KR20170019979A - System, Method for Wall Thinning Management and Computer Readable Record Medium Thereof - Google Patents

Abstract

Disclosed are a pipe thinning management system, a method, and a computer readable recording medium thereof. The pipe thinning management system according to an embodiment of the present invention comprises: a pipe information receiving part receiving pipe design information; a pipe model generating part generating a pipe model corresponding to the received pipe design information; a pipe model analyzing part dividing the pipe model into a component, a segment including at least one component, or a line group including at least one segment; a thinning analyzing part performing a thinning analysis for the pipe model by considering a connection relation between segments and the pipe design information; and an analysis result output part outputting the result of the thinning analysis.

Description

TECHNICAL FIELD [0001] The present invention relates to a piping thinning management system, a piping thinning management system, a method, and a computer readable recording medium.

The present invention relates to a piping thinning management system, a method and a computer readable recording medium, and more particularly, to a piping thinning management system, a method, and a computer readable recording medium. More specifically, And a computer-readable recording medium.

Pipes used in nuclear power plants or general industrial facilities have a complex network, and it is important to interpret and manage pipe thinning phenomena. Wall-thinning refers to a phenomenon in which piping is thinned by corrosion in a power plant. It is not easy to analyze and manage the phenomenon of thinning due to the characteristics of piping having a complicated network.

Although the technology related to the complex network analysis has been proposed in various ways, the technique of recognizing the flow direction of the pipe for the piping thinning analysis and the piping network relationship and considering the factors affecting the thinning, It has not been developed.

Therefore, it is necessary to develop a system or method for grasping the connection relation of complex piping network, performing the thinning analysis, and providing the result of the thinning analysis to the user.

The present invention provides a piping thinning management system, a method, and a computer readable recording medium capable of performing a thinning analysis of a piping network by modeling a piping network in actuality in consideration of a fluid flow direction and grasping complicated piping connection relationships .

The piping system includes a piping information receiving unit for receiving piping design information, a piping model generating unit for generating a piping model corresponding to the received piping design information, A pipe model analyzing unit that divides the pipe model into a line group including segments or one or more segments including the components, a wall thinning analysis for the pipe model in consideration of the connection relationship between the segments and the pipe design information A thinning analysis section and an analysis result output section for outputting the results of the thinning analysis.

Also, the component includes an intuitive tube, an elbow, and a tee (T), and the pipe model analyzer can identify the segment based on the tee (T).

In addition, the piping model analyzing unit may check whether the piping model is connected or disconnected, and determine whether the piping model is suitable as the thinning analysis target.

Also, the thinning analysis unit analyzes characteristics of the component included in the segment, and the characteristics may include a diameter, a length, a flow, a head loss, a friction coefficient, a roughness, a shape, and connection information of the component.

In addition, the thinning analysis unit may sequentially perform a thermal hydraulic force analysis on the segment, and perform a thermal hydraulic force analysis, a hydrochemical analysis, and a reduction ratio analysis on the component.

In addition, the analysis result output unit may output a thinning analysis result including the thinning rate of the component, and display the component in a specific color corresponding to the thinning rate.

According to another aspect of the present invention, there is provided a piping thinning management method including a first step of receiving piping design information, a second step of generating a piping model corresponding to the piping design information received, A segment including at least one component or a line group including at least one segment; performing a wall thinning analysis on the pipeline model in consideration of a connection relationship between the segments and the piping design information; A fourth step and a fifth step of outputting the result of the thinning analysis.

In addition, the component may include an intuitive tube, an elbow, and a tee (T), and in the third step, the segment may be classified based on the tee (T).

In the third step, it is possible to determine whether the piping model is suitably used as the thinning analysis object by checking whether the piping model is connected or disconnected.

In the third step, the characteristic of the component included in the segment is analyzed, and the characteristic may include a diameter, a length, a flow, a head loss, a friction coefficient, a roughness, a shape, and connection information of the component.

The fourth step may include a segment analysis step for sequentially performing a thermal hydraulic force analysis on the segment and a component analysis step for performing a thermal hydraulic force analysis, a hydrochemical analysis, and a curvature rate analysis on the component .

In the fifth step, the thinning analysis result including the thinning rate of the component may be output, and the component may be displayed in a specific color corresponding to the thinning ratio.

