KR102604974B1 - Power plant monitoring system using optical cable - Google Patents

Abstract

The present invention relates to a power generation facility monitoring system using an optical cable, which includes at least one sensing optical fiber installed in a power generation facility, transmitting light to the sensing optical fiber, receiving scattered light output from the sensing optical fiber, and receiving scattered light Based on this, a measurement unit is provided that calculates the detected physical quantity for the power generation facility.
The power generation facility monitoring system using an optical cable according to the present invention uses sensing optical fibers installed in the power generation facility, allowing workers to more easily recognize whether a defect has occurred in the power generation facility from a distance, thereby reducing the time and manpower required for inspection work. There is an advantage to being able to do it.

Description

Power plant monitoring system using optical cable}

The present invention relates to a power generation facility monitoring system using optical cables, and more specifically, to a safety monitoring system that can monitor the facility by installing distributed optical fiber sensors in the power generation facility.

In general, a power plant is equipped with equipment that converts thermal energy and mechanical energy into electrical energy, rotates a turbine using energy sources such as water, coal, natural gas, or nuclear energy, and produces electricity through a generator connected to the turbine.

Power plants are classified into hydroelectric power plants, thermal power plants, nuclear power plants, etc. depending on the type of energy source used and the resulting power generation method. As the lifespan of the power plant's facilities increases, the risk of being deformed or damaged by the high-pressure, high-temperature energy generated during the power generation process increases. If the power plant's equipment is damaged, there is a high possibility that disasters such as worker safety accidents or fires will occur. Accordingly, there is a demand for monitoring technology that can monitor the occurrence of defects or deformations in power plant facilities.

Conventional monitoring techniques involve taking a power plant out of operation and then visually inspecting it by an operator or through non-destructive testing. Therefore, it has the disadvantage of being inefficient because the power generation facility must be stopped while the inspection is in progress, and inconvenient because the operator must personally visit the facility and inspect it.

Registered Patent Publication No. 10-1629538: Method for non-destructively evaluating the current condition of steam generator tubes in nuclear power plants

The present invention was created to improve the above problems, and its purpose is to provide a power generation facility monitoring system using optical cables that allows workers to more easily monitor power generation facilities using distributed optical fiber sensors.

A power generation facility monitoring system using an optical cable according to the present invention to achieve the above object includes at least one sensing optical fiber installed in a power generation facility, transmitting light to the sensing optical fiber, and receiving scattered light output from the sensing optical fiber, It is provided with a measurement unit that calculates the detection physical quantity for the power generation facility based on the received scattered light.

In addition, the power generation facility monitoring system using an optical cable of the present invention further includes an adhesion unit installed in the power generation facility to bring the sensing optical fiber into close contact with the power generation facility.

The adhesion units are installed in the power generation facility to be spaced apart from each other along the longitudinal direction of the sensing optical fiber, and an installation hole is formed so that the sensing optical fiber can penetrate, and the sensing optical fiber penetrating the installation hole is positioned on the surface of the power generation facility. At least one fixing bracket having a cut portion cut along the longitudinal direction on the side opposite to the surface of the power generation facility so as to contact the power generation facility, and the sensing optical fiber installed on the fixing bracket through the cut portion of the power generation facility. It is provided with a pressurizing part that pressurizes the corresponding sensing optical fiber so that it is in close contact with the surface.

The pressurizing unit includes a pressurizing rod installed on the inner surface of the fixing bracket opposite the cutout portion so that an end is in contact with the outer peripheral surface of the sensing optical fiber so as to be able to advance and retreat toward the cutout portion, and the pressurizing rod is moved toward the cutout portion. An elastic member is provided to provide elastic force to the pressurizing rod.

The pressing portion is formed to surround the outer peripheral surface of the sensing optical fiber facing the pressing rod to prevent the sensing optical fiber from being deformed by the end of the pressing rod, and is made of a hard material, wherein the sensing optical fiber is used to generate power. A portion of the cover facing the cut portion may be further provided with a protective cover cut in the longitudinal direction so as to contact the surface of the facility.

The fixing bracket has a through slot formed at a position opposite to the protective cover, and the pressing portion intersects the longitudinal direction of the sensing optical fiber from the protective cover so as to protrude out of the fixing bracket through the through slot. It may further include an auxiliary arm that extends in the direction and is made of a hard material, and a fixing block installed at an end of the auxiliary arm to secure the auxiliary arm to the power generation facility at a position spaced apart from the fixing bracket.

