FR3098500A1 - Method and system for the automatic graphic representation of the calculation points identified in an aircraft structure, on a digital model of the structure of an aircraft - Google Patents

Abstract

A graphical representation system implements a method of graphically representing calculation points identified in a part of the structure of the aircraft. The calculation points are represented on a digital model of the part of the structure of the aircraft. The representation method comprises the following steps: determining the coordinates (E30, E40) of a calculation point from a series of characters describing the positioning of the calculation point in the part of the structure of the aircraft, and representation (E50) of the calculation point, on the digital model of the part of the structure of the aircraft, at determined coordinates. Figure for the abstract: Fig. 2

Description

Method and system for automatic graphical representation of calculation points identified in an aircraft structure, on a digital model of the structure of an aircraft

The present invention relates to a method and a system for graphical representation, on a digital model of at least part of an aircraft structure, of calculation points identified in said at least part of the structure of the aircraft .

The invention thus finds its application in the aeronautical field.

The structure of an aircraft undergoes stresses at certain locations, such as the junctions between two fuselage sections or between the junctions of the fuselage with the wings and the empennage.

For each structure of an aircraft, the locations of the structure of the aircraft suffering from the forces are identified and listed in one or more text files. A text file of this type is known in the aeronautical field as a “ stress dossier ”. In general, for an aircraft structure, a “ stress dossier ” is created for each part of the structure, listing the locations identified as suffering from the forces in this part of the structure. These text files or “stress files” are created manually by operators.

These places suffering from the forces are designated as " calculation points ".

Sometimes a single “ stress dossier ” lists the design points identified throughout the entire aircraft structure.

Thus, for each aircraft structure, one or more text files are created by operators to list identified calculation points. In other words, a text file takes the form of a list of calculation points.

A list of calculation points comprises at least one sequence of characters describing the positioning of a calculation point in a part of the structure of the aircraft. In other words, the list of calculation points contains for each identified calculation point a series of characters or words expressing or describing the positioning of the calculation point.

It will be noted that this series of characters or words has no particular format and that different formats can be used to describe or express the positioning of the identified calculation points. For example, an entry in this list could be " skin between frames 1-2 " to express that a calculation point is present on the skin of the fuselage between frame n°1 and frame n°2. However, these same calculation points could be expressed by a different sequence of characters.

Text files listing calculation points have multiple applications. For example, these text files or “ stress files ” are used, in the event of damage to the aircraft, to identify calculation points which must be checked in order to decide whether the aircraft can be put back into operation or not.

Indeed, when an aircraft is damaged, a certain number of examinations must be carried out at the level of the calculation points included in the damaged part in order to assess whether the aircraft can be put back into operation or, if on the contrary, repairs must be implemented.

Thus, following damage to part of the structure of an aircraft, operators carry out searches in the " stress file " corresponding to the damaged part of the aircraft, to identify the calculation points belonging to the part of the aircraft structure affected by the damage.

Since these searches in the “stress file” are manual, they are quite time-consuming and subject to human error.

The aim of the present invention is to make it easier to use text files associated with the structure of an aircraft.

To this end, the invention relates, according to a first aspect, to a method of graphical representation of calculation points identified in at least part of the structure of an aircraft, on a digital model of said at least part of the structure of the aircraft.

According to the invention, the representation method comprises the following steps implemented by a graphical representation system:

• determination of the coordinates of at least one calculation point from a sequence of characters describing the positioning of said at least one calculation point in said at least part of the structure of the aircraft, and
• representation of the calculation point at the determined coordinates, on said digital model of said at least part of the structure of the aircraft.

Thanks to these characteristics, the calculation points listed in the lists of calculation points or " stress files ", are displayed on a three-dimensional digital graphic representation of the structure of the aircraft, or digital model, created by a computer-aided design (known as a " CAD tool ").

The representation of the calculation points on a digital model of the aircraft structure makes it easy to visualize all the calculation points present on an aircraft structure.

The visualization of the calculation points on a model is of great help in many tasks. For example, in the event of damage to a part of the structure of an aircraft, the identification of the calculation points located in the damaged part is implemented quickly and reliably. Thus, the time to assess whether the damaged aircraft can be put back into operation or not, is reduced.

