EP2158525A1

EP2158525A1 - Computer system for aircraft maintenance

Info

Publication number: EP2158525A1
Application number: EP08760549A
Authority: EP
Inventors: Jean-Philippe Corbefin
Original assignee: Airbus Operations SAS
Current assignee: Airbus Operations SAS
Priority date: 2007-06-15
Filing date: 2008-06-05
Publication date: 2010-03-03
Also published as: FR2917521B1; BRPI0813340A2; RU2486566C2; WO2008155227A1; JP5336477B2; CA2700933A1; CN101681160A; FR2917521A1; US20100198431A1; CN101681160B; JP2010529921A; US8433475B2; RU2010101065A

Abstract

The invention relates to a computer system for aircraft maintenance including a network partitioned into a secured so-called avionics area (101) and an open area (102). The system includes a first software module stored in the avionics area and a second software module stored in the open area, the first module being adapted for browsing a diagnosis tree, the second module being adapted for presenting a maintenance electronic documentation the browsing of the diagnosis tree by the first module automatically and synchronously triggering a presentation by the second module of pages of said maintenance documentation respectively associated with these nodes.

Description

COMPUTER SYSTEM FOR MAINTENANCE OF AN AIRCRAFT

DESCRIPTION

TECHNICAL FIELD The present invention relates generally to the field of aeronautical maintenance.

STATE OF THE PRIOR ART

Traditionally, the maintenance of an aircraft is done on the ground by maintenance technicians using paper documentation.

This documentation was formerly in the form of manuals or maintenance and repair workbooks, respectively referred to as the Aircraft Maintenance Manual (AMM) and TSM.

(TroubleShooting Manual). It comprehensively described the procedures for preventive maintenance, fault detection and repair that could affect any aircraft equipment. Similarly, the remarks of the pilots were recorded in a logbook or "logbook" in paper form. Maintenance technicians then used this log on call for maintenance purposes. More recently, with the tendency to reduce or even eliminate any paper in the cockpit (Less Paper Cockpit), the AMM, TSM and the logbook manuals have been replaced by embedded computer applications. Specifically, the AMM and TSM manuals now come in the form of electronic documents in which the maintenance operator can freely navigate through hyperlinks. These documents contain a description of the aircraft equipment and failures that may affect them, allowing the maintenance operator to identify and resolve the failure.

Similarly, the logbook is also in the form of an electronic document, called "eLogbook".

The aforementioned electronic documents are also linked together by means of hyperlinks, so that the operator can easily switch from one application to another.

In addition, a centralized maintenance system, known as the CMS (Centralised Maintenance System), makes it possible to start testing a remote device when it is equipped with a built-in test module or BITE (Built In Test Equipment). receive possible error messages and correlate them with each other or with faults in order to facilitate the diagnosis.

The maintenance operator therefore has at his disposal a plurality of disparate computer tools that he must master to be able to diagnose and solve a possible failure.

In addition, these maintenance tools have a certain number of deficiencies: Firstly, the operator is not systematically guided in his diagnosis: he is free to follow the procedure which seems to him the most appropriate and, if necessary, to skip test steps or even to reverse the order indicated in the manual, with the risk of a convergence more or less fast according to the options which will have been taken.

Then, in recently designed aircraft, because of the partition of the network embedded in a secure area and an insecure area, it is difficult to predict where will be hosted computer applications related to maintenance. More precisely, the on-board network is generally partitioned into two sub-networks, the first located in a so-called avionic zone, the second in a so-called open or non-secure zone. The links between the two sub-networks are necessarily unidirectional, directed from the avionics subnet to the open subnet. On the other hand, within the same subnet the links can be bidirectional. Hosting the maintenance tools in the open area would not guarantee their integrity, ie effectively guard against malicious access and / or corruption of the programs and data that constitute them. As a result, maintenance tools would not be eligible for certification. In addition, improper use of maintenance tools (untimely or inconsistent tests) could be detrimental to the proper functioning of avionics systems. Conversely, hosting these tools in an avionics area would hardly be possible because it would require the development of specific applications, particularly expensive, and would not allow the possibility of frequent updates.