A plurality of the fixing brackets are installed to be spaced apart from each other along the longitudinal direction of the sensing optical fiber, and may further include a protection unit installed between the fixing brackets to protect the sensing optical fiber.

The protection unit is each fixed at both ends to the adjacent fixing brackets, and includes a plurality of protection wires arranged radially around the sensing optical fiber.

In addition, the present invention includes a mobile body installed to be movable along the protection wire, and a plurality of devices installed on the mobile body so that the end is in contact with the surface of the sensing optical fiber to remove foreign substances stuck to the surface of the sensing optical fiber. It is further provided with a brush and a main body moving part that moves the moving main body along the protection wire.

The power generation facility monitoring system using an optical cable according to the present invention uses sensing optical fibers installed in the power generation facility, allowing workers to more easily recognize whether a defect has occurred in the power generation facility from a distance, thereby reducing the time and manpower required for inspection work. There is an advantage to being able to do it.

1 is a conceptual diagram of a power generation facility monitoring system using optical cables according to the present invention;
Figure 2 is a perspective view of a power generation facility monitoring system using optical cables according to another embodiment of the present invention;
Figure 3 is a cross-sectional view of the power generation facility monitoring system using the optical cable of Figure 2;
Figure 4 is a perspective view of a power generation facility monitoring system using optical cables according to another embodiment of the present invention;
Figure 5 is a perspective view of a power generation facility monitoring system using optical cables according to another embodiment of the present invention;
Figure 6 is a cross-sectional view of a power generation facility monitoring system using optical cables according to another embodiment of the present invention.

Hereinafter, a power generation facility monitoring system using an optical cable according to an embodiment of the present invention will be described in detail with reference to the attached drawings. Since the present invention can be subject to various changes and can have various forms, specific embodiments will be illustrated in the drawings and described in detail in the text. However, this is not intended to limit the present invention to a specific disclosed form, and should be understood to include all changes, equivalents, and substitutes included in the spirit and technical scope of the present invention. While describing each drawing, similar reference numerals are used for similar components. In the attached drawings, the dimensions of the structures are enlarged from the actual size for clarity of the present invention.

Terms such as first, second, etc. may be used to describe various components, but the components should not be limited by the terms. The above terms are used only for the purpose of distinguishing one component from another. For example, a first component may be named a second component, and similarly, the second component may also be named a first component without departing from the scope of the present invention.

The terms used in this application are only used to describe specific embodiments and are not intended to limit the invention. Singular expressions include plural expressions unless the context clearly dictates otherwise. In this application, terms such as “comprise” or “have” are intended to designate the presence of features, numbers, steps, operations, components, parts, or combinations thereof described in the specification, but are not intended to indicate the presence of one or more other features. It should be understood that this does not exclude in advance the possibility of the existence or addition of elements, numbers, steps, operations, components, parts, or combinations thereof.

Unless otherwise defined, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by a person of ordinary skill in the technical field to which the present invention pertains. Terms defined in commonly used dictionaries should be interpreted as having a meaning consistent with the meaning in the context of the related technology, and unless explicitly defined in the present application, should not be interpreted in an ideal or excessively formal sense. No.

Figure 1 shows a power generation facility monitoring system 100 using an optical cable according to the present invention.

Referring to the drawing, the power generation facility monitoring system 100 using the optical cable transmits light to the sensing optical fiber 110 installed in the power generation facility 11, and the sensing optical fiber 110. It is provided with a measurement unit 120 that receives scattered light output from and calculates a detection physical quantity for the power generation facility 11 based on the received scattered light. Here, the power generation facility 11 is a power plant facility such as a silo, a thermal fluid delivery pipe, etc.

The sensing optical fiber 110 extends a predetermined length in the longitudinal direction along the outer peripheral surface of the power generation facility 11. Since the sensing optical fiber 110 is an optical fiber commonly used in the related art in a distributed optical fiber sensor, a detailed description thereof will be omitted. A distributed optical fiber sensor is a scattering sensor that enables long-distance sensing by using a pulse light source to measure backscattered light inside the optical fiber according to the physical quantity acting on the optical fiber. Such distributed optical fiber sensors include Rayleigh scattering optical fiber sensors, Raman scattering optical fiber sensors, and Brilluouin scattering optical fiber sensors.

