KR102082312B1 - Apparatus and method for monitoring overheating of gis(gas insulated switchgear) and power cable connections - Google Patents

Abstract

An apparatus and a method for overheat monitoring of a gas insulated switchgear and a power cable connection are provided, wherein the gas insulated switchgear collects and manages the temperature of the connection measured in a temperature measuring means installed in the connection with the power cable. The overheat monitoring apparatus of the gas insulated switchgear and the power cable connection presented is provided with a temperature measuring means which is installed at the connection of the gas insulated switchgear and the power cable to measure the temperature of the connection portion; Communication means for transmitting the temperature of the connection portion measured by the temperature measuring means via a local area network; And a temperature collecting means for generating an alarm by determining whether overheating of the connection part occurs based on a predetermined temperature set value and the temperature of the connection part received from the communication means.

Description

Overheating monitoring device and method of gas insulated switchgear and power cable connection {APPARATUS AND METHOD FOR MONITORING OVERHEATING OF GIS (GAS INSULATED SWITCHGEAR) AND POWER CABLE CONNECTIONS}

The present invention relates to a device and a method for overheat monitoring of a gas insulated switchgear and a power cable connection, and more particularly, to a gas insulator switch for monitoring an overheat of a connection of a power cable and a gas insulated switchgear of a substation facility. And methods.

The gas insulated switchgear installed in the substation equipment applies the property of SF6, which is an inert gas, to protect the system by safely opening and closing the switch under abnormal conditions such as short-circuit accident as well as switching current in a normal state.

Gas insulated switchgear will fail when overheating in connection with power cable. If a gas insulated switch breaks down, the power supply is interrupted due to power outage of the substation facility.

In order to prevent this, conventionally, a thermal tape is attached to a connection for sensing the temperature of the connection between the gas insulated switchgear and the power cable. During the instantaneous inspection, the operator visually checks whether the temperature tape attached to the connection is discolored and monitors the connection for overheating.

Alternatively, an infrared camera is used to photograph the connection, and the captured image is analyzed to monitor whether the connection is overheated.

However, in the conventional overheat monitoring method of the connection of the gas insulated switchgear and the power cable, there is a problem in that the inspection manpower and the inspection time are excessive because the inspection is performed using the naked eye or the measuring equipment.

In addition, the conventional overheat monitoring method of the connection between the gas insulated switchgear and the power cable is performed by the operator's manual operation, and thus the reliability of the measurement decreases, and there is no blind point and there is no blind point. There is a problem in that it is impossible to quickly cope with the equipment failure, causing a problem in the power supply.

In addition, the conventional overheat monitoring method of the connection between the gas insulated switchgear and the power cable has a problem that the manpower and management time is excessive due to the trend management through the manual operation of the operator.

Prior Document 1: Korean Patent Publication No. 10-2012-0035502 (Name: Power cable pull-out device of the gas insulated switch) Prior Document 2: Korean Patent Publication No. 10-2010-0002964 (Name: Remote management system and method for the preventive diagnosis system of the JIS)

The present invention has been proposed to solve the above-mentioned conventional problems, and the gas insulated switch is a gas insulated switch configured to collect and manage the temperature of the connection part measured by the temperature measuring means installed in the connection part with the power cable. An object of the present invention is to provide an overheat monitoring apparatus and method for a power cable connection portion.

In order to achieve the above object, an overheat monitoring apparatus of a gas insulated switchgear and a power cable connection unit according to an embodiment of the present invention includes: temperature measuring means installed at a connection portion of a gas insulated switchgear and a power cable to measure a temperature of the connection unit; Communication means for transmitting the temperature of the connection portion measured by the temperature measuring means through a local area network; And temperature collection means for generating an alarm by determining whether overheating of the connection part occurs on the basis of a preset temperature set value and the temperature of the connection part received from the communication means, wherein the temperature collection means includes a temperature of the received connection part. Based on the display of the temperature change of the connection screen, the surface temperature and ID of the three phases of the connection in text form, the surface temperature and ID of the single phase of the connection in the form of a graph, by the user The surface temperature of a specific time according to the input search condition is displayed on the screen, and the temperature collecting means generates an alarm when it is determined that overheating of the connection part occurs, and transmits an alarm to a preset manager terminal or a scarda system. And the temperature of the connection portion received from the communication means, in the manager terminal or in the SCADA system. Communication module for transmitting to the to; Including at least one of a connection ID and a time by the user An input module for receiving a search condition; A storage module for storing the surface temperature of the contact portion; A detection module for detecting a surface temperature of the connection portion corresponding to the search condition from a storage module; An output module for outputting a surface temperature of the connection portion; The detection module is controlled to detect the surface temperature of the contact portion corresponding to the search condition received from the input module, and receives the surface temperature of the contact portion corresponding to the search condition from the detection module to change the surface temperature of the contact portion. And a control module for controlling the output module to display.