Further, a computer-readable recording medium on which a program for executing the product information providing method according to the present invention is recorded can be provided.

Provided is a piping thinning management system, a method, and a computer readable recording medium capable of performing a thinning analysis of a piping network by modeling a piping network in actuality in consideration of a fluid flow direction and grasping complicated piping connection relationships .

1 is a view schematically showing a configuration of a piping thinning management system according to an embodiment of the present invention.
2 is a diagram illustrating a piping modeling process according to an embodiment of the present invention.
3 is a diagram illustrating a grouping process of a piping network according to the present invention.
FIG. 4 is a view illustrating an example of a result of thinning analysis according to the present invention. FIG.
FIG. 5 is a flowchart schematically showing a pipe thinning management method according to an embodiment of the present invention.
FIG. 6 is a flowchart schematically showing detailed steps of a thinning analysis step according to the present invention.

Brief Description of the Drawings The advantages and features of the present invention, and the manner of achieving them, will be apparent from and elucidated with reference to the embodiments described in conjunction with the accompanying drawings. It is to be understood, however, that the invention is not limited to the embodiments shown herein but may be embodied in many different forms and should not be construed as being limited to the preferred embodiments of the present invention. do. BRIEF DESCRIPTION OF THE DRAWINGS The above and other aspects of the present invention will become more apparent by describing in detail preferred embodiments thereof with reference to the attached drawings. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

The terminology used in this application is used only to describe a specific embodiment and is not intended to limit the invention. The singular presentation includes plural representations unless the context clearly dictates otherwise. In the present application, the terms "comprises", "having", and the like are used to specify that a feature, a number, a step, an operation, an element, a component, But do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, or combinations thereof. The terms first, second, etc. may be used to describe various elements, but the elements should not be limited by the terms. The terms are used only for the purpose of distinguishing one component from another.

1 is a view schematically showing a configuration of a piping thinning management system according to an embodiment of the present invention.

Referring to FIG. 1, a piping thinning management system 100 according to an embodiment of the present invention includes a piping information receiving unit 110, a piping model generating unit 120, a piping model analyzing unit 130, 140 and an analysis result output unit 150.

The piping information receiving unit 110 receives piping design information. The piping design information can be input by the external input device as the piping model generating unit 120 is basic information for generating any type of piping model. Here, the external input device may be an input device such as a keyboard, a mouse, and a touch pad, which can be connected to the pipeline information receiving unit 110 to transmit information.

The piping design information basically corresponds to a piping design drawing and means a design drawing of a pipe or piping network to be subjected to the thinning analysis using the system 100. [ The piping network may comprise a collection of a plurality of piping components (hereinafter, components), which may include an intuition, an elbow, and a tee (T).

The straight pipe refers to a straight pipe, and various specifications such as length and diameter may exist. An elbow is a component that is disposed in a region where a fluid flow direction such as a liquid or a gas flowing in a pipe varies. The elbow may have various lengths and diameters as well as an intrinsic pipe, and may have various degrees of fluid flow direction change. have. Tee T means a component in which a fluid flowing in different directions meets or is disposed at a point where a fluid flowing in the same direction through the same pipe path diverges in different directions. Therefore, T (T) may be expressed as a component with three directions in which the fluid flows. Tee (T) can also have various lengths and diameters, as well as straight tubes and elbows, and the angle at which the fluid diverges can also be varied.

In addition, the component may further include a valve and a nozzle, and may include various piping materials necessary for a piping network design other than the valve and the nozzle.

Meanwhile, the piping design information includes information on the characteristics of the components, which may include material, diameter, length, head loss, roughness, shape, and connection information of each of the components.

The piping model generating unit 120 generates a piping model corresponding to the piping design information received by the piping information receiving unit 110. [ The piping model may be a set of a plurality of components included in the piping design information, and may be generated as three-dimensional data through connection of components such as the intuition, elbow, and tee described above.

The piping model analysis unit 130 divides the piping model into components, segments, or line groups. A segment is a unit including one or more of the above components, and a line group is a unit including one or more segments and can be understood as the largest unit to be subjected to the thinning analysis.