Meanwhile, although not shown in the drawing, the sensing optical fiber 110 may be installed to surround the outer peripheral surface of the power generation facility 11. Here, the sensing optical fiber 110 is preferably installed in a relatively wide area of the power generation facility 11. Additionally, one or three or more sensing optical fibers 110 may be installed depending on the size of the power generation facility 11 to be installed.

The measurement unit 120 transmits light to the sensing optical fiber 110, receives scattered light output from the sensing optical fiber 110, and calculates the detection physical quantity of the power generation facility 11 based on the received scattered light to detect the power generation facility 11. To determine whether a defect has occurred in (11), it is provided with a light source 121, an optical splitter 122, a calculation unit 123, and a determination unit 124.

The light source 121 is connected to the sensing optical fiber 110 and radiates pulsed light to the sensing optical fiber 110. Here, the light source, although not shown in the drawing, includes a pulse generator and emits pulse light, which is light corresponding to the pulse driving signal output from the pulse generator. The pulse generator is controlled by the calculation unit 123 and outputs a pulse driving signal corresponding to the pulse width of the pulse light to be generated to the light source 121.

The optical splitter 122 is equipped with a circulator and transmits the input light emitted from the light source 121 to the sensing optical fiber 110, and directs the light reflected from the sensing optical fiber 110 to a path different from the light incident path. Print out. In addition, of course, an optical fiber coupler (not shown) can be used as the optical splitter 122 instead of a circulator.

The calculation unit 123 controls the pulse generator to output pulsed light from the light source 121, detects the light output from the sensing optical fiber 110, and generates a power generation facility ( Calculate data on the detected physical quantity in 11). Here, the detected physical quantities include vibration, applied external force, degree of deformation, temperature, etc. It is preferable that a plurality of light sources 121, optical splitters 122, and calculation units 123 configured as described above are provided and installed respectively on the sensing optical fibers 110 installed in the power generation facility 11.

The determination unit 124 determines whether a defect has occurred in the power generation facility 11 based on the detected physical quantity of the power generation facility 11 measured through the calculation unit 123. That is, if the detected physical quantity of the power generation facility 11 calculated through the calculation unit 123 is greater than or equal to a preset value, the determination unit 124 determines that a defect such as a crack, bending, etc. has occurred and sends the calculation unit ( Fault occurrence information is transmitted along with the displacement information provided in 123).

The power generation facility monitoring system 100 using an optical cable according to the present invention configured as described above uses the sensing optical fiber 110 installed in the power generation facility 11 so that workers can more easily detect defects in the power generation facility 11 from a distance. The advantage is that the time and manpower required for inspection work can be reduced because the occurrence can be recognized.

Meanwhile, Figures 2 and 3 show a power generation facility monitoring system 200 using an optical cable according to another embodiment of the present invention.

Elements that perform the same function as those in the previously shown drawings are denoted by the same reference numerals.

Referring to the drawing, the power generation facility monitoring system 200 using the optical cable further includes an adhesion unit 210 installed in the power generation facility 11 to bring the sensing optical fiber 110 into close contact with the power generation facility 11. Equipped with

The adhesion unit 210 is installed on a plurality of fixing brackets 220 installed in the power generation facility 11 to be spaced apart from each other along the longitudinal direction of the sensing optical fiber 110, and is installed on the fixing brackets 220 to secure the sensing optical fiber. (110) is provided with a pressurizing portion (230) that is brought into close contact with the surface of the power generation facility (11).

One side of the fixing bracket 220 is fixed to the power generation facility 11, and an installation hole 221 is formed so that the corresponding sensing optical fiber 110 can pass through. Here, the installation hole 221 is preferably formed to penetrate in the front-back direction. In addition, the fixing bracket 220 is placed on one side opposite to the surface of the power generation facility 11 so that the sensing optical fiber 110 penetrating the installation hole 221 is in contact with the surface of the power generation facility 11, A cut portion 222 is formed along the longitudinal direction. The cut portion 222 has a predetermined width and extends in the front-back direction.

