KR100562567B1 - Preventing Thermal Runway Of Under Ground Electric Power Link System And Control Method Thereof - Google Patents

Abstract

The present invention relates to a underground power transmission and distribution power thermal runaway prevention system and a control method thereof, in particular, by installing a distribution temperature measuring sensor in the longitudinal direction in the power transmission and distribution link embedded in the soil to measure the temperature generated in the power transmission and distribution link The temperature data measured by the distribution temperature measuring device and the current generated from the power transmission and distribution link are measured by current measuring means and sent to the passion water calculating device. When the temperature exceeds the reference temperature or the heat resistance current of the soil is higher than the reference value, an alarm is generated and the current It is a very useful and effective invention to reduce the amount of current supplied in a transportation device to prevent thermal runaway of a power transmission and distribution link.

 In addition, when there is a serious thermal change in the surrounding soil, there is an advantage that it is possible to easily grasp the location and take economic measures in the location.

In addition, by calculating the database of the thermal resistivity of the surrounding soil in advance, it is helpful to the underground power transmission and distribution link research and has the advantage of helping to install and manage later.

Power Cable Integral Insulation Buckle Insert Bolts Flashover Characteristics

Description

Preventing Thermal Runway Of Under Ground Electric Power Link System And Control Method Thereof}             

1 is a view showing the configuration of the underground power transmission and distribution link thermal runaway prevention system according to an embodiment of the present invention,

2 is a view showing the configuration of the underground power transmission and distribution link thermal runaway prevention system according to another embodiment of the present invention,

3 is a view showing the configuration of the underground power transmission and distribution link thermal runaway prevention system according to another embodiment of the present invention,

4 is a flowchart illustrating a control method of the underground power transmission and distribution link thermal runaway prevention system according to the present invention.

* Description of the symbols for the main parts of the drawings *

10,110 soil 12,112 underground power transmission and distribution link

14,114: distribution temperature measuring sensor 16,116: current acquisition means

18,118: Distribution temperature measuring device 20,120: Passionate calculating device

122: current control device

The present invention relates to a power transmission and distribution link, in particular, by installing a distribution temperature measuring sensor in the longitudinal direction in the underground power transmission and distribution link to measure the temperature generated in the power transmission and distribution link and the temperature data measured in the distribution temperature measuring apparatus The current generated from the power transmission and distribution link is measured by current measuring means and sent to the passion water calculating device. When the temperature exceeds the reference temperature or the heat resistance current of the soil is higher than the reference value, an alarm is generated to reduce the amount of current supplied by the current transport device. An underground power transmission and distribution thermal runaway prevention system for preventing thermal runaway of a transmission and distribution link.

In general, thermal runaway of a transmission / distribution link, when heat generated mainly by electric current flowing through the link itself, raises the temperature of the soil in which the link is installed, and this temperature increase continuously occurs, the moisture migration of the soil (Moisture Migration) It is caused by the positive feedback (Positive Feedback) to increase the temperature of the link again by the rapid thermal resistance of the soil.

In the case of the conventional US patent registration No. US4097682, by applying a backfill material containing a plurality of polymer granules containing water in the soil in which the transmission wiring link is installed, it inhibits the phenomenon of moisture migration to the transmission wiring link. Invention is proposed.

In the case of US Pat. No. 4,441,027, the invention is proposed to suppress moisture migration by decaying soil and wax components as backfill material.

However, as described above, the conventional inventions expect the performance of the invention to function for 30 years, which is the life span of the power transport link, but if the power transport link fails to function, There is a problem that leads to a fatal power interruption because there is no device that can detect the danger.

In particular, when it is long and difficult to access, such as underground power transport links, it is impossible to provide information on the location or time at which moisture migration occurs. Syndrome has a problem that causes serious accidents.

The present invention has been made in view of this point, by installing the distribution temperature measuring sensor in the longitudinal direction in the underground power transmission and distribution link to measure the temperature generated in the power transmission and distribution link and the temperature data measured by the distribution temperature measuring device The current generated from the power transmission and distribution link is measured by current measuring means and sent to the passion water calculating device. When the temperature exceeds the reference temperature or the heat resistance current of the soil is higher than the reference value, an alarm is generated to reduce the amount of current supplied by the current transport device. The purpose is to prevent thermal runaway of transmission and distribution links.

