阅读说明：本技术 一种基于断口分析的飞机结构破坏模式分析方法 (Fracture analysis-based airplane structure failure mode analysis method ) 是由 翟新康 田小幸 于 2020-12-29 设计创作，主要内容包括：本发明公开一种基于断口分析的飞机结构破坏模式分析方法,包括：对断裂结构件进行断口电镜扫描分析；通过测量断口相邻疲劳条带之间距离,获得裂纹扩展速率；按照断裂力学方法,计算出裂纹扩展方向上裂纹尖端应力强度因子；根据裂纹尖端应力强度因子推导出裂纹远端应力最大值；通过判断应力最大值是否超过全机疲劳有限元模型求解中相应部位的当量最大应力,从而判断断裂结构件的破坏模式是否属于正常疲劳破坏以外的破坏模式；上述飞机结构破坏模式分析方法采用的理论分析方法正确,工程概念明确,步骤清晰。本发明可用于判断该结构件破坏是否属于正常疲劳破坏以外的破坏模式。(The invention discloses an aircraft structure failure mode analysis method based on fracture analysis, which comprises the following steps: performing fracture electron microscope scanning analysis on the fractured structural part; obtaining the crack propagation rate by measuring the distance between adjacent fatigue strips of the fracture; calculating the stress intensity factor of the crack tip in the crack propagation direction according to a fracture mechanics method; deducing the maximum stress value of the far end of the crack according to the stress intensity factor of the tip of the crack; judging whether the failure mode of the fractured structural member belongs to failure modes except normal fatigue failure by judging whether the maximum stress value exceeds the equivalent maximum stress of the corresponding part in the full-machine fatigue finite element model solution; the aircraft structure failure mode analysis method adopts a correct theoretical analysis method, has clear engineering concept and clear steps. The method can be used for judging whether the structural part is damaged in a damage mode except normal fatigue damage.)

1. An aircraft structure failure mode analysis method based on fracture analysis is characterized by comprising the following steps:

performing fracture electron microscope scanning analysis on the fractured structural part;

obtaining the crack propagation rate by measuring the distance between adjacent fatigue strips of the fracture;

calculating the stress intensity factor of the crack tip in the crack propagation direction according to a fracture mechanics method;

deducing the maximum stress value of the far end of the crack according to the stress intensity factor of the tip of the crack;

and judging whether the failure mode of the fractured structural member belongs to failure modes except normal fatigue failure by judging whether the maximum stress value exceeds the equivalent maximum stress of the corresponding part in the solution of the full-machine fatigue finite element model.

2. The method for analyzing the structural failure mode of the airplane based on fracture analysis according to claim 1, wherein before performing fracture electron microscope scanning analysis on the fractured structural member, the method further comprises:

step 1, selecting and intercepting a fracture with a full fracture surface in a fractured structural part, and protecting the fracture;

and 2, establishing a coordinate identification line in the crack propagation direction on the back of the fracture, and marking off equant points for scanning the electron microscope on the coordinate identification line.

3. The method for analyzing the structural failure mode of the airplane based on fracture analysis as claimed in claim 2, wherein the step 2 comprises:

the method for establishing the identification line comprises the following steps: establishing a coordinate identification line in the crack propagation direction along the crack propagation direction by taking the corresponding position of the crack starting point on the back of the fracture as an origin;

the division mode of the equal division points is as follows: dividing the corresponding straight line length L of the crack starting point and the crack ending point on the back surface of the fracture into N equally spaced points.

4. The method for analyzing the structural failure mode of the airplane based on fracture analysis according to claim 3, wherein the fracture structural part is subjected to scanning analysis by a fracture electron microscope, and the method comprises the following steps:

and 3, performing electron microscope scanning analysis on the fractures selected in the step 1 at each equal division point established in the step 2 by adopting an electron microscope scanning instrument, and ensuring that each equal division point can clearly acquire a regular fatigue strip in the scanning process.