The temperature measuring means is provided on the surface of the connecting portion to measure the surface temperature of the connecting portion.

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In order to achieve the above object, an overheat monitoring method of a gas insulated switchgear and a power cable connection unit according to an embodiment of the present invention includes: measuring temperature of a gas insulated switchgear and a power cable by a temperature measuring unit; Transmitting, by communication means, the temperature of the measured connection portion through a local area network; And determining, by a temperature collecting means, whether overheating of the connection part occurs based on a predetermined temperature setting value and the temperature of the connection part received from the communication means; And generating, by the temperature collecting means, an alarm if it is determined that overheating of the connection part occurs in the determining step, and by the temperature collecting means, a temperature change of the connection part based on the received connection part temperature. Display the screen, the surface temperature and ID for the three phases of the connection in text form, the surface temperature and ID for the single phase of the connection in graph form, the specific time according to the search conditions input by the user Display the surface temperature of the screen, and by the communication module included in the temperature collecting means, if it is determined that the overheating of the connection unit generates an alarm, and transmits the alarm to a predetermined manager terminal or the SCADA system, The temperature of the connection received from the communication means is transmitted to the manager terminal or the SCADA system. And, by the input module included in the temperature collecting means, comprising at least one of the connection ID and time by the user, The surface temperature of the connection part corresponding to the search condition is received by a storage module included in the temperature collecting means, receiving the search condition, and storing the surface temperature of the connection part by the storage module included in the temperature collecting means. Is detected from the storage module, and the output module included in the temperature collecting means outputs the surface temperature of the connection portion, and corresponds to the search condition received from the input module by the control module included in the temperature collecting means. And control the detection module to detect the surface temperature of the contact portion, and control the output module to receive the surface temperature of the contact portion corresponding to a search condition from the detection module and display a change in the surface temperature of the contact portion. It is done.

In the step of measuring the connection part temperature, the surface temperature of the connection part is measured by a temperature measuring means.

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According to the present invention, the apparatus and method for overheat monitoring of a gas insulated switchgear and a power cable connection part automatically measure and transmit the temperature of the gas insulated switchgear and a power cable connection part. Compared to the prior art made by manual operation, the efficiency of manpower operation is maximized, and the trend management enables the preliminary confirmation of abnormal symptoms, and has the effect of improving the accuracy of temperature measurement.

According to the present invention, the apparatus and method for overheat monitoring of a gas insulated switchgear and a power cable connection part automatically measures and transmits the temperature of the gas insulated switchgear and a power cable connection part. It is possible to monitor all the time and prevent the power failure by quickly coping with the manager in the event of overheating.

1 is a view for explaining the overheat monitoring device of the gas insulated switchgear and power cable connection according to an embodiment of the present invention.
FIG. 2 is a block diagram illustrating the temperature collection device of FIG. 1. FIG.
3 to 5 are views for explaining the output module of FIG.
6 is a view for explaining the overheat monitoring method of the gas insulated switch and the power cable connection according to an embodiment of the present invention.

Hereinafter, the most preferred embodiments of the present invention will be described with reference to the accompanying drawings so that those skilled in the art can easily implement the technical idea of the present invention. . First of all, in adding reference numerals to the components of each drawing, it should be noted that the same reference numerals are designated as much as possible even if displayed on different drawings. In addition, in describing the present invention, if it is determined that the detailed description of the related well-known configuration or function may obscure the gist of the present invention, the detailed description thereof will be omitted.