Depending on the size of the sensing optical fiber 110, the above-described fixing bracket 220 may be installed one by one or a plurality of fixing brackets 220 may be installed spaced apart from each other along the longitudinal direction of the corresponding sensing optical fiber 110.

The pressing portion 230 is capable of advancing and retracting toward the cut portion 222 on the inner surface of the fixing bracket 220 opposite the cut portion 222 so that its end can contact the outer peripheral surface of the sensing optical fiber 110. It is provided with a pressure rod 231 installed in a suitable manner and an elastic member 232 that provides elastic force to the pressure rod 231 so that the pressure rod 231 moves toward the cut portion 222.

The pressure rod 231 is installed on the other side of the fixing bracket 220 with one end retracted into the installation hole 221. At this time, as described above, the pressure rod 231 is installed so that one end can slide in a direction adjacent to the cut portion 222. A gripping member 233 is installed on the other end of the pressure rod 231 so that the operator can manipulate it by gripping it.

Meanwhile, the pressure rod 231 has a contact member 234 formed at one end that contacts the outer peripheral surface of the sensing optical fiber 110. The contact member 234 is formed to be curved to correspond to the curvature of the outer peripheral surface of the sensing optical fiber 110.

One end of the elastic member 232 is in contact with the contact member 234, and the other end is supported on the inner wall of the fixing bracket 220 to provide elastic force to move one end of the pressurizing rod 231 toward the sensing optical fiber 110. do. The elastic member 232 is a coil spring, but is not limited to this, and any elastic force providing means capable of providing elastic force to the pressurizing rod 231 can be applied.

Meanwhile, the pressing unit 230 is located on the outer peripheral surface of the sensing optical fiber 110 opposite to the pressing rod 231 in order to prevent the sensing optical fiber 110 from being deformed by the end of the pressing rod 231. It is further provided with a protective cover 240 formed to surround it.

The protective cover 240 has an insertion hole 241 formed so that the sensing optical fiber 110 can be inserted therethrough. Meanwhile, the protective cover 240 is formed so that the corresponding sensing optical fiber 110 is in contact with the surface of the power generation facility 11, and the portion opposite to the cut portion 222 is cut in the longitudinal direction. Here, the protective cover 240 is preferably formed so that the cut portion has a width and length corresponding to the width and length of the cut portion 222 of the fixing bracket 220. In addition, the protective cover 240 is preferably made of a hard material such as metal to prevent the sensing optical fiber 110 from being deformed by the pressure rod 231.

Meanwhile, the protective cover 240, although not shown in the drawing, supports the sensing optical fiber 110 spaced apart from the inner wall surface to provide a flow space for air to flow between the inner wall surface and the sensing optical fiber 110. A number of supporting protrusions are formed to allow for this. The support protrusions are preferably formed to protrude toward the center of the insertion hole 241 at positions spaced apart from each other on the inner wall of the protective cover 240. Since the sensing optical fiber 110 is supported at a distance from the inner wall of the protective cover 240 by the support protrusion, the protective cover 240 is prevented from being adhered to the sensing optical fiber 110, and the protective cover 240 and Even if rainwater flows between the sensing optical fibers 110, it is easily dried, thereby preventing errors in the measurement values of the sensing optical fibers 110 due to moisture.

The pressing parts 230 configured as described above are provided to be spaced apart from each other along the longitudinal direction of the sensing optical fiber 110 and bring the corresponding sensing optical fiber 110 into close contact with the power generation facility 11, so that the power generation facility using the sensing optical fiber 110 The accuracy of measuring defects in (11) can be improved.

Meanwhile, Figure 4 shows a power generation facility monitoring system 300 using an optical cable according to another embodiment of the present invention.

Referring to the drawing, the power generation facility monitoring system 300 using the optical cable further includes a protection unit 310 installed between the fixing brackets 220 to protect the sensing optical fiber 110.

The protection unit 310 includes a plurality of protection wires 311, both ends of which are respectively fixed to the fixing brackets 220 adjacent to each other. The protection wire 311 extends a predetermined distance along the longitudinal direction of the sensing optical fiber 110, and both ends are fixed to the fixing brackets 220, respectively. At this time, the protective wires 311 are preferably arranged radially around the sensing optical fiber 110.