This object includes: a distribution temperature measuring sensor configured to measure a distributed temperature of the underground power transmission and distribution link installed in the ground in a longitudinal direction; A distribution temperature measuring device configured to obtain temperature information in a longitudinal direction from temperature information of the distribution temperature measuring sensor; Current acquiring means for acquiring a current flowing through the underground power transmission and distribution link; Alarm is generated when the distribution temperature around the underground power transmission and distribution link is higher than the reference value or the thermal resistivity of the soil is higher than the reference value by thermal analysis from the distribution temperature measured by the distribution temperature measuring device and the current data acquired by the current acquiring means. Is achieved by providing an underground power transmission and distribution thermal runaway prevention system, including a passion water estimator.

The distributed temperature measuring sensor includes: a first distributed temperature measuring sensor installed in a longitudinal direction parallel to the underground power transmission wiring; It is preferable that the second distribution temperature measuring sensor is installed in the longitudinal direction in parallel with a constant distance with respect to the first distribution temperature measuring sensor.

The distributed temperature measuring sensor may further include: a first surface disposed in a longitudinal direction parallel to the underground power transmission wiring; It is preferable that it is formed of a loop including a second surface which is installed in the longitudinal direction in parallel with a predetermined distance with respect to the underground power transmission wiring.

An object of the present invention is a distribution temperature measuring sensor for embedding a back-filling material in the ground, and measuring the distributed temperature is installed in the longitudinal direction with respect to the underground power transmission and distribution link installed inside the backfilling material; A distribution temperature measuring device configured to obtain temperature information in a longitudinal direction from temperature information of the distribution temperature measuring sensor; Current acquiring means for acquiring a current flowing through the underground power transmission and distribution link; An alarm is generated when the distribution temperature around the underground power transmission and distribution link is higher than the reference value or the thermal resistivity of the soil is higher than the reference value by thermal analysis from the distribution temperature measured by the distribution temperature measuring device and the current data acquired by the current acquiring means. Passion water calculation device to generate; When an alarm occurs in the passion water calculating device, it is achieved by providing an underground power transmission and distribution thermal runaway prevention system consisting of a current control device for reducing the current of the underground power transmission and distribution link.

The distributed temperature measuring sensor includes: a first distributed temperature measuring sensor installed in a longitudinal direction parallel to the underground power transmission wiring; It is preferable that the second distribution temperature measuring sensor is installed in the longitudinal direction in parallel with a constant distance with respect to the first distribution temperature measuring sensor.

An object of the present invention includes a temperature calculating step of acquiring a current flowing in an underground power transmission and distribution link by an acquiring means to calculate a temperature around the underground power transmission and distribution link; A temperature measuring step of measuring a temperature distributed by a distribution temperature measuring sensor installed in a longitudinal direction with respect to the underground power transmission and distribution link installed in the soil after the temperature calculating step; A first judging step of determining whether a temperature measured in the temperature measuring step is equal to or greater than a reference value by using a distribution temperature measuring device; When the temperature measured in the first determination step is less than the reference value passion calculation step of calculating the amount of heat from the outside of the underground power transmission and distribution link and the passion water from the soil around the underground power transmission and distribution link in the passion water calculating device; A second judging step of determining whether or not the passion water value calculated in the calculating step is greater than or equal to the reference value, and returning to an initial state if it is less than or equal to the reference value; An alarm generation step of generating an alarm in the passion water calculating device when the temperature determined in the first and second determination steps is greater than or equal to the reference value and the passion water is greater than or equal to the reference value; When the alarm occurs in the alarm generation step is achieved by providing a underground power transmission and distribution thermal runaway control method comprising a current control step of controlling the current in the underground power transmission and distribution link in the current control device.

EMBODIMENT OF THE INVENTION Hereinafter, the structure of this invention is demonstrated in detail based on an accompanying drawing.

1 is a view showing the configuration of the underground power transmission and distribution link thermal runaway prevention system according to an embodiment of the present invention, Figure 2 is a view showing the configuration of a underground power transmission and distribution link thermal runaway prevention system according to another embodiment of the present invention 3 is a view showing the configuration of the underground power transmission and distribution link thermal runaway prevention system according to another embodiment of the present invention, Figure 4 is a flow chart of the control method of the underground power transmission and distribution link thermal runaway prevention system according to the present invention The figure shown.