An object of the present invention is to propose a maintenance tool for an aircraft that does not have the aforementioned drawbacks, that is to say, on the one hand, that allows to guide the operator in a systematic way and to on the other hand, which offers an implementation compatible with the partition of the embedded network.

STATEMENT OF THE INVENTION

The present invention is defined by a computer maintenance system for an aircraft equipped with a partitioned network in a secure area, called avionics, and an open area, said computer system comprising a first software module hosted in the avionics area and a second software module hosted in the open area, the first module being adapted to traverse a diagnostic tree, the second module being adapted to present an electronic maintenance documentation, the path of the diagnostics shaft by the first module inducing automatically and synchronously presenting by the second page module of said maintenance documentation respectively associated with these nodes. Advantageously, each node of said diagnostic tree corresponds to at least one maintenance task and the first module transmits to the second module a hyperlink pointing to a page of the maintenance documentation associated with this task when the first module reaches said node.

The first module typically determines the next node based on the result of the execution of said maintenance task corresponding to that node. The diagnostic tree is determined for example from a fault identifier code, said code being itself obtained from an analysis of an entry of an electronic logbook hosted in the avionics zone. If the first module determines that a device of the aircraft is defective at the end of the path of the diagnostics tree, said system can be adapted to verify the presence of this equipment in a minimum list of aircraft equipment, called MEL list, hosted in the avionics area.

If said faulty equipment is present in the MEL list, the system is adapted to calculate the corresponding cost in terms of functional performance losses or safety margins of the aircraft. In addition, a third software module, housed in the avionics zone, and a fourth software module, hosted in the open zone, may be provided, the third module being adapted to browse and select the elements of the MEL list, the fourth software module to be presented. documentation pages corresponding to said equipment, the selecting an element by said third software module inducing automatically and synchronously a presentation by the fourth module of a documentation page relating to this element. For each element of the MEL list, the third module advantageously transmits to the fourth module, a hyperlink pointing to a URL containing said documentation page relating to this element.

The first module and, if applicable, the third module, can be hosted in a first computer of the avionics zone and the second module and, where appropriate, the fourth module can be hosted ( s) in a second computer of the open area, the second computer then being connected to the network portion of the avionic area by a unidirectional link to the open area and a wireless access point.

According to one variant, the first module and, where appropriate, the third module can be hosted in a first computer of the avionics zone and the second module and, where appropriate, the fourth module can be hosted in a second computer of the open area, the inputs / outputs of the first and second computers being connected to a KVM switch, said switch being adapted to switch said inputs / outputs to a common input / output interface.

BRIEF DESCRIPTION OF THE DRAWINGS Other features and advantages of the invention will become apparent on reading a Preferred embodiment of the invention is made with reference to the attached figures among which:

Fig. 1 schematically illustrates a first embodiment of the maintenance system according to the invention;

Fig. 2 schematically illustrates an alternative embodiment of the maintenance system according to the invention;

Fig. 3 illustrates the operation of the maintenance system according to the invention;

Fig. 4 gives an example of a diagnostic tree;

Figs. 5A to 5G represent the contents of a first screen and a second screen of the maintenance system, during the progression of the diagnostic module along successive nodes of the diagnostic tree.

DETAILED PRESENTATION OF PARTICULAR EMBODIMENTS

The idea underlying the invention is to provide a maintenance system comprising a first software module hosted in the avionics area and a second software module hosted in the open area, the first being a diagnostic module adapted to perform a route in a diagnostic tree, the second being dedicated to the presentation of the maintenance documentation, the path of nodes of the diagnostic tree automatically and synchronously inducing a presentation of the documentation pages respectively associated with these nodes. Fig. 1 illustrates a maintenance computer system according to an embodiment of the invention.

The system is composed of two parts 101 and 102 respectively included in the avionics zone AW and the open zone OW. Each of the parts of the system comprises a plurality of equipment interconnected by bidirectional links, for example virtual links of a switched Ethernet network. On the other hand, the two parts are connected to each other only by one or more unidirectional link (s) directed (s) from the AW zone to the OW zone, symbolized in the figure by diodes.