When an obstacle approaches the sensing optical fiber 110, the obstacle comes into contact with the protection wires 311, and the protection wires 311 prevent the obstacle from colliding with the sensing optical fiber 110. The protection unit 310 configured as described above can prevent the sensing optical fiber 110 from being damaged or deformed by external obstacles other than the power generation facility 11 by using a plurality of protection wires 311.

Meanwhile, Figure 5 shows a power generation facility monitoring system 400 using an optical cable according to another embodiment of the present invention.

Referring to the drawing, the power generation facility monitoring system 400 using the optical cable further includes a cleaning unit 410 that moves along the protection wire 311 to clean the sensing optical fiber 110.

The cleaning unit 410 includes a mobile body 420 movably installed along the protection wire 311, and an end portion of the sensing optical fiber (110) to remove foreign substances attached to the surface of the sensing optical fiber 110. It is provided with a plurality of brushes 430 installed on the moving body 420 so as to contact the surface of the movable body 420, and a body moving part 440 that moves the moving body 420 along the protection wire 311. .

The mobile body 420 is formed with a plurality of penetration holes 421 through which the protection wire 311 can pass. The through hole 421 is preferably formed to penetrate the moving body 420 at a position corresponding to each protection wire 311 along the longitudinal direction of the sensing optical fiber 110. In addition, the mobile body 420 has a passage hole 422 formed to allow the sensing optical fiber 110 to pass through. Here, the passage port 422 is preferably formed so that the side opposite to the power generation facility 11 is open.

A plurality of brushes 430 are formed on the inner wall of the passage hole 422, and their ends protrude so as to contact the outer peripheral surface of the sensing optical fiber 110. The brush 430 is preferably made of a material that is flexible and has a certain amount of elasticity so that it can be easily bent when in contact with the sensing optical fiber 110.

The main body moving unit 440 includes a plurality of wheels 441 rotatably installed on the moving main body 420 so that the outer peripheral surface is in contact with the outer peripheral surface of the power generation facility 11, and a rotation motor (not shown) that rotates the wheels 441. Poetry) is provided. Meanwhile, the main body moving part 440 is not limited to this, but is a driving means that can move the moving main body 420 along the longitudinal direction of the protection wire 311, so it can be applied to anything.

As described above, the cleaning unit 410 moves the mobile body 420 equipped with the brush 430 along the protection wire 311 to remove foreign substances stuck to the sensing optical fiber 110, so that the weight of the foreign substances It is possible to prevent errors from occurring in measurement values measured through the sensing optical fiber 110.

Meanwhile, Figure 6 shows a pressing unit 510 according to another embodiment of the present invention.

Referring to the drawing, the pressing unit 510 includes a plurality of auxiliary arms 511 extending from the protective cover 240, and is installed at the end of the auxiliary arm 511 to secure the auxiliary arm 511 to the fixing bracket. It is provided with a fixing block 512 that is fixed to the power generation facility 11 at a position spaced apart from 220.

Here, the fixing bracket 220 has a plurality of through slots 223 formed at a position opposite to the protective cover 240. The through slots 223 are formed on the left and right sides of the fixing bracket 220, respectively, and extend a predetermined length along the longitudinal direction of the sensing optical fiber 110. Additionally, the through slot 223 may be formed to have a predetermined width in the front-to-back direction.

The auxiliary arm 511 is formed on the outer peripheral surface of the protective cover 240 opposite the through slot 223, and extends the length of the sensing optical fiber 110 to protrude out of the fixing bracket 220 through the through slot 223. It extends in a direction that intersects the direction. Additionally, the auxiliary arm 511 is preferably made of a hard material such as metal with a certain strength.

The fixing block 512 is installed at the end of the auxiliary arm 511 exposed to the outside of the fixing bracket 220 and is fixed to the outer peripheral surface of the power generation facility 11. Although the fixing block 512 is not shown in the drawing, it is fixed to the surface of the power generation facility 11 by welding or bolting.

As described above, the auxiliary arm 511 is fixed to the power generation facility 11 at a position away from the sensing optical fiber 110 by the fixing block 512, and is made of a hard material, so it is fixed to the corresponding position by the auxiliary arm 511. Displacement generated in the power generation facility 11 may be transmitted to the sensing optical fiber 110. Therefore, there is an advantage that the measurable range of the sensing optical fiber 110 is expanded.