The configuration of an embodiment of the present invention, the distribution temperature measuring sensor 14 for measuring the distributed temperature is installed in the longitudinal direction with respect to the underground power transmission and distribution link 12 installed in the underground (10); A distribution temperature measuring device 18 for obtaining temperature information in a longitudinal direction from the temperature information of the distribution temperature measuring sensor 14; Current acquiring means (16) for acquiring a current flowing in the underground power transmission and distribution link (12); From the distribution temperature measured by the distribution temperature measuring device 18 and the current data acquired by the current acquiring means 16, thermal analysis of the underground power transmission / distribution link 12 around the underground power transmission / distribution link 12 is above a reference value or soil ( If the heat resistivity of 10) is more than the reference value is made of a passion water calculating device 20 for generating an alarm. In this case, the underground transmission and distribution link 12 may be directly buried in the soil, it may be installed in the power outlet or pipeline.

And, as shown in another embodiment shown in Figure 2, the distribution temperature measuring sensor 14, the first distribution temperature measuring sensor (installed in the longitudinal direction parallel to the underground power transmission wiring 12 ( 13); It consists of a second distribution temperature measuring sensor 15 which is installed in the longitudinal direction in parallel with a constant distance to the first distribution temperature measuring sensor (13).

The distributed temperature measuring sensor 14 includes: a first surface disposed in a longitudinal direction parallel to the underground power transmission wiring 12; It is formed as a loop including a second surface which is installed in the longitudinal direction in parallel with a predetermined distance to the underground power transmission wiring 12.

And, as shown in Figure 3, according to another embodiment of the present invention, the underground material 110 is embedded in the backfill material 111, underground power installed in the backfill material 111 A distribution temperature measuring sensor 114 installed in the longitudinal direction with respect to the transmission and distribution link 112 and measuring a distributed temperature; A distribution temperature measuring device 118 for obtaining temperature information in a longitudinal direction from temperature information of the distribution temperature measuring sensor 114; Current acquiring means (116) for acquiring a current flowing in the underground power transmission and distribution link (112); The distribution temperature measured by the distribution temperature measuring device 118 and the distribution temperature around the underground power transmission and distribution link 112 by thermal analysis from the current data acquired by the current acquiring means 116 is higher than the reference value or soil. Passion water calculating device 120 for generating an alarm when the thermal resistivity of 110 is greater than or equal to the reference value; When the alarm occurs in the passion water calculating device 120, it comprises a current control device 122 for reducing the current of the underground power transmission and distribution link 112.

The distributed temperature measuring sensor 114 includes: a first distributed temperature measuring sensor 113 installed in a longitudinal direction parallel to the underground power transmission wiring 112; It consists of a second distribution temperature measuring sensor 115 is installed in the longitudinal direction in parallel with a constant distance to the first distribution temperature measuring sensor 113.

The roof power transmission and distribution links 12 and 112 include underground power cables, accessories, transformers, and circuit breakers.

The distributed temperature measuring sensors 14 and 114 are installed using an optical fiber, and a length of about 15 km or less is appropriate. In particular, a multi-mode 50/125 μm (Core / cladding) 10 km is suitable. The optical fiber may use a multimode and a single mode, and considering the accuracy and economy of temperature measurement, it is optimal to use a multi-mode optical fiber for communication.

In addition, the distribution temperature measuring device (18, 118), the distribution temperature measuring sensor (14, 114) by detecting the wavelength of the laser light incident on the distribution temperature measuring sensor (14, 114) and returning Tells every 1m the total length of the installed temperature. Generally, scattered light or Brillouin scattered light is obtained from temperature dependence of reflected light even when pulses of several to several tens of ns width are incident on the distribution temperature measuring sensors 14 and 114.

In addition, the current acquiring means 16 and 116 may generally use a current converter, and may receive a value measured using an optical CT or a communication device.

Using the current measured by the current obtaining means (16) (116) to calculate the amount of heat exiting the link (12) (112) outside the temperature and soil measured from the distribution temperature measuring device (14) (114) The thermal resistivity and heat capacity of the soil 10 and 110 around the links 12 and 112 are calculated through the temperature of the infinite origin of. On the other hand, the temperature of the infinite origin generally follows the international standard IEC.