A component is a piping component, as described above, that includes an intuitive, elbow, tee, valve, and nozzle. Segment refers to a set of components that are centered around the point at which thermal hydraulic conditions affecting thinning are changed. Thermal hydrodynamic conditions refer to the conditions that affect the conversion of heat energy and the flow of fluid, and the segments can be separated by tee. Fluid flowing along the piping can be a representative component that changes the thermal hydraulic condition because the flow changes greatly as it passes through the tee. A line group is a set of segments that becomes a series of groups to be subjected to a thinning analysis.

Meanwhile, the piping model analysis unit 130 may check whether the piping model is connected or disconnected. The fluid flow inside the pipe is determined according to the connection relationship of the pipe model. If there is a connection relationship in which the pipe model is circulated or a connection is disconnected between the input part and the output part of the fluid, the fluid in the pipe also circulates It can not flow.

The pipe model analyzing unit 130 can determine whether the pipe model is suitable as an object of thinning analysis according to a result of checking whether the pipe model is circulated or disconnected. For example, when the pipe model has circulation or disconnected sections, it can be determined that the piping model is unsuitable as an object of thinning analysis.

The thinning analysis unit 140 performs a wall thinning analysis on the pipe model in consideration of the connection relationship between the segments and the pipe design information. The thinning analysis unit 140 does not perform the thinning analysis on the pipe model when the pipe model analyzing unit 130 determines that the pipe model is unsuitable as the thinning analysis target.

On the other hand, if it is determined that the piping model is suitable for the thinning analysis in the pipe model analyzing unit 130, the thinning analysis unit 140 performs the thinning analysis on the corresponding pipe model. In the thinning analysis, the thinning analysis unit 140 primarily performs thinning analysis on the segments. Upon completion of the thinning analysis for the segment, thermal hydrodynamic analysis and hydrochemistry analysis are performed on the individual components included in the segment. When the thermal hydraulic analysis and the hydrochemical analysis are performed on the individual components, the analysis of the susceptibility of individual components is performed.

In order to analyze the susceptibility, thermal hydrodynamic analysis and hydrochemical analysis are required. Therefore, in order to analyze the susceptibility of the segment, thermal hydrodynamic analysis and hydrochemical analysis of the segment should be preceded.

Here, the thermal hydraulic analysis is an analysis of the thermal energy conversion and the fluid flow in the piping model, and analyzes the change of temperature, pressure and enthalpy according to the fluid flow. The hydrochemical analysis analyzes the pH change of the fluid flowing inside the piping model. The influences on the pipe thinning depend on the pH change of the fluid, and the rate of reduction is closely related to the material of the pipe.

In other words, the thinning analysis unit 140 performs a thinning analysis on a component after performing a thinning analysis on a segment, and each thinning analysis includes a thinning ratio analysis after a thermal hydraulic force analysis and a hydrochemical analysis.

The analysis result output unit 150 outputs the result of the thinning analysis in the thinning analysis unit 140. [ The analysis result is output to the output unit 150. Based on the pipe model generated by the pipe model generation unit 120, the analysis result of the components of the pipe model, Can be displayed.

As described above, the piping model can be generated as three-dimensional data, and each component can be represented in different colors corresponding to the rate of reduction. For example, a component with the highest rate of reduction may be represented as red, a component with the lowest rate of growth as purple, and a component with intermediate rate of growth may be represented as green.

The piping thinning management system 100 according to the present invention can be connected to the output device and the analysis result output unit 150 outputs information on the rate of reduction of the components constituting the piping model from the thinning analysis unit 140, . ≪ / RTI > The susceptibility can be expressed as mils / yrs, where mils means 10 ^-3 inch. And, mils / yrs is the thickness of the component that is decremented every year (year).

The user who uses the piping thinning management system 100 can refer to the thinning analysis result provided by the analysis result output unit 150 through the output device, that is, by referring to the thinning rate, the thinning of the piping and / Management can be performed.

The characteristic information of the piping model for performing the thermal hydraulic force analysis and the hydrochemical analysis in the thinning analysis unit 140 may be acquired by combining the characteristic information of each component received by the piping information receiving unit 110 . As described above, the characteristic information of the component may include material, aperture, length, head loss, roughness, shape, and connection information, and the characteristic information may include a boundary condition of the component and a boundary condition of the segment including one or more components It is important information for interpretation.

The boundary conditions are information about the temperature of the fluid, the pressure of the fluid and the enthalpy of the fluid, and it is possible to determine the characteristics of the fluid at the starting and ending points of the flow (fluid movement or fluid flow) .

