KR20230053795A - Fiber optic sensor probe for diagnosis of transformer insuation oil aging - Google Patents

Abstract

The present invention relates to an optical fiber sensor probe for diagnosing deterioration of insulating oil for a transformer. The optical fiber sensor probe for diagnosing deterioration of insulating oil for a transformer comprises: a light source which emits light; an optical transmitter which includes a main optical fiber configured to transmit light transmitted from the light source, a sub optical fiber arranged to surround the main optical fiber and configured to transmit light, and a covering part surrounding the main optical fiber and the sub optical fiber; a test object which is installed inside a transformer, and includes a main body having an internal receiving space extending along a first direction from a first coupling port to which the optical transmitter is coupled, and an open hole formed in a middle portion thereof to communicate with the internal receiving space and the outside to allow the inflow of insulating oil and a sub body communicating with the internal receiving space of the main body but extends in a direction intersecting the extension direction of the main body; a reflector which is arranged to reflect light having passed through the insulating oil flowing into the internal receiving space of the main body and transmit the light to the sub optical fiber; a relay transmitter which is coupled to a sub body and has a relay optical fiber for transmitting light scattered in the internal accommodation space of the main body and transmitted through the sub body; a first light detection unit which detects first light received through the sub optical fiber; a second light detection unit which detects second light received through the relay optical fiber; and a measuring unit which measures the chromaticity and turbidity of the insulating oil from signals output from the first and second light detection units. According to the present invention, the optical fiber sensor probe has a longer optical path than an existing optical fiber sensor and thus has more excellent signal quality.

Description

Fiber optic sensor probe for diagnosis of transformer insulation oil aging}

The present invention relates to an optical fiber sensor probe for diagnosing deterioration of transformer insulating oil, and more particularly, to an optical fiber sensor probe capable of diagnosing deterioration by simultaneously measuring chromaticity and turbidity of insulating oil.

A transformer is a very important facility for power supply, and various diagnostic methods are applied to detect abnormalities at an early stage so as to prevent power supply interruption.

As a method for diagnosing abnormalities in the transformer, Korean Patent Publication No. 10-2005-0023878 discloses a device for diagnosing abnormalities by detecting pyrolysis gas of insulating oil.

The device detects gas by installing a gas sensor in the upper space of insulating oil filled inside the transformer. In this case, in order to distinguish and identify the gas type, a plurality of sensors capable of detecting each gas type must be provided. There is a disadvantage that it is difficult to build to detect while distinguishing the type of gas.

In addition, when applying a gas sensor operated by power supply, there is a disadvantage in that durability can be weakened when arcs and discharges occur through power supply wiring.

Meanwhile, as a method of detecting deterioration of the insulating oil, there is a method of measuring the chromaticity or turbidity of the insulating oil.

As such a deterioration detection method, after installing the light emitting element and light receiving element in a straight line inside the transformer, measuring the optical power lost using the light scattering characteristics of the material inside the insulating oil to calculate the turbidity. The measurement method and configuration are disclosed in Korean Registered Patent Nos. 10-1100330 and 10-1291213. Since the optical sensor directly installs the light emitting element and the light receiving element inside the transformer, there is a very high probability that the elements will fail in a high voltage and insulating oil inflow environment. In addition, since a wire is used to connect a light emitting element, a light receiving element, and a measuring instrument, there is a very high possibility that the sensor may malfunction due to electromagnetic interference.

In addition, a device for detecting the temperature and gas of the insulating oil after impregnating a specially processed optical fiber with the insulating oil inside the transformer is disclosed in Korean Registered Patent No. 10-1681561. The system measures the temperature using the variation of the reflected wavelength of the optical fiber grating and uses the transmission or reflection spectrum of the gas introduced into the fiber using the hollow fiber to determine the type of gas contained in the insulating oil, but also determines the turbidity and chromaticity. There are disadvantages in that the length of the optical path is very short to measure and the light loss due to bending of the optical fiber is very large.

The present invention was invented to improve the above problems, and provides an optical fiber sensor probe capable of diagnosing the deterioration state of the transformer insulating oil by simultaneously measuring the chromaticity and turbidity of the insulating oil inside the transformer without installing an optical active element therein. There is a purpose.