The description of the presented embodiments is provided to enable any person skilled in the art to use or practice the present invention. Various modifications to these embodiments will be apparent to those skilled in the art, and the general principles defined herein may be applied to other embodiments without departing from the scope of the invention. Thus, the present invention is not limited to the embodiments presented herein, but is to be construed in the broadest scope consistent with the principles and novel features presented herein.

100: Power generation facility monitoring system using optical cables
110: sensing optical fiber
120: Measuring unit
121: light source
122: Optical splitter
123; calculation department
124: Determination unit

Claims (9)

At least one sensing optical fiber installed in a power generation facility;
a measurement unit that transmits light to the sensing optical fiber, receives scattered light output from the sensing optical fiber, and calculates a detection physical quantity for the power generation facility based on the received scattered light; and
It is further provided with a contact unit installed at the power generation facility to bring the sensing optical fiber into close contact with the power generation facility,
The adhesion unit is
Installed in the power generation facility to be spaced apart from each other along the longitudinal direction of the sensing optical fiber, an installation hole is formed so that the sensing optical fiber can pass through, and the sensing optical fiber penetrating the installation hole is in contact with the surface of the power generation facility. At least one fixing bracket having a cut portion cut along the longitudinal direction on the side opposite to the surface of the power generation facility; and
a pressurizing unit installed on the fixing bracket to press the sensing optical fiber so that the sensing optical fiber is brought into close contact with the surface of the power generation facility through the cut portion;
The pressurizing part is
a pressure rod installed on the inner surface of the fixing bracket opposite the cut portion so that an end can contact the outer peripheral surface of the sensing optical fiber so as to be able to advance and retreat toward the cut portion;
an elastic member that provides elastic force to the pressing rod so that the pressing rod moves toward the cut portion;
In order to prevent the sensing optical fiber from being deformed by the end of the pressure rod, it is formed to surround the outer circumferential surface of the sensing optical fiber facing the pressure rod, and is made of a hard material, and the sensing optical fiber is made of a hard material and is not connected to the surface of the power generation facility. A protective cover is provided with a portion opposite to the cut portion cut in the longitudinal direction so as to contact the
The fixing bracket has a through slot formed at a position opposite the protective cover,
The pressurizing part is
an auxiliary arm formed of a hard material and extending from the protective cover in a direction intersecting the longitudinal direction of the sensing optical fiber to protrude outside the fixing bracket through the through slot; and
Further comprising: a fixing block installed at an end of the auxiliary arm to secure the auxiliary arm to the power generation facility at a position spaced apart from the fixing bracket,
Power generation facility monitoring system using optical cables.
delete delete delete delete delete delete delete At least one sensing optical fiber installed in a power generation facility;
a measurement unit that transmits light to the sensing optical fiber, receives scattered light output from the sensing optical fiber, and calculates a detection physical quantity for the power generation facility based on the received scattered light; and
an adhesion unit installed at the power generation facility to bring the sensing optical fiber into close contact with the power generation facility,
The adhesion unit is
Installed in the power generation facility to be spaced apart from each other along the longitudinal direction of the sensing optical fiber, an installation hole is formed so that the sensing optical fiber can pass through, and the sensing optical fiber penetrating the installation hole is in contact with the surface of the power generation facility. At least one fixing bracket having a cut portion cut along the longitudinal direction on the side opposite to the surface of the power generation facility; and
a pressurizing unit installed on the fixing bracket to press the sensing optical fiber so that the sensing optical fiber is brought into close contact with the surface of the power generation facility through the cut portion;
A plurality of the fixing brackets are installed to be spaced apart from each other along the longitudinal direction of the sensing optical fiber,
A protection unit installed between the fixing brackets to protect the sensing optical fiber,
The protection unit is each fixed at both ends to the adjacent fixing brackets and has a plurality of protection wires arranged radially around the sensing optical fiber,
A mobile body installed to be movable along the protection wire;
A plurality of brushes installed on the moving body so that their ends are in contact with the surface of the sensing optical fiber to remove foreign substances stuck to the surface of the sensing optical fiber; and
Further comprising a main body moving part that moves the moving main body along the protection wire,
Power generation facility monitoring system using optical cables.

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