5. The method for analyzing structural failure modes of aircraft based on fracture analysis as claimed in claim 3, wherein the obtaining of the crack propagation rate by measuring the distance between adjacent fatigue strips of the fracture comprises:

step 41, analyzing the scanning result of the electron microscope obtained in the step 3 at each equally divided point, and measuring the distance between adjacent fatigue strips on the back surface of the fracture;

and 42, accurately calculating and obtaining the crack propagation rate da/dN of each equally divided point by adopting a method of measuring and averaging for multiple times and multiple positions.

6. The method for analyzing structural failure modes of aircraft based on fracture analysis as claimed in claim 5, wherein the calculating stress intensity factors of the crack tips in the crack propagation direction comprises:

step 5, calculating the stress intensity factor delta K of the crack tip at each equally divided point in the following way:

according to the formulaCalculating a stress intensity factor delta K of the crack tip at each equally divided point;

wherein C and n are material constants.

7. The method for analyzing structural failure modes of an aircraft based on fracture analysis of claim 6, wherein the deriving the maximum stress at the distal end of the crack comprises:

step 6, calculating the maximum value sigma of the stress at the far end of the crack at each aliquot point_maxCalculating the maximum value sigma of the crack distal stress at each aliquot point_maxThe method comprises the following steps:

wherein, beta is a comprehensive correction factor, R is a stress ratio, and R is sigma₁/σ₂，σ₁，σ₂In the solution of finite element model for fatigue of whole machineEquivalent minimum, maximum stress at this location.

8. The method for analyzing the structural failure mode of the airplane based on fracture analysis as claimed in claim 7, wherein the step of judging whether the failure mode of the fracture structural part belongs to failure other than normal fatigue failure comprises the following steps:

step 7, judging the maximum value sigma of the crack far-end stress obtained in the step 6_maxWhether the equivalent maximum stress sigma of the corresponding part in the solution of the full-machine fatigue finite element model is exceeded or not₂And if so, determining that the failure mode of the part belongs to failure modes other than normal fatigue failure.

Technical Field

The invention relates to the technical field of aviation fatigue fracture, in particular to an aircraft structure failure mode analysis method based on fracture analysis.

Background

During the flight of an aircraft, various possible fatigue cracks inevitably occur. When the general structural parts of the airplane have fatigue cracks, the general structural parts are usually repaired by adopting the conventional repair technology. However, when a critical part or a critical part of the aircraft structure has a crack, the crack is usually analyzed, the cause of the crack is identified, and then a repair plan is determined for repair.

When fracture analysis is carried out, the conventional analysis mode at present is to measure the distance between fracture fatigue strips, reversely estimate the crack propagation rate, estimate the fatigue life, and then compare the fatigue life with the design life of a structural part so as to judge whether the fatigue crack of the structural part belongs to abnormal damage.

However, the problems that the aircraft is loaded in the flight process is extremely complicated, the structural part is loaded in an expected range, the maximum load in a full-aircraft fatigue load spectrum is exceeded, and the structural part is subjected to large stress cannot be determined only by fracture analysis.

Disclosure of Invention

The purpose of the invention is: the embodiment of the invention provides an aircraft structure failure mode analysis method based on fracture analysis, which aims to solve the problem that whether the load of a structural part is in an expected range, whether the maximum load in a full-aircraft fatigue load spectrum is exceeded, whether the structural part bears larger stress and the like cannot be determined in the conventional fracture analysis mode.

The technical scheme of the invention is as follows: the embodiment of the invention provides an aircraft structure failure mode analysis method based on fracture analysis, which comprises the following steps:

performing fracture electron microscope scanning analysis on the fractured structural part;

obtaining the crack propagation rate by measuring the distance between adjacent fatigue strips of the fracture;

calculating the stress intensity factor of the crack tip in the crack propagation direction according to a fracture mechanics method;

deducing the maximum stress value of the far end of the crack according to the stress intensity factor of the tip of the crack;

and judging whether the failure mode of the fractured structural member belongs to failure modes except normal fatigue failure by judging whether the maximum stress value exceeds the equivalent maximum stress of the corresponding part in the solution of the full-machine fatigue finite element model.