The thinning analysis unit 140 may include an algorithm for performing thermal hydraulic force analysis and hydrochemical analysis on the pipe model. Thermal hydrodynamic analysis is generally used to find approximate solutions numerically by computer. Numerical methods can be classified into local thermal hydraulic analysis and system thermal hydraulic analysis according to the characteristics of thermal hydraulic analysis. Local thermal hydraulic analysis can be performed using commercial computer code. On the other hand, in order to perform hydro-thermal hydraulic analysis, a specific computer code can be developed and used in the pipe model to be analyzed.

Since the reduction rate analysis of the piping model in the piping thinning management system 100 according to the present invention is performed for each of the segments and the components, the thinning analysis unit 140 uses the above- Hydraulic analysis can be performed.

Meanwhile, the thinning analysis unit 140 may include a database for hydrochemistry analysis. The database stores data on an environment in which piping components constructed through experiments in various environments are damaged.

The thinning analysis unit 140 includes an algorithm and a database for performing a thermal hydraulic force analysis and a hydrochemical analysis so that an effect of automating the thermal hydraulic force analysis and the hydrochemical analysis of the pipe model generated by the pipeline model generation unit 120 Can be provided. Also, the thinning analysis unit 140 performs thinning analysis using the thermal hydraulic force analysis and the hydrochemical analysis result for the pipe model, and the analysis result is represented by the thinning rate, and the analysis result output unit 150 outputs the three- It is possible to more easily manage the thinning of the piping network.

2 is a diagram illustrating a piping modeling process according to an embodiment of the present invention.

1, the piping thinning management system 100 according to the present invention may be connected to an output device, and may include piping design information input through an external input device, piping design information based on the piping design information, The model can be displayed through the output device. Here, the output device may include any type of display device.

2, an area A1 for displaying the pipe design information received from the external input device, an area A2 for displaying the pipe model generated corresponding to the received pipe design information, a component of the generated pipe model, The area A3 for displaying the configuration relationship of the segment and the line group can constitute one large screen.

The area A1 is an area for displaying piping design information received by the piping information receiving unit 110 (refer to FIG. 1), and the area A2 is an area for displaying the piping design information received by the piping model generating unit 120 (see FIG. 1) It can be understood as an area for displaying the piping model. The region A3 can be understood as a region for displaying a database (not shown) for storing information on the configuration and / or the connection relation of the components of the piping model generated by the piping model generation unit 120. [

2 may be included in the pipe thinning management system 100 (see FIG. 1) according to an embodiment of the present invention, and the area A1 may include a keyboard and / or a mouse The piping design information may be input by an external input device.

In the area A1, a piping component type is displayed. Referring to FIG. 2, a component type, a piping size, and a piping schedule are displayed. The component types may include straight tubes, elbows, tees, valves, and nozzles as described with reference to FIG. 1, and the tubing size may refer to the length of each component. The piping schedule means the thickness of the component, and the thickness of the component can be understood as the difference between the outer diameter and the inner diameter.

In the area A2, a pipe model including at least one component is displayed. The component included in the pipe model may be selectable by the external input device. Among the components displayed in the area A2, the component selected by the external input device can be displayed in a manner (bold font, different color, etc.) distinguishable from other components in the area A3. On the other hand, among the components displayed on the list of the area A3, the component selected by the external input device may be displayed in a manner (different color, blinking, etc.) in which the component is distinguished from the other components in the area A2. If one component is selected in the area A2 or A3, the property of the selected component may be displayed in the area A1.

The information on the plurality of components included in the piping design information may be received in order according to the flow direction of the fluid, and the information on the currently received component may include information on the previously received component . That is, the information of the currently received component is borrowed from the information of the previously received component, unless the user using the system 100 separately intervenes. For example, if the previously received component has the length l, If the currently received component is also a straight pipe, it can be set to be carbon steel of the same diameter (r).

3 is a diagram illustrating a grouping process of a piping network according to the present invention.

As described with reference to FIG. 1, the pipeline model analysis unit 130 divides the pipeline model into components, segments, or line groups. Fig. 3 shows one line group, and the line group includes segments 1 to 5. And, each segment includes at least one or more components.