According to other possible characteristics, taken alone or in combination with each other:

- said at least one calculation point is part of a list of calculation points in a text file;

- the step of determining the coordinates comprises the following sub-steps:

- identification of key words and/or numbers in said sequence of characters describing said at least one calculation point, and

- generation of a sequence of terms expressing the positioning of said at least one calculation point according to the identified keywords and/or numbers;

- the terms of said sequence of terms correspond to parts and/or constituent elements of the structure of the aircraft, and the numbers uniquely identify said parts and/or said constituent elements of the structure of the aircraft;

- the terms in the succession of terms are organized according to a predetermined order;

- the step of identifying terms comprises searching for keywords among the characters of said sequence of characters describing the positioning of said at least one calculation point, using a dictionary of keywords associating keywords with parts and/ or components of the structure of the aircraft;

- the determination of the coordinates further comprises a step of searching in a dictionary of coordinates associating coordinates with each part and/or constituent element of the structure of the aircraft, terms in said generated sequence of terms.

The present invention relates, according to a second aspect, to a system for graphical representation on a digital model of at least a part of a structure of an aircraft, of calculation points in said at least a part of the structure of the aircraft.

According to the invention, the representation system comprises:

• means for determining the coordinates of at least one calculation point from a sequence of characters describing the positioning of said at least one calculation point in said at least part of the structure of the aircraft, and
• means for representing said at least one calculation point on said digital model of said at least part of the structure of the aircraft, at the coordinates determined by said determining means.

The present invention relates, according to a third aspect, to a use of the representation system in accordance with the invention and implementing the representation method in accordance with the invention to obtain a digital model of at least part of a structure of an aircraft on which calculation points are graphically represented in said at least part of the structure of the aircraft.

The representation system and the use of this system have characteristics and advantages similar to those previously described in relation to the representation method.

Other features and advantages of the invention will appear further in the description below.

In the accompanying drawings, given by way of non-limiting examples:

FIG. 1 is a model of part of an aircraft structure;

FIG. 2 is a diagram illustrating steps of the representation method according to one embodiment of the invention; And

FIG. 3 is a diagram illustrating a representation system architecture according to one embodiment.

The invention finds its application in maintenance operations, for example to decide whether to restart or repair an aircraft following damage to its structure.

FIG. 1 represents a three-dimensional digital model 1 of part of an aircraft structure in which calculation points 10 are represented by the implementation of the representation method in accordance with the invention. More particularly, FIG. 1 represents the central part of the fuselage of an aircraft. This digital model 1 is generally obtained with a computer-aided design tool or CAD tool.

The graphical representation method in accordance with the invention is implemented using one or more text files in which the calculation points identified beforehand are referenced. In some embodiments, a single text file lists all of the calculation points identified in the aircraft structure, and in other embodiments, different text files respectively list different parts of the aircraft structure. aircraft.

A text file contains sequences of characters describing the positioning of the calculation points. In other words, a text file comprises a list of calculation points, the positioning of each calculation point being described by a sequence of characters.

A text file comprising calculation points is known in the aeronautical field as a “ stress file ”.

The sequences of characters are formed by free text introduced by an operator after identification of the calculation points. It will thus be noted that the positioning of a calculation point can be defined by different sequences of characters.

For example, a text file might have the following list with a list of character sequences:

“ Skin between fr41-42

skin between stringer 3&4

Upper panel stringer 5 and root joint

Keel beam Central door fitting »

It will be noted that the examples given in no way limiting, are sequences of characters in the English language. Of course, other languages can be used to describe the positioning of the calculation points, and even several languages can be used in the same text file. Also, in this example, the list includes the positioning relative to three calculation points. Of course, the list includes numbers of different sequences of characters, depending on the number of calculation points identified.

In the example above, the first sequence of characters expresses the positioning of a calculation point on the skin of the fuselage located between frames 41 and 42, the second sequence, that of a calculation point positioned between the stringers 3 and 4.

The graphical representation method in accordance with the invention comprises, as will be described in detail with reference to FIG. 2, the determination of the coordinates of the calculation points 10 from the sequences of characters in the text files describing the positioning of the points of calculation, and the representation of the calculation points 10 on the digital model 1 of at least part of the structure of the aircraft, at the coordinates which have been determined.

FIG. 2 represents an embodiment of the method of graphical representation, on a digital model 1 of at least part of a structure of an aircraft, of the calculation points 10 identified in said at least part of the structure of an aircraft.

The graphical representation method can be implemented for each of the text files containing the positioning of the calculation points or “ stress file ”. For example, in the event of damage to a part of the structure of an aircraft, the representation method can be implemented for the stress dossier corresponding to this part of the structure of the aircraft.

In particular, once a text file or “ stress dossier ” is selected E00, the method includes a step E20 of identifying the key words and/or numbers in the sequences of characters describing the calculation points. For the identification of the key words, a dictionary of the key words associating key words with parts and/or constituent elements of the structure of the aircraft is used.

Due to the free generation of sequences of characters describing the positioning of the calculation points, the constituent elements of the structure of the aircraft can be described by different keywords to designate the same element. Thus, in the aforementioned dictionary of keywords, different keywords designating the same element are associated with these constituent elements of the structure of the aircraft.