Optionally, in the method for analyzing a failure mode of an aircraft structure based on fracture analysis as described above, before performing fracture electron microscope scanning analysis on a fractured structural member, the method further includes:

step 1, selecting and intercepting a fracture with a full fracture surface in a fractured structural part, and protecting the fracture;

and 2, establishing a coordinate identification line in the crack propagation direction on the back of the fracture, and marking off equant points for scanning the electron microscope on the coordinate identification line.

Optionally, in the method for analyzing structural failure modes of an aircraft based on fracture analysis as described above, the step 2 includes:

the method for establishing the identification line comprises the following steps: establishing a coordinate identification line in the crack propagation direction along the crack propagation direction by taking the corresponding position of the crack starting point on the back of the fracture as an origin;

the division mode of the equal division points is as follows: dividing the corresponding straight line length L of the crack starting point and the crack ending point on the back surface of the fracture into N equally spaced points.

Optionally, in the method for analyzing a failure mode of an aircraft structure based on fracture analysis as described above, performing fracture electron microscope scanning analysis on a fractured structural member includes:

and 3, performing electron microscope scanning analysis on the fractures selected in the step 1 at each equal division point established in the step 2 by adopting an electron microscope scanning instrument, and ensuring that each equal division point can clearly acquire a regular fatigue strip in the scanning process.

Optionally, in the method for analyzing structural failure mode of an aircraft based on fracture analysis as described above, the obtaining a crack propagation rate by measuring a distance between adjacent fatigue strips of the fracture includes:

step 41, analyzing the scanning result of the electron microscope obtained in the step 3 at each equally divided point, and measuring the distance between adjacent fatigue strips on the back surface of the fracture;

and 42, accurately calculating and obtaining the crack propagation rate da/dN of each equally divided point by adopting a method of measuring and averaging for multiple times and multiple positions.

Optionally, in the method for analyzing structural failure modes of an aircraft based on fracture analysis as described above, the calculating a stress intensity factor of a crack tip in a crack propagation direction includes:

step 5, calculating the stress intensity factor delta K of the crack tip at each equally divided point in the following way:

according to the formulaCalculating a stress intensity factor delta K of the crack tip at each equally divided point;

wherein C and n are material constants.

Optionally, in the method for analyzing structural failure modes of an aircraft based on fracture analysis as described above, the deriving a maximum stress value at a distal end of a crack includes:

step 6, calculating the maximum value sigma of the stress at the far end of the crack at each aliquot point_maxCalculating the maximum value sigma of the crack distal stress at each aliquot point_maxThe method comprises the following steps:

wherein, beta is a comprehensive correction factor, R is a stress ratio, and R is sigma₁/σ₂，σ₁，σ₂Respectively solving the equivalent minimum stress and the equivalent maximum stress of the part in the full-machine fatigue finite element model.

Optionally, in the method for analyzing a failure mode of an aircraft structure based on fracture analysis as described above, the determining whether the failure mode of the fractured structure belongs to a failure other than a normal fatigue failure includes:

step 7, judging the maximum value sigma of the crack far-end stress obtained in the step 6_maxWhether the equivalent maximum stress sigma of the corresponding part in the solution of the full-machine fatigue finite element model is exceeded or not₂And if so, determining that the failure mode of the part belongs to failure modes other than normal fatigue failure.