For example, Segment 1 contains six components, which consist of five intuitive lines and one elbow. Segment 2 consists of four straight tubes and one elbow. Segment 3 consists of six tubes and one elbow. Segment 4 consists of one tube. Segment 5 consists of two tubes. The elbows of segment 1 through segment 3 serve to connect the intuition to the intuition.

3, segment 1, segment 2, and segment 4 are connected via Te at the Pm point, and Segments 3 to 5 are connected via Te at the Pn point. That is, one segment and the other segment are separated by a tee.

One segment may include at least one component, and one line group may include at least one input (or input) and at least one output (or output). The input means the point where the flow of the fluid starts, and the output means the point where the flow of the fluid ends. It can be understood that the attracting flow along the pipe model flows from the input section toward the output section. The line group shown in FIG. 3 has three input units (Pin, 1, Pin, 2, Pin, 3) and one output unit (Pout, 4).

When one pipe model is generated in the pipe model generation unit 120, the pipe model analysis unit 130 determines the pipe model as one line group and divides the line group into one or more segments based on the Ti. The piping model analysis unit 130 divides the segment segment into components such as an intuition and an elbow.

The thinning analysis unit 140 performs thinning analysis on the segments classified by the piping model analysis unit 130. The thinning analysis includes thermal hydraulic analysis and hydrochemical analysis, and it is possible to perform the thinning analysis after performing the thermal hydraulic force analysis and the water chemical analysis on the segment.

One line group includes boundary conditions at the input and boundary conditions at the output. The boundary condition of the line group may be substantially the same as the boundary condition of the component constituting the input unit of the line group and the boundary condition of the component constituting the output unit of the line group. Here, the boundary condition means a condition including the temperature, pressure, and enthalpy of the fluid at the input unit and the output unit.

The segments are distinguished from other segments based on the Ti, and the boundary conditions of the segments can be determined according to the boundary conditions of the components constituting one segment. The thinning analysis unit 140 uses the boundary condition to perform the thermal hydrodynamic analysis and the hydrochemical analysis on the segment, and uses the thermal hydraulic force analysis result and the water chemical analysis result performed using the boundary condition to calculate the thinning Perform analysis.

Upon completion of the thinning analysis for the segments, the thinning analysis unit 140 performs thinning analysis for each component. The thinning analysis for a component includes thermal hydraulic analysis and hydrochemical analysis, as well as the thinning analysis for the segment.

The results of the thinning analysis can be expressed in terms of the thinning rate, and the results of the thinning analysis are provided in the analysis result output unit 150.

FIG. 4 is a view illustrating an example of a result of thinning analysis according to the present invention. FIG.

The analysis result output unit 150 outputs the results of the thinning analysis for the pipe model, and the results of the thinning analysis are expressed by the rate of the respective components. And, each component can be expressed in different colors according to the impression rate. The unit of deposition rate is expressed in mils / yrs, where mils means 10 ^-3 inch. And, mils / yrs is the thickness of the component that is decremented every year (year).

Referring to FIG. 4, the colors from purple to red represent the corresponding growth rates, purple represents the lowest growth rate, and red represents the highest growth rate. It can be seen that the green and the green color show a moderate growth rate.

The color shown in Fig. 4 is merely an example, and the coloring rate is not necessarily expressed by the color shown in Fig.

Referring to the piping model of FIG. 4, it can be seen that the reduction rate is high in the elbow and tee, and the rate of reduction is the highest in the tee, which can be interpreted as the flow of the fluid changes in the elbow and tee. It can be understood that the elongation direction is changed in the elbow, and the pressure due to the fluid may be high at the point where the direction changes. In addition, it can be understood that the fluid flow can be branched or aggregated in the tee, so that the pressure of the fluid changes most greatly, and the rate of precipitation also becomes maximum.

Using the results of the thinning analysis in Fig. 4, it is possible to predict the life of the piping network in a certain piping model. Then, referring to the thickness of each component constituting the piping network and the depressurization rate of FIG. 4, the current thickness of each component may be predicted.

For a specific component that exhibits a high level of susceptibility, it is possible to apply a management method that shortens the inspection period and can perform more careful and precise inspection and management than other components.

FIG. 5 is a flowchart schematically showing a pipe thinning management method according to an embodiment of the present invention.

