperature is higher than the reference temperature when the voltage value of the temperature sensing unit 200 is lower than the reference voltage.

The controller 600 may set the reference voltage generated by the reference voltage generator 500 and control the display unit 410 based on the reference voltage. That is, the controller 600 may set a voltage value by the resistance of the temperature sensing unit 200 corresponding to the temperature of the terminal block that may cause a problem due to the contact resistance. In this way, the reference temperature set by the controller 600 may be divided into several steps. For example, the controller 600 may set the reference temperature in four steps of 80, 90, 100, and 120 (° C).

The display unit 400 displays a result of comparing the voltage value of the temperature sensing unit 200 and the reference voltage value compared by the comparator 700. That is, the temperature of the terminal block 100 may be compared with the reference temperature by comparing the temperature of the terminal block 100 with the reference temperature. The display unit 400 may be implemented using an LED. LEDs can vary the color of emission over a range of temperatures to represent temperature levels of danger. For example, the display unit 400 may be implemented with a plurality of LEDs, and each LED may emit light depending on the temperature of the terminal block 100. When the LEDs are implemented as the first to third LEDs, the first LED indicates when the terminal block 100 operates within a normal temperature range, and the second LED is close to a reference temperature at which the terminal block 100 is a limit temperature. Can be set to emit light.

In addition, when the terminal block 100 exceeds the limit temperature, the third LED may be set to emit light.

It is to be understood by those skilled in the art that the present invention may be embodied in many other forms without departing from the spirit and scope of the invention,

Accordingly, the above-described embodiments are to be considered illustrative and not restrictive, and all embodiments within the scope of the appended claims and their equivalents are intended to be included within the scope of the present invention.

100: terminal block 200: temperature sensing unit
300: arithmetic processing unit 400: display unit
500: reference voltage generation unit 600: control unit
220: insulation 230: league

Claims (5)

A terminal block connected to a breaker;
A temperature sensing unit connected to the terminal block and configured to detect a temperature change of the terminal block;
A calculation processing unit calculating a temperature of the terminal block based on the signal detected by the temperature sensing unit; And
And a display unit for displaying the temperature of the terminal block to the user according to the result of the calculation processing unit.
The temperature sensing unit is connected to the terminal block in a one-to-one, the temperature processing unit, characterized in that for calculating the temperature of each terminal block.
The method of claim 1,
The temperature sensing unit
A rig electrically connected to the terminal block;
A temperature sensor inherent in the rig; And
And an insulation part formed between the rig and the temperature sensor to insulate the rig and the temperature sensor.
The method of claim 2,
The insulating portion
Non-woven fabric surrounding the temperature sensor; And
Insulation resin surrounding the non-woven fabric; temperature sensing device comprising a.
The method of claim 3, wherein
The insulating resin is a temperature sensing device, characterized in that at least one of Teflon or epoxy.
,

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