The invention has the advantages that:

the embodiment of the invention provides a fracture analysis-based airplane structure failure mode analysis method aiming at the problem that the failure mode is not easy to determine after a crack occurs in an airplane structure in flight, the method is based on fracture electron microscope scanning analysis on a fractured structure, the crack propagation rate is obtained by measuring the distance between fracture fatigue strips, the stress intensity factor value of the tip of the crack in the crack propagation direction is calculated according to a fracture mechanics method, the maximum value of the stress at the far end of the crack is reversely deduced, and therefore whether the structural part failure belongs to failure other than normal fatigue failure is judged by judging whether the stress maximum value exceeds the equivalent maximum stress of the part in the full-airplane fatigue finite element model solution. The theoretical analysis method adopted by the invention is correct, the engineering concept is clear, and the steps are clear. The method can be used for judging whether the structural part is damaged in a damage mode except normal fatigue damage.

Drawings

The accompanying drawings are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the example serve to explain the principles of the invention and not to limit the invention.

FIG. 1 is a flowchart of a method for analyzing structural failure modes of an aircraft based on fracture analysis according to an embodiment of the present invention;

FIG. 2 is a schematic illustration of a fracture fatigue strip in an embodiment of the invention;

FIG. 3 is a schematic diagram of a coordinate marking line established in an embodiment of the present invention;

FIG. 4 is a graphical representation of the crack, crack tip, distal end stresses in an embodiment of the invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, embodiments of the present invention will be described in detail below with reference to the accompanying drawings. It should be noted that the embodiments and features of the embodiments in the present application may be arbitrarily combined with each other without conflict.

The steps illustrated in the flow charts of the figures may be performed in a computer system such as a set of computer-executable instructions. Also, while a logical order is shown in the flow diagrams, in some cases, the steps shown or described may be performed in an order different than here.

According to the technical scheme provided by the embodiment of the invention, on the basis of carrying out fracture electron microscope scanning analysis on a fractured structural part, the crack propagation rate is obtained by measuring the distance between fracture fatigue strips, the stress intensity factor value of the crack tip in the crack propagation direction is calculated according to a fracture mechanics method, the maximum value of the stress at the far end of the crack tip is further reversely pushed out, and the aircraft structure failure mode analysis method based on fracture analysis is provided by judging whether the maximum value of the stress exceeds the equivalent maximum stress of the part in the whole aircraft fatigue finite element model solution.

The following specific embodiments of the present invention may be combined, and the same or similar concepts or processes may not be described in detail in some embodiments. The present invention will be described in further detail with reference to the accompanying drawings.

The embodiment of the invention provides an aircraft structure failure mode analysis method based on fracture analysis, which comprises the following steps:

performing fracture electron microscope scanning analysis on the fractured structural part;

obtaining the crack propagation rate by measuring the distance between adjacent fatigue strips of the fracture;

calculating the stress intensity factor of the crack tip in the crack propagation direction according to a fracture mechanics method;

deducing the maximum stress value of the far end of the crack according to the stress intensity factor of the tip of the crack;

and judging whether the failure mode of the fractured structural member belongs to failure modes except normal fatigue failure by judging whether the maximum stress value exceeds the equivalent maximum stress of the corresponding part in the solution of the full-machine fatigue finite element model.

The method for analyzing the structural failure mode of the airplane based on fracture analysis provided by the embodiment of the invention is based on fracture electron microscope scanning analysis, calculates the stress intensity factor value of the crack tip according to a fracture mechanics method, reversely deduces the maximum value of the far-end stress of the crack tip, and judges whether the value exceeds the equivalent maximum stress of the part in a full-machine fatigue finite element model, thereby solving various problems existing in the existing port analysis mode. The embodiment of the invention solves the problem that whether the load of the structural part is in an expected range, whether the maximum load in a full-machine fatigue load spectrum is exceeded, whether the structural part bears larger stress and the like cannot be determined by the conventional fracture analysis mode, thereby realizing the judgment of whether the structural part is damaged in a damage mode except normal fatigue damage.