On the other hand, when calculating the thermal resistivity and heat capacity of the soil (10, 110) around the underground power transmission and distribution link (12, 112), the first distribution temperature measuring sensor 113 of the distribution temperature sensor 114 is linked ( 12) (112), and the second distribution temperature measuring sensor 115 is installed in parallel to the links (12, 112) at the outermost part of the soil (10) 110 to obtain the soil heat constant It is possible to obtain the thermal resistivity and the heat capacity of the soil 10 and 110 from the change of the values of the first sensor 113 and the second sensor 115 and the measured current.

The passion water calculating device 20 or 120 may use an industrial computer, an industrial server computer, a PCL, or the like.

Hereinafter, the operation and effects of the present invention will be described in detail with reference to the accompanying drawings.

Since the embodiment of the present invention shown in Figs. 1 and 3 is almost the same, only the third embodiment shown in Figs. 3 and 4 will be described.

First, the current flowing through the underground power transmission and distribution link 112 is measured by the current measuring means 116 to proceed to the temperature calculation step of calculating the temperature around the underground power transmission and distribution link 112. (S1)

Then, after the temperature calculation step (S1) to proceed with the temperature measuring step of measuring the temperature distributed by the distribution temperature measuring sensor 114 installed in the longitudinal direction with respect to the underground power transmission and distribution link 112 installed in the soil (110). (S2)

At this time, the first distribution temperature measurement sensor 113 installed on the outer circumferential surface of the underground power transmission and distribution device 112 is measured from the side, and the second distribution temperature measurement is installed at a distance away from the underground power transmission and distribution device 112 Each sensor 115 measures temperature.

Then, the first determination step of determining by the distribution temperature measuring device 118 whether the temperature calculated and measured in the temperature calculation and measurement step S1 and S2 is equal to or greater than a reference value is performed.

And, if the temperature calculated and measured in the temperature calculation and measurement step (S1) (S2) is less than the reference value, the heat from the outside of the underground power transmission and distribution link 112 and the soil around the underground power transmission and distribution link 112 ( Passion water coming from the 110) to calculate the passion water to calculate the passion water calculating device 120. (S4) (S5)

Then, the amount of heat escaping from the outside of the links 12 and 112 is calculated using the current measured by the current measuring means 16 and 116 and the temperature measured by the distribution temperature measuring devices 14 and 114. And the thermal resistivity and heat capacity of the soil (10, 110) around the links 12, 112 through the temperature of the infinite origin of the soil. On the other hand, the temperature of the infinite origin generally follows the international standard IEC.

On the other hand, when calculating the thermal resistivity and heat capacity of the soil (10, 110) around the underground power transmission and distribution link (12, 112), the first distribution temperature measuring sensor 113 of the distribution temperature sensor 114 is linked ( 12) (112), and the second distribution temperature measuring sensor 115 is installed in parallel to the links (12, 112) at the outermost part of the soil (10) 110 to obtain the soil heat constant It is possible to obtain the thermal resistivity and the heat capacity of the soil 10 and 110 from the change of the values of the first sensor 113 and the second sensor 115 and the measured current.

In addition, it is determined whether the passion water value calculated in the passion water calculation step (S5) is greater than or equal to the reference value, and if it is less than the reference value, the second determination step of returning to the initial state is performed.

When the temperature determined in the first and second determination steps S3 and S6 is equal to or greater than the reference value and the number of passions is equal to or greater than the reference value, the alarm sound generating step of generating an alarm is performed by the passion water calculating device 120. (S7)

When an alarm is generated in the alarm sound generating step S7, the current control device 122 performs a current control step of controlling the current of the underground power transmission and distribution link 112.

 Therefore, as described above, when using the underground power transmission and distribution power thermal runaway prevention system and the control method according to the present invention, by installing a distribution temperature measuring sensor in the longitudinal direction in the power transmission and distribution link embedded in the ground in the power transmission and distribution link When the generated temperature is measured, the temperature data measured by the distribution temperature measuring device and the current generated by the power transmission / distribution link are measured by current measuring means and sent to the passionate water calculating device, and the temperature or the heat resistance current of the soil is higher than the reference value. It is a very useful and effective invention to prevent the thermal runaway of the power transmission and distribution link by generating a warning, thereby reducing the current supply in the current transport device.