In order to achieve the above object, an optical fiber sensor probe according to the present invention is capable of diagnosing deterioration of insulating oil filled in a transformer, comprising: a light source for emitting light; an optical transmission body having a main optical fiber disposed in the center to transmit light transmitted from the light source, a sub optical fiber disposed to surround the main optical fiber and transmitting light, and a sheathing portion to surround and surround the main optical fiber and the sub optical fiber; It is installed inside the transformer and has an inner accommodating space extending along a first direction from the first coupler to which the optical transmitter is coupled, and an open hole communicating with the inner accommodating space and the outside to allow the inflow of the insulating oil to the middle portion. a test body having a main body formed thereon, and a sub body extending in a direction intersecting the extension direction of the main body while communicating with the inner accommodating space in the main body; a reflector disposed farther from the first coupler than the sub body to reflect the light transmitted from the optical transmission body and passed through the insulating oil introduced into the inner accommodating space of the main body; a relay transporter coupled to the subbody and having a relay optical fiber for transmitting light scattered in the inner accommodating space of the main body and transmitted through the subbody; a first light detector detecting first light reflected from the reflector and received through the sub optical fiber; a second photodetector for detecting the second light received through the relay optical fiber; and a measurement unit for measuring chromaticity and turbidity of the insulating oil from signals output from the first and second photodetectors.

It is preferable that the optical transmission body has 6 sub-optical fibers arranged in close contact around the main optical fiber, and in the relay transmission structure, 6 relay optical fibers are arranged closely around one relay optical fiber.

In addition, the main body and the optical transmitter can be coupled to and separated from each other using a screw coupling method, and the subbody and the relay transmitter can be coupled to and separated from each other using a screw coupling method.

In addition, a first collimating lens mounted between the optical transmitter and the main body; A second collimating lens mounted between the subbody and the relay transporter may be further included.

According to one aspect of the present invention, the main optical fiber includes a first part for receiving and transmitting the light transmitted from the light source, and a first part for receiving the light transmitted from the first part and transmitting the light to the inlet of the main body. and a coupler having two parts, combining the first part and the second part to relay optical transmission, wherein the sub-optical fiber is connected to the combiner and transmits light to the first photodetector. and a fourth portion connected to the third portion to relay optical transmission through the coupler and extending toward the inlet of the main body.

According to the optical fiber sensor probe for diagnosing deterioration of transformer insulating oil according to the present invention, since the optical active element is not installed inside the transformer, it can be safely used without malfunction even in a high voltage and insulating oil inflow environment, and the optical path is longer than the existing optical fiber sensor. Therefore, the signal quality is better. In addition, chromaticity and turbidity can be measured at the same time, and manufacturing cost and time can be reduced because it can be easily manufactured with only a multimode fiber bundle without special processes such as fiber optic grating laser process and hollow fiber manufacturing process.

1 is a view showing an optical fiber sensor probe according to an embodiment of the present invention;
Figure 2 is an exploded perspective view showing the inspection body of Figure 1 is separated,
3 is a view showing an optical fiber sensor probe according to another embodiment of the present invention.

Hereinafter, an optical fiber sensor probe according to a preferred embodiment of the present invention will be described in more detail with reference to the accompanying drawings.

FIG. 1 is a view showing an optical fiber sensor probe according to an embodiment of the present invention, and FIG. 2 is an exploded perspective view showing the inspection body of FIG. 1 in a separated manner.

1 and 2, the optical fiber sensor probe 100 according to the present invention includes a light source 110, an optical transmission element 120, a test element 130, a reflector 151, a relay transmission element 160, a first A first photodetector 181, a second photodetector 182, and a measurement unit 190 are provided.

The light source 110 emits light so that light is transmitted through the main optical fiber 121 of the optical transmission body 120 so that deterioration of the insulating oil 20 filled in the transformer 10 can be diagnosed.

The optical transmission body 120 includes a main optical fiber 121 disposed in the center and transmitting light transmitted from the light source 110, a sub optical fiber 123 disposed surrounding the main optical fiber 121 and transmitting light, and a main optical fiber 121 and the sub-optical fiber 123 are surrounded by a covering portion 125. In the illustrated example, in the optical transmission body 120, six sub-optical fibers 123 are concentrically arranged around one main optical fiber 121 in close contact, and the main optical fiber embedded at the end of the enclosing portion 125 ( 121) and the sub-optical fiber 123, it has a structure with a first screw coupling part 125a having a screw thread formed on the outer circumferential surface so that it can be coupled to and separated from the inspection body 130 described later in a screw manner while supporting light relay. . The first screw coupling portion 125a may be formed of a metal or hard synthetic resin material, and the remaining coating portion 125 may be formed of a mutually coupled structure by applying a material that allows bending.