Specific embodiments of the above steps will be described below. Fig. 1 is a flowchart of an aircraft structural failure mode analysis method based on fracture analysis, fig. 2 is a schematic diagram of a fracture fatigue strip in an embodiment of the present invention, where 1 in fig. 2 is a coordinate marking line of a crack propagation direction, 2 is a fatigue strip, and 3 is a distance between two adjacent fatigue strips.

Referring to fig. 1 and fig. 2, in the method according to the embodiment of the present invention, before performing the scanning analysis on the fracture structural member by using the electron microscope, the method may further include the following steps:

step one, selecting and intercepting a fracture with a full fracture surface in a fractured structural member, and protecting the fracture.

And secondly, establishing a coordinate identification line in the crack propagation direction on the back of the fracture, and marking off equant points for scanning the electron microscope on the coordinate identification line.

The way of the coordinate identification line established in this step is: establishing a coordinate identification line in the crack propagation direction along the crack propagation direction by taking the corresponding position of the crack starting point on the back of the fracture as an origin; fig. 3 is a schematic diagram of a coordinate marking line established in the embodiment of the present invention.

The dividing mode of the equal division points in the step is as follows: dividing the corresponding straight line length L of the crack starting point and the crack ending point on the back surface of the fracture into N equally spaced points.

In the method provided by the embodiment of the present invention, the implementation manner of performing scanning analysis on the fracture structural part by using a fracture electron microscope may include the following steps:

and step three, performing electron microscope scanning analysis on the fracture. The specific implementation mode of the step is as follows:

and (4) performing electron microscope scanning analysis on the fracture selected in the step one at each equal division point established in the step two, scanning by adopting an electron microscope scanning instrument, and ensuring that each equal division point can clearly obtain a regular fatigue strip in the scanning process.

In the method provided by the embodiment of the present invention, the implementation manner of obtaining the crack propagation rate by measuring the distance between the fracture adjacent fatigue strips may include the following steps:

and step four, measuring the distance between the fatigue strips and calculating the crack propagation rate da/dN at each aliquot point. The specific implementation mode of the step is as follows:

analyzing the scanning result of the electron microscope obtained in the third step at each equally divided point, and measuring the distance between adjacent fatigue strips on the back of the fracture; and accurately calculating and obtaining the crack propagation rate da/dN at each equally divided point by adopting a method of measuring and averaging for multiple times and multiple positions.

In the method provided by the embodiment of the present invention, the above-mentioned implementation manner of calculating the stress intensity factor of the crack tip in the crack propagation direction may include the following steps:

and step five, calculating the stress intensity factor delta K of the crack tip at each aliquot point. The calculation mode of the step is as follows:

according to the formula of paris,calculating to obtain a stress intensity factor delta K of the crack tip at each equally divided point;

wherein C and n are material constants.

In the method provided by the embodiment of the present invention, the above implementation manner of deriving the maximum value of the stress at the far end of the crack may include the following steps:

step six, calculating the maximum value sigma of the far-end stress of the crack at each equally divided point_max. The calculation mode of the step is as follows:

calculating the maximum value sigma of the stress at the far end of the crack at each equal division point according to the paris formula_maxComprises the following steps:

wherein, beta is a comprehensive correction factor, R is a stress ratio, and R is sigma₁/σ₂，σ₁，σ₂Respectively solving the equivalent minimum stress and the equivalent maximum stress of the part in the full-machine fatigue finite element model. Fig. 4 is a schematic diagram of the crack, crack tip, and distal end stresses in an embodiment of the invention.

In the method provided by an embodiment of the present invention, the determining whether the failure mode of the fractured structure belongs to a failure mode other than normal fatigue failure may include:

step seven, judging the maximum value sigma of the crack distal stress obtained in the step six_maxWhether the equivalent maximum stress sigma of the corresponding part in the solution of the full-machine fatigue finite element model is exceeded or not₂If the failure mode exceeds the predetermined failure mode, the failure mode at the portion is determined to belong to a failure mode other than normal fatigue failure.