The part of the avionic zone comprises a maintenance terminal 110 or OMT (Onboard Maintenance Terminal) hosting a centralized maintenance system (CMS), 113. This system comprises in particular a first software module, called diagnostic module, 115, adapted to traverse a predetermined diagnostic tree. The OMT terminal also hosts a software module 120, responsible for managing the logbook. The OMT terminal is also connected to integrated test modules, 130, implemented in some equipment to be tested, and to a unit 160 responsible for controlling all the circuit breakers relating to these devices. The activation of a circuit breaker makes it possible to cut off the power supply of one or more pieces of equipment in order to replace it safely. Finally, the OMT terminal has an input / output interface 150 including a display screen and a keyboard. The part of the system in the open area includes a terminal for consulting the maintenance documentation, hereinafter referred to as information terminal. This terminal may for example take the form of a laptop computer, 190, or an electronic slate (Tablet PC ™), 195. The maintenance documentation is housed either directly in the laptop 190 or the electronic slate 195 , if its memory size is sufficiently low, either in an embedded server 170, otherwise. The laptop or electronic slate can be connected via a wireless link to the wired network via an AP access point. If the access point is connected to the avionic part of the network, this connection is made by means of a unidirectional link 181, as shown in the figure. Frame switches denoted SW allow routing on the various links of the network.

According to a second embodiment shown in FIG. 2, a common input / output interface 155 (keyboard, screen and, where appropriate, mouse) is shared between the computer 110 hosting the diagnostic module and the computer 191 hosting the maintenance documentation. The inputs / outputs of these computers are connected through the KVM (Keyboard Video Mouse) switch 185, to this common input / output interface, said switch to switch, manually or automatically, between the two computers. Note that only the video signal of the computer 191 goes up from the open area to the avionics area so that the security of the latter is not affected. The maintenance operator can easily switch from the diagnostic screen to the documentation screen, as will be seen below. In case of failure, the system

CMS is notified either directly by a message transmitted by the flight alarm system or FWS (Flight Warning System), or by a note of the driver recorded as entry in the logbook 120, or by both jointly . The CMS system can correlate different failures to look for the likely common cause (s). In all cases, the CMS system provides a probable fault identification code, associated with one or more replaceable equipment (s) or LRUs (Line Replaceable ϋnits).

The diagnostic module, 115, receives a fault identification code and retrieves the diagnostics tree corresponding to this code. The module 115 is adapted to traverse this diagnostic tree according to the indications provided by the maintenance operator and / or the test modules integrated in the equipment to be tested. The diagnostic tree generally comprises a first part relating to the confirmation of the failure and a second part, relating to the actual resolution, in case the failure is actually confirmed.

Each node of the diagnostic tree includes a task or a sequence of tasks to be performed, the result of which determines the choice of the next node. Each node of the diagnostics tree corresponds to a page of the maintenance documentation intended to be displayed on the information terminal 190 or 195. The path of the diagnosis tree induces simultaneously and automatically a navigation through the pages of the the documentation associated with the traversed nodes. More specifically, each time a node is visited by the diagnostic module, a hyperlink is transmitted by the terminal OMT to said terminal. The latter includes a navigation module that synchronizes automatically by searching for the URL pointed to by the hyperlink. The corresponding page can be retrieved locally in the information terminal if the documentation is stored there or if said page is available in the cache memory, or in the embedded server 170. Alternatively, the documentation page can be retrieved from a server on the ground.

The maintenance operator is thus routinely guided through the diagnostic procedure while being able to consult the maintenance documentation for each step of the procedure.

Storing maintenance documentation in the open area facilitates update operations. The latter can be performed for example by means of a data downloading method complying with the ARINC 615 protocol or simply by replacing a memory medium. The update usually leaves the diagnostic tree unchanged, which ensures the integrity of the maintenance system. The diagnostics tree can be extracted from the existing maintenance documentation, ie the aforementioned AMM and TSM manuals. More precisely, the diagnostic tree corresponds to the tree structure of the TSM manual. When a step in the fault repair procedure, corresponding to a tree node in the TSM manual, requires the completion of certain maintenance tasks in the AMM manual. In this case the tree constituting these tasks is grafted locally to the aforementioned node. The set of tree nodes in the TSM manual to which the trees of the maintenance tasks related to these nodes are thus grafted, forms the diagnostic tree. If the AMM and TSM manuals are in the form of XML or SGML documents, the diagnostic tree will be obtained by removing the visual representation elements, for example layout elements, images, three-dimensional schemas , animation scripts. These elements are rejected in the documentation section. However, all the functional elements will be kept in the diagnostic tree, including hyperlinks to launch test applications, download software for a device, activate or deactivate a circuit breaker, etc.