Hereinafter, an overheat monitoring apparatus of a gas insulated switchgear and a power cable connection unit according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings. 1 is a view for explaining the overheat monitoring apparatus of the gas insulated switch and the power cable connection according to an embodiment of the present invention. FIG. 2 is a block diagram illustrating the temperature collection device of FIG. 1, and FIGS. 3 to 5 are views for explaining the output module of FIG. 2.

As shown in FIG. 1, the overheat monitoring apparatus of the gas insulated switch and the power cable connection unit includes a plurality of temperature measuring means 120, communication means 140, and temperature collecting means 160. Here, in FIG. 1, although the plurality of temperature measuring means 120 is connected to the communication means 140, the communication means 140 and the temperature measuring means 120 may be connected one-to-one. Of course, the temperature measuring means 120 and the communication means 140 may be configured as a single device.

The temperature measuring unit 120 is installed at the connection portion 30 of the gas insulated switchgear 10 and the power cable 20 to measure the temperature of the connection portion 30. At this time, the temperature measuring means 120 is composed of a thermistor (Thermistor) is installed on the surface of the connecting portion (30). The temperature measuring unit 120 periodically measures the surface temperature of the connection unit 30 according to a preset measurement cycle (for example, about 1 minute to 10 minutes) and transmits the measured surface temperature to the communication unit 140. Here, the temperature measuring unit 120 transmits the ID of the connection unit 30 of the measurement target connection unit 30 to the communication unit 140 together with the surface temperature.

The communication means 140 receives the surface temperature of the connection portion 30 from the plurality of temperature measuring means 120. The communication means 140 transmits the surface temperature of the connection portion 30 to the temperature collecting means 160 via near field communication. At this time, the communication means 140 transmits the surface temperature and the connection part ID to the temperature collection means 160. Here, the communication means 140 is configured as a terminal supporting near field communication such as RFID, NFC, Zigbee, Bluetooth.

The temperature collecting means 160 receives the surface temperature of the connection 30 via the communication means 140. That is, the temperature collecting means 160 receives the surface temperature of the connection portion 30 from the communication means 140 via the local area network 200.

The temperature collecting unit 160 determines whether overheating of the connection unit 30 occurs based on a preset temperature set value and surface temperature. At this time, the temperature collecting unit 160 determines that the overheating occurs in the connection unit 30 when the surface temperature is equal to or higher than the temperature set value.

The temperature collecting unit 160 generates an alarm based on the determination result of the overheat occurrence of the connection unit 30. That is, when the temperature collecting unit 160 determines that the overheating of the connection unit 30 occurs, the temperature collecting unit 160 generates an alarm through a buzzer, a lamp flashing, or the like. In this case, when determining that the overheating of the connection unit 30 occurs, the temperature collecting unit 160 may transmit an alarm message to the manager terminal 300 through a wired / wireless network 400 such as a mobile communication network, a LAN, or a WiFi. Here, the manager terminal 300 may be configured of a laptop, desktop, smart phone, and the like.

The temperature collecting unit 160 classifies and stores the received surface temperature for each connection unit 30. That is, the temperature collecting means 160 stores the separator (eg, name, unique number, etc.) of the connection part 30 in association with the surface temperature of the connection part 30.

The temperature collecting unit 160 displays the surface temperature of the received connection unit 30 on the screen. That is, the temperature collecting means 160 outputs the received surface temperature of the connecting portion 30 in a text, graph or the like, and displays the current surface temperature of the connecting portion 30 on the screen. In this case, the temperature collecting unit 160 displays the screen by dividing the surface temperature for each connection unit 30.

The temperature collecting unit 160 displays the surface temperature of the connection unit 30 as a trend for each period and the surface temperature of a specific time according to a search condition. That is, the temperature collecting means 160 is based on a trend for each period (for example, year, month, day) that means a change in the surface temperature of each connection part 30 based on the previously stored surface temperature, and the search condition input by the user. Screen surface temperature according to the specified time.

The temperature collecting means 160 may transmit the surface temperature and the alert of the connection 30 to the SCADA system through the wired / wireless network 400. Through this, the surface temperature of the connection unit 30 and the alarm according to the overheating occurrence in the scarda system 500 can be confirmed.