In addition, when there is a serious thermal change in the surrounding soil, there is an advantage that it is possible to easily grasp the location and take economic measures in the location.

In addition, by calculating the database of the thermal resistivity of the surrounding soil in advance, it is helpful to the underground power transmission and distribution link research and has the advantage of helping to install and manage later.

Claims (6)

A distribution temperature sensor installed in the longitudinal direction of the underground power transmission and distribution link installed in the ground and measuring a distributed temperature; A distribution temperature measuring device configured to obtain temperature information in a longitudinal direction from temperature information of the distribution temperature measuring sensor; Current acquiring means for acquiring a current flowing through the underground power transmission and distribution link; Alarm is generated when the distribution temperature around the underground power transmission and distribution link is higher than the reference value or the thermal resistivity of the soil is higher than the reference value by thermal analysis from the distribution temperature measured by the distribution temperature measuring device and the current data acquired by the current acquiring means. Underground power transmission and distribution thermal runaway prevention system, characterized in that it comprises a passion water calculating device. The sensor of claim 1, wherein the distribution temperature measuring sensor comprises: a first distribution temperature measuring sensor installed in a longitudinal direction parallel to the underground power transmission wiring; Underground power transmission and distribution thermal runaway prevention system, characterized in that consisting of a second distribution temperature measuring sensor installed in the longitudinal direction in parallel with a constant distance to the first distribution temperature measuring sensor. The sensor of claim 1, wherein the distributed temperature measuring sensor comprises: a first surface disposed in a longitudinal direction parallel to the underground power transmission wiring; Underground power transmission and distribution thermal runaway prevention system, characterized in that formed in a loop including a second surface is provided in a longitudinal direction in parallel with a predetermined distance to the underground power transmission wiring. A distribution temperature measuring sensor for embedding the backfill material in the ground and measuring the distributed temperature in a longitudinal direction with respect to the underground power transmission and distribution link installed in the backfill material; A distribution temperature measuring device configured to obtain temperature information in a longitudinal direction from temperature information of the distribution temperature measuring sensor; Current acquiring means for acquiring a current flowing through the underground power transmission and distribution link; An alarm is generated when the distribution temperature around the underground power transmission and distribution link is higher than the reference value or the thermal resistivity of the soil is higher than the reference value by thermal analysis from the distribution temperature measured by the distribution temperature measuring device and the current data acquired by the current acquiring means. Passion water calculation device to generate; Underground power transmission and distribution thermal runaway prevention system, characterized in that consisting of a current control device for reducing the current of the underground power transmission and distribution link when an alarm occurs in the passion water calculating device. 5. The sensor of claim 4, wherein the distributed temperature measuring sensor comprises: a first distributed temperature measuring sensor installed in a longitudinal direction parallel to the underground power transmission wiring; Underground power transmission and distribution thermal runaway prevention system, characterized in that consisting of a second distribution temperature measuring sensor installed in the longitudinal direction in parallel with a constant distance to the first distribution temperature measuring sensor. A temperature calculating step of acquiring a current flowing through the underground power transmission / distribution link by an acquiring means to calculate a temperature around the underground power transmission / distribution link; A temperature measuring step of measuring a temperature distributed by a distribution temperature measuring sensor installed in a longitudinal direction with respect to the underground power transmission and distribution link installed in the soil after the temperature calculating step; A first judging step of determining whether a temperature measured in the temperature measuring step is equal to or greater than a reference value by using a distribution temperature measuring device; When the temperature measured in the first determination step is less than the reference value passion calculation step of calculating the amount of heat from the outside of the underground power transmission and distribution link and the passion water from the soil around the underground power transmission and distribution link in the passion water calculating device; A second judging step of determining whether or not the passion water value calculated in the calculating step is greater than or equal to the reference value, and returning to an initial state if it is less than or equal to the reference value; An alarm generation step of generating an alarm in the passion water calculating device when the temperature determined in the first and second determination steps is greater than or equal to the reference value and the passion water is greater than or equal to the reference value; Underground power transmission and distribution thermal runaway control method comprising the current control step of controlling the current in the underground power transmission and distribution link when the alarm is generated in the alarm generation step.

Images