Thus, on the one hand, a diagnostic tree is obtained and on the other hand a purely documentary file, both being, for example, in XML or SGML format but having distinct DTDs. In addition, at each node of the diagnostic tree is associated a hyperlink to a page of the document file.

The diagnostic tree and the document file can also be developed in parallel, provided that they respect their

Respective DTDs and the consistency of the hyperlinks between the two documents.

Fig. 3 illustrates an example of operation of the maintenance computer system according to the invention.

A fault identification code is transmitted to the diagnostic module, for example from a logbook setpoint. The diagnostics module searches for the diagnostics tree (indicated here by "Task N") corresponding to this code. This tree is divided into two parts noted (I) and (II) respectively corresponding to the procedure of confirmation of failure and the procedure of resolution of failure.

During the diagnostic tree run, the presentation of the maintenance documentation is synchronized as each node of the tree passes. For example, when the diagnostic module goes through node 5, the documentation page relating to sub-task 5 is displayed on the information terminal. It should be noted, however, that switching from one node to the next does not necessarily require a change of the page to be displayed. In addition, the maintenance operator can navigate freely through the documentation through hyperlinks. For example, the operator can click on the hyperlink "subtask 5- 2" to see the page related to this subtask. However, as soon as the diagnostic module passes to the next node (in this case node 8), the documentation page for this last node ("subtask 8") will automatically appear on the terminal screen. information.

At the end of the path of the diagnostic tree, either the fault is resolved or the fault remains and the corresponding mention is recorded in the logbook. If the fault persists, the defective equipment is listed and compared with the contents of the Minimum Equipment List (MEL). This list, contrary to what its name indicates, gives the list of equipment whose operation is optional for the operation of the device. Thus, if equipment diagnosed as defective is not on the list, the flight must be canceled. On the other hand, if a device diagnosed as defective is in the MEL list, the system determines the constraints imposed by the malfunction of the equipment and the associated cost in terms of functional performance losses or safety margins. For example, the malfunction of an equipment may impose a constraint on the amount of fuel that the aircraft will be able to embark, which will in turn result in a limit of its range of action. The aforementioned costs are stored in a file hosted in the avionics area.

According to an embodiment variant not shown, the computer system according to the invention comprises a third software module, hosted in the avionic zone, for example in the diagnostic terminal, allowing the pilot or the maintenance operator to browse the MEL list and select any equipment from this list. The computer system also comprises a fourth software module, hosted in the open zone, for example in the information terminal, responsible for displaying the documentation relating to the elements of the MEL list. This documentation is housed in the open area, for example by the information terminal or the embedded server 170. Alternatively, this documentation may be hosted by a server on the ground. The MEL list is, meanwhile, hosted in the avionics area, for example in the diagnostic terminal.

When an element of the MEL list is selected by means of the third software module, it transmits via the network to the fourth module a hyperlink pointing to a URL giving the documentation page relating to this element. The fourth software module then retrieves this page and displays it on the information terminal screen. In this way, the path of the elements of the MEL list automatically and synchronously induces a presentation of the corresponding documentation pages by the information terminal.

Fig. 4 gives an example of a diagnostics tree used by the diagnostic module 115, corresponding to a determined fault code, noted here TSM 31-50-810-982-A, corresponding to a failure of the software of a system of diagnosis. flight alarm FWS 2 (Flight Warning System). The part of the tree relating to the confirmation procedure and the part relating to the isolation procedure are separated by a horizontal dashed line. FIGS. 5A to 5G show the contents of the screens of the OMT terminal and the information terminal for an example of a path of the diagnostics shaft shown in FIG. 4.

The root 410 of the diagnostics tree 400 is associated with a documentation page shown in the left-hand part of FIG. 5A. This page shows the main steps of the procedure for confirming and isolating the fault. In 410, the diagnostic module tests the failure indicated in the logbook. In this case, the status of the fault is confirmed (node 421) and therefore the diagnostic module proceeds to node 441.