For example, a framework can be expressed by the term “ cadre ”, “ frame ”, “ frames ”, “ fr ” etc… Thus, the dictionary associates all these key words with the constituent element of the “ frame ” structure.

For example, if the step of identifying the key words E20 is implemented for the sequence of characters “ Skin between fr41-42 ” , the constituent element of the structure of the aircraft “ skin ” is identified. Then, the term "frame" is identified as indicative of the location of the calculation point.

Prior to this step E20 of identifying the key words, the method may comprise a step E10 of selecting the model and the version of the aircraft, followed by a step E11 of selecting the dictionary of key words corresponding to the part of structure associated with the “ stress file ”. For example, if the " stress dossier " corresponds to the central part of the fuselage, the dictionary of keywords selected is that corresponding to the fuselage.

In one embodiment, the identification step E20 comprises a step of searching for keywords and then of searching for numbers located after the identified keywords.

The method further comprises a generation step E30 of a sequence of terms expressing the positioning of the calculation points according to the key words and/or figures identified in the identification step E20.

Thanks to this step, a sequence of terms is generated so as to uniformly express the positioning of all the calculation points. This sequence of terms has a predefined form and order.

The terms of the sequence of terms generated correspond to parts and/or constituent elements of the structure of the aircraft, and the numbers identified uniquely designate the parts and/or constituent elements of the structure of the aircraft.

In one embodiment, the sequence of terms comprises a first term designating a part of the structure of the aircraft, such as the fuselage, a wing, the empennage, followed by a term representing the constituent element of the structure of the aircraft containing the calculation point such as the skin, or other.

The following terms correspond to the location of the calculation point in the part of the aircraft structure. These terms consist of a mixture of terms designating components of the structure of the aircraft and numbers uniquely identifying these components.

Thus, for example, for the free text describing the positioning of a calculation point such as " Skin between fr41-42 ", the sequence of terms generated at step E30 would be the following " Fuselage/ P eau / cadre /41/ cadre /42 ”.

After the generation of a sequence of terms in the generation step E30, the method includes the determination E40 of the coordinates of the calculation points from the sequence of terms generated in the generation step E30. For this, a search step E41 for terms in said sequence of generated terms is implemented in a dictionary of coordinates, this dictionary of coordinates associating coordinates with each part and/or constituent elements of the structure of the aircraft. In one embodiment, the step of searching for the keywords E41 begins by searching for location data. In the example above, the coordinates associated with frames 41 and 42 are taken from the dictionary.

In case of failure to obtain these coordinates, the term corresponding to the part of the structure, such as "skin" is searched.

Thanks to this search step E41, the XYZ coordinates associated with each constituent element of the structure of the aircraft are extracted, during an extraction step E42, so as to deduce the exact position of the calculation point 10 concerned. For example, thanks to the aforementioned sequence of terms, coordinates representative of the position of frames 40 and 42 are extracted.

Then, the coordinates of the calculation point are deduced from the extracted coordinates. In one embodiment, the coordinates denote the midpoint between frames 41 and 42.

Once the coordinates are obtained, the calculation point is represented E50 on the digital model (1) at the determined coordinates.

FIG. 3 illustrates an example of hardware architecture suitable for implementing the invention, in particular the representation method represented in FIG. 2. The graphic representation system 100 here comprises a communication bus 105 to which are connected:

- One or more central processing units or microprocessors 110 (CPU, acronym for Central Processing Unit in English terminology);

- A read only memory 115 (ROM, acronym for Read Only Memory in Anglo-Saxon terminology) which may include the programs necessary for the implementation of the invention;

- A random access memory or cache memory 120 (RAM, acronym for Random Access Memory in English terminology) comprising registers adapted to record variables and parameters created and modified during the execution of the aforementioned programs; And

- a communication interface 150 suitable for transmitting and receiving data, in particular to and from the controlled devices of the aircraft to control them and know their status.

The graphical representation system 100 also preferably has the following elements:

- one or more display units 125 making it possible to view data such as the lists of calculation points identified in the structure of the aircraft or the digital models, and being able to serve as a graphic interface with an operator who will be able to interact with the programs according to the invention, using a keyboard and a mouse 130 or another pointing device such as a touch screen or a remote control;

- a hard disk 135 which may include the aforementioned programs and data processed or to be processed according to the invention; And

- a memory card reader 140 adapted to receive a memory card 145 and to read or write thereto data processed or to be processed according to the invention.