In addition, a part of the main optical fiber 121 extending from the front end of the enclosing part 125 to the light source 110 and a part of the sub optical fiber extending to the first light detector 181 may be exposed from the enclosing part 125. can

The inspection object 130 irradiates the light transmitted from the light source 110 through the main optical fiber 121 to the insulating oil, and transmits the light scattered from the insulating oil and the light reflected from the reflector 151 to the sub optical fiber 122 and Transmission to the relay optical fiber 161 can be supported.

It can be divided into a main body 131 and a sub body 135. Here, the main body 131 and the optical transmitter 120 can be mutually coupled and separated by a screw coupling method, and the sub body 135 and the relay transmitter 160 can also be coupled to and separated from each other by a screw coupling method. is formed to be able to

The inspection body 130 is installed inside the transformer 10 and is screwed in communication with the first screw coupling portion 125a of the optical transmission body 120 along a first direction from the first coupler 131a serving as an entrance. A main body 131 having an extended inner accommodating space 132 and having an open hole 134 communicating with the inner accommodating space 132 and the outside to allow the inflow of the insulating oil 20 in the middle portion, and 131 has a structure having a subbody 135 that communicates with the inner accommodation space 132 and protrudes in a direction crossing the extension direction of the main body 131.

Here, the main body 131 is formed in a tubular shape with one end open and the other end closed, and a first inner portion screwed with the first screw coupling part 125a on the inner circumferential surface along the longitudinal direction from the first coupler 130a. A thread is formed.

In addition, the sub body 135 is formed in the form of a hollow tube, communicates with the inner accommodation space 132, and is screwed to communicate with the second screw coupling part 165a formed in the relay transmission body 160 to be described later, and has an outlet. A second internal thread screwed to the second screw coupling portion 165a is formed on the inner circumferential surface of the second coupler 135a toward the main body 131.

The reflector 151 reflects the light transmitted from the light transmitter 120 and passed through the insulating oil 20 introduced into the inner accommodating space 132 of the main body 131 from the first coupler 130a to the sub body. (135) is placed further away. The reflector 151 is disposed to transmit reflected light to the sub optical fiber 122 .

The first collimating lens 155 is mounted between the optical transmission body 120 and the main body 131 to focus the light transmitted from the main optical fiber 121 to the insulating oil 20 and to focus the scattered light to the sub optical fiber 122. supports

The second collimating lens 156 is mounted between the subbody 135 and the relay transmission body 160 to support focusing of light scattered from the insulating oil 20 to the relay optical fiber 161 .

The relay transmitter 160 is screwed to the subbody 135 and transmits the scattered light scattered in the inner accommodating space 132 of the main body 131 and transmitted through the subbody 135 through the relay optical fiber 161. do.

In the relay transmission body 160, six relay optical fibers 161 are concentrically arranged around one relay optical fiber 161 in close contact, and the enclosing portion 165 surrounding the relay optical fibers 161 is It has a structure with

At the front end of the enclosing part 165, a second screw coupling part 165a having a threaded outer circumferential surface is provided so as to support optical relaying of the built-in optical relay fiber 161 and to be coupled to and separated from the sub body 135 in a screw manner. It has a structure with Similarly, the second screw coupling part 165a is made of a metal or hard synthetic resin material, and the rest of the covering part 165 of the relay transmission body 160 is made of a material that allows bending, and is coupled to each other. can be formed

According to this structure, the light emitted through the main optical fiber 121 and incident on the insulating oil 20 in the main body 131 is partially absorbed and scattered by the insulating oil 20, and the color of the insulating oil 20 is deteriorated. Corresponding to the change, the absorbed wavelength band and absorption rate change. In this case, information on the chromaticity is measured from the first light received back to the sub optical fiber 122 via the insulating oil 20 and the reflector 151, and the turbidity is scattered in the insulating oil 20 in a direction orthogonal to the light propagation direction. It is measured from the second light emitted to and transmitted through the relay optical fiber 161.

The first light detector 181 detects the first light reflected from the reflector 151 and received through the sub optical fiber 122 and outputs an electrical signal corresponding to the detected light to the measurement unit 190 .

The second light detector 182 detects the second light received through the relay optical fiber 161 and outputs an electrical signal corresponding to the detected light to the measurer 190 .

The measuring unit 190 controls driving of the light source 110 and measures chromaticity and turbidity of the insulating oil 20 from signals output from the first photodetector 181 and the second photodetector 182 .