The temperature collecting means 160 sets the surface temperature measuring cycle and the temperature set value of the temperature collecting means 160. That is, the temperature collecting unit 160 receives the measurement period and the temperature set value to the manager terminal 300 through the wired / wireless network 400. The temperature collecting unit 160 may directly receive a measurement cycle and a temperature set value from the manager. The temperature collecting unit 160 transmits the measurement cycle of the set surface temperature through the local area network 200 to set the measurement cycle of the temperature measuring unit 120. The temperature collecting means 160 changes the existing temperature set value to the input temperature set value.

To this end, as shown in FIG. 2, the temperature collecting means 160 includes a communication module 161, an input module 162, a setting module, a determination module 167, and an output module 166.

The communication module 161 transmits and receives data with the communication means 140, the manager terminal 300, and the scarda system 500. That is, the communication module 161 receives the surface temperature of the connection unit 30 from the communication means 140 via the local area network 200. The communication module 161 transmits a measurement period to the communication means 140 via the local area network 200. The communication module 161 transmits surface temperature related information of the connection unit 30 to the manager terminal 300 and the SCADA system 500 through the wired / wireless network 400. In other words, the communication module 161 transmits an alarm corresponding to the surface temperature and the overheating of the connection unit 30 to the manager terminal 300 and the scarda system 500 through the wired / wireless network 400.

The input module 162 includes a touch panel and a keyboard to receive a measurement cycle, a temperature set value, a search condition, control information, and the like. The input module 162 transmits the measurement period and the temperature set value to the control module 163.

The control module 163 controls the communication module 161 to transmit the measurement period received from the input module 162 to the temperature measuring means 120. That is, the control module 163 transmits the measurement period received together with the measurement period transmission request message to the communication module 161.

The control module 163 controls the determination module 167 to change the preset temperature setting value to the temperature setting value received from the input module 162. That is, the control module 163 transmits the temperature set value received from the input module 162 to the determination module 167 together with the temperature set value update request message.

The control module 163 controls the output module 166 to display the surface temperature of the connection portion 30 received from the communication module 161. That is, the control module 163 transmits the connection unit 30 information and the surface temperature of the connection unit 30 to the output module 166 together with the screen output request message.

The control module 163 controls the storage module 164 to store the surface temperature of the connection 30 received from the communication module 161. That is, the control module 163 transmits the surface temperature of the connection unit 30 to the storage module 164 together with the storage request message.

The control module 163 controls the detection module 165 to detect the surface temperature of the connection unit 30 corresponding to the search condition received from the input module 162. That is, the control module 163 transmits a search condition to the detection module 165. The control module 163 receives the surface temperature of the connection unit 30 corresponding to the search condition from the detection module 165. The control module 163 controls the output module 166 to display the surface temperature of the connection portion 30 received from the detection module 165.

The control module 163 transmits the surface temperature of the connection unit 30 received from the communication module 161 or the detection module 165 and an alarm resulting from overheating of the connection unit 30 to the SCADA system. To control.

The storage module 164 stores the surface temperature of the connection unit 30 received from the control module 163. The storage module 164 stores the surface temperature for each connection unit 30. In this case, the storage module 164 stores the connection unit ID, surface temperature, and measurement time in association.

The detection module 165 detects the surface temperature corresponding to the search condition received from the control module 163 from the storage module 164. That is, the detection module 165 receives a search condition including at least one of the ID and time of the connection unit 30 from the control module 163. The detection module 165 detects, from the storage module 164, the surface temperature associated with at least one of the ID and time of the connection part 30 included in the received search condition. The detection module 165 transmits the detected surface temperature to the control module 163.

The output module 166 outputs the surface temperature of the connecting portion 30 received from the control module 163. The output module 166 outputs the surface temperature together with the connection 30 ID to display the current surface temperatures of the connections 30. In this case, the output module 166 outputs the surface temperature in a text form (see FIG. 3), a graph form (see FIG. 4), and a trend form (see FIG. 5).

The output module 166 outputs the surface temperature corresponding to the search condition received from the control module 163. That is, the output module 166 outputs the surface temperature of the connecting portions 30 at a specific time (or a specific time zone). The output module 166 outputs a specific time and the surface temperature of the specific connection 30.

The determination module 167 updates the preset temperature setting value to the temperature setting value received from the control module 163 according to the control of the control module 163. That is, when the determination module 167 receives the temperature set value update request message from the control module 163, the determination module 167 updates the preset temperature set value to the temperature set value received from the control module 163.