DETAILED DESCRIPTION OF EMBODIMENT (S) OF INVENTION

The method for analyzing the structural failure mode of the aircraft based on fracture analysis provided by the embodiment of the invention is further described in detail in a certain specific embodiment.

Referring to fig. 1 and 2, this embodiment provides a method for analyzing structural failure modes of an aircraft based on fracture analysis, and the method is implemented as follows:

it is known that: the crack length is 275 μm, the crack propagation rate da/dN is 0.43 μm/n, and c is 1.059 × 10^-7，n＝3.32。

The method for analyzing the structural failure mode of the aircraft based on fracture analysis, provided by the specific embodiment, comprises the following steps:

step one, selecting and intercepting a fracture with a full fracture surface in a fractured structural member, and protecting the fracture.

And step two, establishing a crack propagation direction coordinate identification line on the back of the fracture. And establishing a coordinate marking line in the crack propagation direction along the crack propagation direction by taking the corresponding position of the crack starting point on the fracture back surface as an origin, dividing the corresponding straight line length L of the crack starting point and the crack ending point on the fracture back surface into N equal intervals, and establishing an equal division point, wherein N is 10, for example.

And step three, performing electron microscope scanning analysis on the fracture. And (4) performing electron microscope scanning analysis on the fracture selected in the step one at each equal division point established in the step two, scanning by adopting an electron microscope scanning instrument, and ensuring that each equal division point can clearly obtain a regular fatigue strip in the scanning process.

And step four, measuring the distance between the fatigue strips and calculating the crack propagation rate da/dN at each aliquot point. And analyzing the scanning result of the electron microscope obtained in the step three at each equally dividing point, and accurately calculating and obtaining the crack propagation rate da/dN at each equally dividing point by adopting a method of measuring and averaging for multiple times and multiple places. And selecting a 3 rd bisecting point, wherein the crack length alpha is 275 mu m, and measuring and calculating a crack propagation rate da/dN at the point by an electron microscope scanning picture to be 0.43 mu m/n.

And step five, calculating the stress intensity factor delta K of the crack tip at each aliquot point. According to the formula of paris,and calculating to obtain the stress intensity factor delta K of the crack tip at each aliquot point.

Wherein C and n are material constants. Through the calculation, the method has the advantages that,

step six, calculating the maximum value sigma of the far-end stress of the crack at each equally divided point_max. Calculating the maximum value sigma of the stress at the far end of the crack at each equal division point according to the paris formula_maxCalculated σ_max377.7 MPa. In this case, referring to the handbook of stress intensity factors (1993), the comprehensive correction factor β is 1.1, the equivalent minimum and maximum stresses at this location in the finite element model of fatigue of the whole machine are examined, and R is calculated to be 0.

Seventhly, judging that the maximum value sigma of the stress at the far end of the crack_max>σ₂It is indicated that the failure at this portion belongs to a failure mode other than normal fatigue failure.

The embodiment of the invention provides a fracture analysis-based airplane structure failure mode analysis method aiming at the problem that the failure mode is not easy to determine after a crack occurs in an airplane structure in flight, the method is based on fracture electron microscope scanning analysis on a fractured structure, the crack propagation rate is obtained by measuring the distance between fracture fatigue strips, the stress intensity factor value of the tip of the crack in the crack propagation direction is calculated according to a fracture mechanics method, the maximum value of the stress at the far end of the crack is reversely deduced, and therefore whether the structural part failure belongs to failure other than normal fatigue failure is judged by judging whether the stress maximum value exceeds the equivalent maximum stress of the part in the full-airplane fatigue finite element model solution. The theoretical analysis method adopted by the invention is correct, the engineering concept is clear, and the steps are clear. The method can be used for judging whether the structural part is damaged in a damage mode except normal fatigue damage.

Although the embodiments of the present invention have been described above, the above description is only for the convenience of understanding the present invention, and is not intended to limit the present invention. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.