The node 441 is associated with the execution of an integrated test program (BITE) of a unit (LRU) of the FWS system called CPIOM-C2 (Core Processing Input / Output Module). As illustrated in FIG. 5B, the screen of the terminal OMT indicates the degree of completion of the test program, and the information screen the details of the corresponding procedure. In this case, at the end of the test, the program returns an error code as indicated on the screen of the OMT terminal in FIG. 5C. The failure of the CPIOM-C2 unit is therefore isolated (node 441 of the diagnostics tree). The documentation page remains unchanged at this point. Node 451 corresponds to a procedure for replacing the CPIOM-C2 unit, as illustrated in FIG. 5D and the information terminal screen indicates the detail. In a first step, the circuit breaker of the CPI0M-C2 power supply circuit is activated, that is, its power supply is cut off, and then in a second step (see Fig. 5E) a new unit is installed.

Once the new unit is installed and power is restored, the diagnostics module tests the FWS again, that is, returns to root 410 of the diagnostics tree. The test of the system proves this time satisfactory (absence of error code), as indicated in FIG. 4G. The documentation page is of course the same as that displayed during the first pass in the diagnostic tree.

The maintenance operator therefore concludes that the fault has been repaired and bears the corresponding mention in the logbook.

Claims

1. Computer maintenance system for an aircraft equipped with a partitioned network in a secure zone, called avionics (101), and an open zone

(102), characterized in that it comprises a first software module hosted in the avionic area and a second software module hosted in the open area, the first module being adapted to traverse a diagnostic tree, the second module being adapted to present electronic maintenance documentation, the path of the diagnostics tree by the first module automatically and synchronously inducing a presentation by the second page module of said maintenance documentation respectively associated with these nodes.

2. Computer system according to claim 1, characterized in that each node of said diagnostics tree corresponds to at least one maintenance task and that the first module transmits to the second module a hyperlink pointing to a page of the maintenance documentation associated with this task when the first module reaches said node.

3. Computer system according to claim 2, characterized in that for each node of the diagnostic tree, the first module determines the next node according to the result of the execution of said maintenance task corresponding to this node.

Computer system according to one of the preceding claims, characterized in that the diagnosis tree is determined from a fault identifier code, said code being itself obtained from an analysis of an input an electronic logbook (120) hosted in the avionics area.

5. Computer system according to one of the preceding claims, characterized in that, if the first module determines that a device of the aircraft is defective at the end of the path of the diagnostics shaft, said system is adapted to check the presence of this equipment in a minimum list of equipment of the aircraft, called MEL list, hosted in the avionics area.

6. Computer system according to claim 5, characterized in that, if said faulty equipment is present in the MEL list, the system is adapted to calculate the corresponding cost in terms of functional performance losses or safety margins of the aircraft .

7. Computer system according to claim 5 or 6, characterized in that it comprises a third software module, hosted in the avionics area, and a fourth software module, hosted in the open area, the third module being adapted to browse and select the elements of the MEL list, the fourth software module to present pages documentation corresponding to said equipment, the selection of an element by said third software module inducing automatically and synchronously a presentation by the fourth module of a documentation page relating to this element.

8. Computer system according to claim 7, characterized in that, for each element of the MEL list, the third module transmits to the fourth module, a hyperlink pointing to a URL containing said documentation page relating to this element.

9. Computer system according to one of the preceding claims, characterized in that the first module and, where appropriate the third module, is (are) hosted in a first computer of the avionics area and that the second module and , where appropriate the fourth module, is (are) hosted in a second computer of the open zone, the second computer being connected to the part of the network of the avionic zone by a unidirectional link (181) to the open zone and a wireless access point (180).

10. Computer system according to one of claims 1 to 8, characterized in that the first module and, where appropriate the third module, is (are) hosted in a first computer of the avionics area and the second module and, if applicable, the fourth module, is (are) hosted in a second computer in the open area, the inputs / outputs of the first and second computers being connected to a KVM switch, said switch being adapted to switch said inputs / outputs to a common input / output interface (155).