The method includes a first step (S10) of receiving piping design information, a second step (S20) of generating a piping model corresponding to the piping design information received, A third step (S30) of classifying a model, a segment including at least one component, or a line group including at least one segment, a step (S30) for reducing a thickness of the pipe model by considering a connection relation between the segments and the pipe design information a fourth step (S40) of performing wall thinning analysis and a fifth step (S50) of outputting the result of the thinning analysis.

The piping design information is information for constructing a piping network or a piping model to be subjected to the thinning analysis, and it can be understood that it basically corresponds to the piping design drawing. The piping network or piping model may be formed of a plurality of piping components (hereinafter, referred to as components), and the components may include an intuition, an elbow, and a tee (T). Also, the piping design information can be input through an input device such as a keyboard, a mouse, and / or a touch pad.

And, the piping design information includes information on the characteristics of the components, which may include the material, diameter, length, head loss, roughness, shape, and connection information of each of the components. The pipe design information received in the first step S10 may be sequentially received according to the flow direction of the fluid. The information on the pipe design information or the components received earlier may be transmitted to the pipe design information or component It can be used as information. For example, if the previously received component is intuitive and the next received component is intuitive, then the characteristics of the later received component may have the characteristics of the previously received component intact, unless a special signal is received externally, for example.

In the second step S20, a piping model is generated using one or more components, and the piping model can be generated as three-dimensional data.

In the third step S30, the pipe model generated in the second step S20 is divided into one segment and another segment based on the T (T). In the tee (T), since the flow direction and pressure of the fluid change greatly, it can be a segmentation criterion of the segment. Here, a segment can be understood as a component of a piping model including one or more components, and a segment can be a component forming one line group.

In the third step S30, the segment is divided based on the T (T), and the divided segment is further divided into one or more components.

In the third step S30, it is determined whether the pipe model is connected or disconnected and whether the pipe model is suitable for the thinning analysis. If it is determined that the pipe model is not suitable as an object of the thinning analysis, the thinning analysis ends at the third step S30.

Here, the connection circulation means that the input and output portions of the fluid are the same in one component or one segment. In this case, since it can be understood that there is no component in which the fluid flows in and flows out, it is a condition that the thinning analysis can not be performed. The disconnection means that there is a section where the flow of the fluid from the input section to the output section specified in one piping model is disconnected.

In the fourth step S40, the thinning analysis is performed on the segments classified in the third step S30. The analysis of thinning involves thermal and hydrochemical analysis, where the thermal hydraulic analysis is the interpretation of the thermal energy conversion and fluid flow in the piping model, which analyzes the changes in temperature, pressure and enthalpy do. The hydrochemical analysis analyzes the pH change of the fluid flowing inside the piping model. The influences on the pipe thinning depend on the pH change of the fluid, and the rate of reduction is closely related to the material of the pipe.

In the fourth step S40, when the thermal hydraulic force analysis and the hydrochemical analysis are completed for the piping model, the piping model is subjected to the thinning analysis, and the result of the thinning analysis can be expressed as the thinning rate.

In the fifth step S50, a thinning analysis result including the thinning rate of components included in the piping model may be output, and the component may be displayed in a specific color corresponding to the thinning rate.

The result of the thinning analysis output in the fifth step S50 can be expressed as shown in FIG. 4, and the unit of the thinning rate is expressed as mils / yrs, where mils means 10 ^-3 inch.

FIG. 6 is a flowchart schematically showing detailed steps of a thinning analysis step according to the present invention.

Referring to FIG. 6, the thinning analysis step includes a segment analysis step (S41) and a component analysis step (S42). The segment interpretation step (S41) performs thermal hydrodynamic analysis, hydrochemical analysis, and susceptibility analysis for the segment. In the component analysis step (S42), a thermal hydraulic force analysis, a hydrochemical analysis, and a susceptibility analysis are performed on the component.

In order to perform the descent rate analysis for a segment or a component, thermal hydrodynamic analysis and hydrochemical analysis for the segment or component should be preceded. In addition, by analyzing the growth rate of the segments before analyzing the growth rate of the target component, the influence of the fluid flowing in different directions in the segment forming one line group can be analyzed first.

Meanwhile, the present invention can be embodied in computer readable code on a computer readable recording medium. A computer-readable recording medium includes all kinds of recording apparatuses in which data that can be read by a computer system is stored.