The determination module 167 compares the surface temperature of the connection unit 30 input from the communication module 161 with the temperature set value to determine whether overheating of the connection unit 30 occurs. At this time, the determination module 167 determines that overheating of the connection part 30 occurs when the surface temperature of the connection part 30 is equal to or higher than a temperature set value.

The alarm module 168 generates an alarm when the determination module 167 determines that the overheating of the connection unit 30 occurs. At this time, the alarm module 168 generates an alarm for warning of overheating of the connection unit 30 through a buzzer, a lamp flashing, or the like. The alarm module 168 may transmit an alarm message to the manager terminal 300 through a wired or wireless network 400 such as a mobile communication network, a LAN, or a WiFi when an overheating occurs in the connection unit 30.

Hereinafter, the overheat monitoring method of the gas insulated switchgear and the power cable connection unit according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings. 6 is a view for explaining the overheat monitoring method of the gas insulated switch and the power cable connection according to an embodiment of the present invention.

The temperature measuring unit 120 measures the temperature of the connection portion 30 of the gas insulated switch 10 and the power cable 20 (S100). That is, the temperature measuring means 120 periodically measures the surface temperature of the connection portion 30 according to a predetermined measurement cycle (for example, about 1 minute to 10 minutes). The temperature measuring unit 120 transmits the surface temperature of the connection unit 30 measured through a communication module (not shown) supporting the local area network 200 or a separate communication unit 140 to the temperature collecting unit 160. do. At this time, the temperature measuring unit 120 transmits the ID of the connection unit 30 of the measurement target connection unit 30 to the temperature collection unit 160 together with the surface temperature. Here, the temperature measuring means 120 may have a fixed measuring period or set a period input from the manager through the temperature collecting means 160 as the measuring period.

The temperature collecting unit 160 outputs the temperature of the connection unit 30 received by the temperature measuring unit 120 (S200). That is, the temperature collecting means 160 is a time period (for example, it means that the surface temperature of the connection portion 30 received from the temperature measuring means 120 means a change in the surface temperature of the text form, graph form, the connection portion 30, Year, month, day) Print in the form of trend. In this case, the temperature collecting unit 160 displays the screen by dividing the surface temperature for each connection unit 30. Here, the temperature collecting unit 160 may display the surface temperature of the specific time according to the search condition. The temperature collecting unit 160 may transmit the surface temperature of the connection unit 30 to the SCADA system or the manager terminal 300 through the wired / wireless network 400.

The temperature collecting unit 160 determines whether overheating of the connection unit 30 occurs based on the temperature set value and the temperature of the connection unit 30 (S300). At this time, the temperature collecting unit 160 determines that overheating of the connection unit 30 occurs when the temperature (that is, the surface temperature) of the connection unit 30 is equal to or higher than the temperature set value.

If it is determined that the overheating occurs in the connecting portion 30 (S400; YES), the temperature collecting means 160 generates an alarm indicating the overheating occurrence of the connecting portion 30 (S500). That is, the temperature collecting unit 160 generates an alarm for warning the overheating of the connection unit 30 through a buzzer, a lamp flashing, or the like when the overheating of the connection unit 30 occurs. Here, when the temperature collecting unit 160 determines that the overheating of the connection unit 30 occurs, an alarm message is sent to the manager terminal 300 or the scarda system 500 through the wired / wireless network 400 such as a mobile communication network, a LAN, or a WiFi. Can also be transmitted.

As described above, the overheat monitoring apparatus and method of the gas insulated switchgear and the power cable connection unit automatically measure and transmit the temperature of the gas insulated switchgear 10 and the power cable 20 connection part 30, and use the same to connect the connection part 30. By overheating the alarm and generating an alarm, the efficiency of manpower operation can be maximized compared to the prior art made by the manual operation of the manager, and the trend management enables the preliminary confirmation of abnormal symptoms and the accuracy of the temperature measurement can be improved. It has an effect.

According to the present invention, the overheat monitoring apparatus and method of the gas insulated switchgear and the power cable connection unit automatically measure and transmit the temperature of the gas insulated switchgear 10 and the power cable 20 connection part 30, and use the same to connect the connection part 30. By monitoring the overheating of the alarm), 24 hours of continuous monitoring is possible, and in the event of overheating, the manager can quickly deal with the power failure and prevent power failure.