In the measurement unit 190, a chromaticity value corresponding to the intensity of the signal received through the first photodetector 181 through the sub optical fiber 122 based on the intensity of light emitted from the light source 110, and a relay optical fiber ( 161), a look-up table (not shown) in which turbidity values corresponding to the intensity of the signal received through the second photodetector 181 are obtained through experiments and recorded therein is provided. Accordingly, the measurement unit 190 calculates chromaticity and turbidity from signals output from the first photodetector 181 and the second photodetector 182 by referring to the lookup table.

Of course, the measurement unit 190 may be constructed to transmit an alarm message to a registered manager or display an alarm message through the display unit when it is determined that the calculated chromaticity and turbidity correspond to the set alarm conditions.

On the other hand, the light transmission body may be built to be coupled through the coupler 125 in the manner shown in FIG. 3 differently from the illustrated example.

That is, the main optical fiber receives and transmits the light transmitted from the light source 110 to the first part 121a, and receives the light transmitted from the first part 121a and transmits the light to the inlet of the main body 131. and a second part 121b for optical transmission, and the coupler 125 optically and physically couples the first part 121a and the second part 121b to enable light transmission.

Similarly, the sub-optical fiber is also coupled to the third portion 122a connected to the coupler 125 to transmit light to the first photodetector 181, and through the coupler 125 to relay light transmission with the third portion 122a. It is built in a structure having a fourth portion (122b) extending toward the inlet of the main body (131).

Here, the coupler 125 may have various structures such as an optical connector supporting connection between optical fibers.

According to the fiber optic sensor probe for diagnosing deterioration of transformer insulating oil described above, stability can be improved while supporting simultaneous measurement of chromaticity and turbidity.

110: light source 120: optical transmitter
130: inspector 151: reflector
160: relay transporter 181: first photodetector
182: second light detection unit 190: measuring unit

Claims (5)

In an optical fiber sensor probe capable of diagnosing deterioration of insulating oil filled inside a transformer,
a light source for emitting light;
an optical transmission body having a main optical fiber disposed in the center to transmit light transmitted from the light source, a sub optical fiber disposed to surround the main optical fiber and transmitting light, and a sheathing portion to surround and surround the main optical fiber and the sub optical fiber;
It is installed inside the transformer and has an inner accommodating space extending along a first direction from the first coupler to which the optical transmitter is coupled, and an open hole communicating with the inner accommodating space and the outside to allow the inflow of the insulating oil to the middle portion. a test body having a main body formed thereon, and a sub body extending in a direction intersecting the extension direction of the main body while communicating with the inner accommodating space in the main body;
a reflector disposed farther from the first coupler than the subbody to reflect the light transmitted from the optical transmitter and passed through the insulating oil introduced into the inner accommodating space of the main body;
a relay transporter coupled to the subbody and having a relay optical fiber for transmitting light scattered in the inner accommodating space of the main body and transmitted through the subbody;
a first light detector detecting first light reflected from the reflector and received through the sub optical fiber;
a second photodetector for detecting the second light received through the relay optical fiber;
An optical fiber sensor probe for diagnosing deterioration of transformer insulating oil, characterized in that it comprises a; 2. The optical transmission system of claim 1 , wherein six sub-optical fibers are arranged in close contact around the main optical fiber, and in the relay transmission structure, six relaying optical fibers are arranged around one relay optical fiber in close contact with each other. An optical fiber sensor probe for diagnosing deterioration of transformer insulating oil, characterized in that. 3. The feature of claim 2, wherein the main body and the optical transmission body are coupled and separated from each other by a screw coupling method, and the subbody and the relay transmission body are also formed to be coupled and separated from each other using a screw coupling method. Fiber optic sensor probe for diagnosing deterioration of transformer insulating oil. According to claim 3,
a first collimating lens mounted between the optical transmitter and the main body;
An optical fiber sensor probe for diagnosing deterioration of transformer insulating oil, further comprising a second collimating lens mounted between the subbody and the relay transmission body. The method of claim 1, wherein the main optical fiber has a first portion for receiving and transmitting the light transmitted from the light source, and a second portion for receiving the light transmitted from the first portion and transmitting the light to the inlet of the main body. to provide,
And a coupler for coupling the first part and the second part to relay optical transmission;
The sub optical fiber has a third portion connected to the coupler and transmitting light to the first photodetector, and a fourth portion coupled to relay light transmission with the third portion through the coupler and extending toward the inlet of the main body. An optical fiber sensor probe for diagnosing deterioration of transformer insulating oil, characterized in that it is formed in a structure having a part.

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