Examples of the computer-readable recording medium include a ROM, a RAM, a CD-ROM, a magnetic tape, a floppy disk, an optical data storage device and the like, and also implemented in the form of a carrier wave (for example, transmission via the Internet) .

In addition, the computer-readable recording medium may be distributed over network-connected computer systems so that computer readable codes can be stored and executed in a distributed manner. In addition, functional programs, codes, and code segments for implementing the present invention can be easily deduced by programmers skilled in the art to which the present invention belongs.

Unless there is explicitly stated or contrary to the description of the steps constituting the method according to the invention, the steps may be carried out in any suitable order. The present invention is not necessarily limited to the order of description of the above steps. The use of all examples or exemplary language (e.g., etc.) in this invention is for the purpose of describing the present invention only in detail and is not intended to be limited by the scope of the claims, But is not limited thereto. It will also be appreciated by those skilled in the art that various modifications, combinations, and alterations may be made depending on design criteria and factors within the scope of the appended claims or equivalents thereof.

Accordingly, the spirit of the present invention should not be construed as being limited to the above-described embodiments, and all ranges that are equivalent to or equivalent to the claims of the present invention as well as the claims Category.

100: piping thinning management system 110: piping information reception unit
120: piping model generation unit 130: piping model analysis unit
140: thinning analysis section 150: analysis result output section

Claims (13)

A piping information receiving unit for receiving piping design information;
A pipeline model generation unit for generating a pipeline model corresponding to the received pipeline design information;
A piping model analysis unit for dividing the piping model into a component group, a segment including at least one component, or a line group including at least one segment;
A thinning analysis unit for performing a thinning analysis on the pipe model in consideration of a connection relationship between the segments and the piping design information; And
An analysis result output unit for outputting a result of the thinning analysis;
Wherein the piping system comprises: The method according to claim 1,
The component includes an intuitive tube, an elbow, and a tee (T)
Wherein the pipe model analyzing unit classifies the segments based on the T (T). The method according to claim 1,
Wherein the pipe model analyzing unit examines whether the pipe model is connected or disconnected and determines whether the pipe model is suitable as the thinning analysis object. The method according to claim 1,
Wherein the thinning analysis unit analyzes characteristics of the component included in the segment,
Wherein the characteristics include a diameter, a length, a flow, a head loss, a friction coefficient, a roughness, a shape, and connection information of the component. The method according to claim 1,
Wherein the thinning analysis unit sequentially performs a thermal hydraulic force analysis on the segment and performs a thermal hydraulic force analysis, a hydrochemical analysis, and a reduction ratio analysis on the component. The method according to claim 1,
Wherein the analysis result output unit outputs a thinning analysis result including the thinning rate of the component, and displays the component in a specific color corresponding to the thinning rate. A first step of receiving piping design information;
A second step of generating a piping model corresponding to the received piping design information;
A third step of dividing the piping model into a component group, a segment including one or more components, or a line group including at least one segment;
A fourth step of performing a wall thinning analysis on the pipe model in consideration of a connection relationship between the segments and the piping design information; And
A fifth step of outputting a result of the thinning analysis;
Wherein the piping system comprises: 8. The method of claim 7,
The component includes an intuitive tube, an elbow, and a tee (T)
Wherein in the third step, the segments are classified based on the tee (T). 8. The method of claim 7,
Wherein the third step determines whether or not the pipe model is connected or disconnected and determines whether the pipe model is suitable as the thinning analysis object. 8. The method of claim 7,
In the third step, characteristics of the component included in the segment are analyzed,
Wherein the characteristics include a diameter, a length, a flow, a head loss, a friction coefficient, a roughness, a shape, and connection information of the component. 8. The method of claim 7,
The fourth step may be, sequentially,
A segment analysis step of performing thermal hydrodynamic analysis, hydrochemical analysis, and suspension rate analysis for the segment; And
A component analysis step for performing thermal hydrodynamic analysis, hydrochemical analysis, and reduction rate analysis for the component;
Wherein the piping system comprises: 8. The method of claim 7,
Wherein in the fifth step, the thinning analysis result including the thinning rate of the component is output, and the component is displayed in a specific color corresponding to the thinning rate. A computer-readable recording medium on which a program for executing the method according to any one of claims 7 to 12 is recorded.

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