Although a preferred embodiment according to the present invention has been described above, it can be modified in various forms, and those skilled in the art can make various modifications and modifications without departing from the claims of the present invention. It is understood that it may be practiced.

10: gas insulated switchgear 20: power cable
30 connection part 120 temperature measuring means
140: communication means 160: temperature collection means
161: communication module 162: input module
163: control module 164: storage module
165: detection module 166: output module
167: judgment module 168: alarm module
200: local area network 300: administrator terminal
400: network 500: Skada system

Claims (10)

Temperature measuring means provided at a connection portion of a gas insulated switchgear and a power cable to measure a temperature of the connection portion;
Communication means for transmitting the temperature of the connection portion measured by the temperature measuring means through a local area network; And
And a temperature collecting means for generating an alarm by determining whether overheating of the connection part occurs based on a predetermined temperature setting value and the temperature of the connection part received from the communication means,
The temperature collecting means displays the temperature change of the connection portion based on the received temperature of the connection portion,
Display the surface temperature and ID of the three phases of the connection in text form, display the surface temperature and ID of the single phase of the connection in graph form, and display the surface temperature of a specific time according to a search condition input by the user. Mark on,
The temperature collecting means,
If it is determined that the overheating of the connection portion is generated, an alarm is generated, and an alarm is transmitted to a predetermined manager terminal or a skada system, and communication for transmitting the temperature of the connection portion received from the communication means to the manager terminal or skada system module;
Including at least one of a connection ID and a time by the user An input module for receiving a search condition;
A storage module for storing the surface temperature of the contact portion;
A detection module for detecting a surface temperature of the connection portion corresponding to the search condition from a storage module;
An output module for outputting a surface temperature of the connection portion;
The detection module is controlled to detect the surface temperature of the contact portion corresponding to the search condition received from the input module, and receives the surface temperature of the contact portion corresponding to the search condition from the detection module to change the surface temperature of the contact portion. A control module for controlling the output module to display;
Overheat monitoring device of the gas insulated switch and power cable connection comprising a.
The method according to claim 1,
The temperature measuring means,
The overheat monitoring apparatus of the gas insulated switchgear and the power cable connection part provided on the surface of the said connection part and measuring the surface temperature of the said connection part. delete delete delete Measuring, by the temperature measuring means, the connection temperature of the gas insulated switch and the power cable;
Transmitting, by communication means, the temperature of the measured connection portion through a local area network; And
Determining, by a temperature collecting means, whether overheating of the connection part occurs based on a predetermined temperature setting value and a temperature of the connection part received from the communication means; And
By the temperature collecting means, generating an alarm if it is determined that overheating of the connection part occurs in the determining step,
By the temperature collecting means, the temperature change of the connection portion is displayed on the screen based on the received temperature of the connection portion,
Display the surface temperature and ID of the three phases of the connection in text form, display the surface temperature and ID of the single phase of the connection in graph form, and display the surface temperature of a specific time according to a search condition input by the user. Mark on,
When the communication module included in the temperature collecting means determines that the overheating of the connection part occurs, an alarm is generated, the alarm is transmitted to a predetermined manager terminal or the SCADA system, and the temperature of the connection part received from the communication means is determined. Transmit to the manager terminal or the skada system,
By the input module included in the temperature collecting means, by the user includes at least one of the connection ID and time Receive the search criteria,
By means of a storage module included in the temperature collecting means, storing the surface temperature of the contact portion,
A detection module included in the temperature collecting means detects the surface temperature of the connection portion corresponding to the search condition from the storage module,
By the output module included in the temperature collecting means, output the surface temperature of the connecting portion,
The detection module controls the detection module to detect the surface temperature of the connection part corresponding to the search condition received from the input module by a control module included in the temperature collecting means, and the connection part corresponding to the search condition from the detection module. And controlling the output module to receive a surface temperature and display a change in the surface temperature of the connection portion. The method according to claim 6,
In the step of measuring the connection temperature
And overtemperature monitoring method for the gas insulated switchgear and the power cable connecting portion, by measuring the surface temperature of the connecting portion by the temperature measuring means. delete delete delete

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