The communication bus allows communication and interoperability between the various elements included in the graphic representation system 100 or connected to it. The representation of the bus is not limiting and, in particular, the central unit is capable of communicating instructions to any element of the graphic representation system 100 directly or via another element of the graphic representation system 100.

The executable code of each program allowing the programmable device to implement the processes according to the invention can be stored, for example, in the hard disk 135 or in ROM 115.

According to a variant, the memory card 145 can contain data, in particular aircraft models or “ stress files ” that can be requested, as well as the executable code of the aforementioned programs which, once read by the graphic representation system 100, is stored in hard disk 135.

According to another variant, the executable code of the programs could be received, at least partially, via the interface 150, to be stored in a manner identical to that described previously.

More generally, the program or programs may be loaded into one of the storage means of the graphic representation system 100 before being executed.

The central unit 110 will control and direct the execution of the instructions or portions of software code of the program or programs according to the invention, instructions which are stored in the hard disk 135 or in the ROM 115 or else in the other elements of aforementioned storage. When powered up, the program or programs which are stored in a non-volatile memory, for example the hard disk 135 or the ROM 115, are transferred to the random access memory 120 which then contains the executable code of the program or programs according to the invention, as well as registers for storing the variables and parameters necessary for the implementation of the invention.

The graphic representation system 100 comprises in particular the means necessary for implementing the method according to the invention, such as the means for determining the coordinates of the calculation points, the means for representing the calculation points, the means for identification of key words and/or numbers, means for generating sequences of terms, and means for searching for key words and terms in a dictionary.

Claims (11)

Method of graphical representation, on a digital model (1) of at least part of an aircraft structure, of calculation points (10) identified in said at least part of the structure of the aircraft, said representation method being characterized in that it comprises the following steps implemented by a graphic representation system:
- determination of the coordinates (E30, E40) of at least one calculation point from a sequence of characters describing the positioning of said at least one calculation point in said at least part of the structure of the aircraft, and
- representation (E50) of said at least one calculation point, on said digital model (1) of said at least part of the structure of the aircraft, at the determined coordinates. Representation method according to Claim 1, characterized in that the said at least one calculation point is part of a list of calculation points in a text file. Representation method according to one of Claims 1 or 2, characterized in that the step of determining the coordinates comprises the following sub-steps:
- identification (E20) of key words and/or numbers in said sequence of characters describing said at least one calculation point, and
- generation of a sequence (E30) of terms expressing the positioning of said at least one calculation point according to the identified keywords and/or numbers. Representation method according to Claim 3, characterized in that the terms of the said sequence of terms correspond to parts and/or constituent elements of the structure of the aircraft, and the numbers uniquely identify the said parts and/or the said elements components of the aircraft structure. Representation method according to one of Claims 3 or 4, characterized in that the step of identifying (E20) the key words and/or digits includes the search for key words (E41) among the characters of the said sequence of characters describing the positioning of said at least one calculation point, using a dictionary of keywords associating keywords with parts and/or constituent elements of the structure of the aircraft. Representation method according to one of Claims 3 to 5, characterized in that the said determination of the coordinates (E30, E40) further comprises a search step (E42) in a dictionary of coordinates associating coordinates with each part and/ or constituent element of the structure of the aircraft, terms in said generated sequence of terms. Graphic representation system on a digital model of at least a part of an aircraft structure, of calculation points identified in said at least a part of the structure of the aircraft, said representation system being characterized in that that it includes:
- means for determining the coordinates of at least one calculation point from a sequence of characters describing the positioning of said at least one calculation point in said at least part of the structure of the aircraft, and
- means for representing said at least one calculation point on said digital model of said at least part of the structure of the aircraft, at the coordinates determined by said determining means. Representation system according to Claim 7, characterized in that the means for determining the coordinates comprise:
- means for identifying key words and/or numbers in said sequence of characters describing said at least one calculation point, and
- means for generating a sequence of terms expressing the positioning of said at least one calculation point as a function of the key words and/or numbers identified by said identification means. Representation system according to Claim 8, characterized in that the term identification means comprise search means configured to search for key words among the characters of the said sequence of characters describing the positioning of the said at least one calculation point, in a dictionary of keywords associating keywords with parts and/or constituent elements of the structure of the aircraft. Representation system according to one of Claims 8 or 9, characterized in that the said means for determining the coordinates further comprise search means configured to search in a dictionary of coordinates associating coordinates with each part and/or constituent element of the structure of the aircraft, terms in said generated sequence of terms. Use of the representation system in accordance with one of Claims 7 to 10 and implementing the method of representation in accordance with one of Claims 1 to 6 to obtain a digital model of at least part of a structure of an aircraft on which are graphically represented calculation points identified in said at least part of the structure of the aircraft.