DE102013106587A1 - Method for collision checking and computer program product - Google Patents

Abstract

The application relates to a method for collision checking, the method being carried out by means of a data processing device and comprising the following steps: providing a first data object (8) which represents a wall with a plurality of projections protruding from the wall, the first data object (8) indicating the position of the comprising a plurality of projections, providing a second data object (9) representing a wall lining element for lining the wall, the second data object comprising dimensions of the wall lining element, determining collisions of the plurality of projections with the wall lining element if the wall lining element is in a specific section on the wall is arranged, and outputting status information that includes the determined collisions. The application also includes a computer program product.

Description

The invention relates to a method for collision checking and a computer program product.

background

The development of insulation for aircraft interiors is currently characterized by many manual steps. The dimensions of the interior (primary structure, holder, etc.) are successively measured in a digital mock-up. The resulting shape of an insulating mat - outer boundary and recesses - is transferred to a drawing sheet. The graphic representation (CAD) of an insulating mat serves as the basis for further processing / reformatting in a machine-readable format, which i.a. is used to control cutting machines. Since all production-relevant dimensions are measured in CAD, manually transferred to a drawing and finally processed for production, this process is very error-prone. Due to the high number of fault geometries in the aircraft interior, the danger is great that structural changes that require an adaptation of the insulating mat, are overlooked. The effort involved in examining the system environment for possible changes is disproportionately high.

Summary

The object is to provide improved technologies for preparing the manufacture of wall lining elements for lining a wall.

This object is achieved by the method according to independent claim 1 and the computer program product according to independent claim 9. Advantageous embodiments are the subject of dependent claims.

According to one aspect, a method for collision checking is provided, which is carried out by means of a data processing device. It comprises the following steps: A first data object is provided which represents a wall with a plurality of protrusions protruding from the wall. The first data object includes position information of the plurality of protrusions. Furthermore, a second data object is provided that represents a wall lining element for lining the wall and includes dimensions of the wall lining element. Collisions of the plurality of protrusions with the wall lining element are detected when the wall lining element is placed in a certain portion on the wall. Finally, a status information is output, which includes the detected collisions. The detected collisions can be output in the form of collision markers.

According to a further aspect, a computer program product is provided which executes the method when executed by means of a data processing device. The computer program product may be stored on a non-volatile storage medium. It can be provided to load the computer program product for execution in a memory of the data processing device.

To prepare a manufacturing process, a lining of the wall with the wall lining element is simulated in advance. For this purpose, the wall lining element is arranged in a certain section on the wall. If the particular portion has at least one of the plurality of protrusions, the wall lining member collides with the protrusion. The wall lining element does not come to a flat contact with the wall in this area. If necessary, the collision must be eliminated before the wall lining element is ready for production.

The first data object may represent an interior of an aircraft. The interior can be provided as a three-dimensional data model, which is created for example by means of a laser scan. The wall in this case corresponds to an inner wall of the aircraft. The plurality of projections may, for example, be holders which protrude into the interior and serve for receiving systems and / or components. The wall may have flat and / or curved sections. Recesses may be formed in the wall, for example for receiving a window and / or a door.

The second data object includes dimensions of the wall lining element. The wall lining element may have various shapes, for example quadrangular, in particular rectangular, square or trapezoidal. The dimensions include the side lengths of the wall lining element and its thickness. Furthermore, the second data object may include information about one or more materials. The wall lining element may for example be a mat. The mat may for example consist of glass wool. Several layers of glass wool can be superimposed to form a mat, for example, two or three layers. The thickness of the individual layers can also be covered by the second data object. The mat may have a filling and a cover. Filling and cover can be made of different materials. The cover may for example consist of a film. For example, the mat may be an insulating mat for thermal insulation of the wall be. Alternatively, the wall lining element may consist of a plastic and be produced, for example, as an injection-molded element.

The second data object can be provided, for example, as an xml file. It can be provided that the second data object comprises further information. For example, surfaces may be defined for heat protection on the wall lining element. Alternatively or additionally, the second data object may include positions for fastening means on the wall lining element, for example for pins. Furthermore, the second data object may comprise positions at which adhesive tape and / or Velcro is attached to the wall lining element. Furthermore, the second data object may include the following information, for example if the wall lining element is a mat: a designation of the mat, an identification number of the mat, a customer identification number, a mat type, a mat variant and / or a version number of the mat. The information can be detected, for example, when creating the second data object by means of a user input and then stored in the second data object. It may be provided that certain information after saving can not be changed, for example, the type of mat. In addition, it can be provided to perform a plausibility test after entering the information.

The mat type defines a topology of the mat. If the type of mat is input, it can determine which further information is relevant for the mat, for example by means of an input mask. For example, a mat of the "flat field mat" type may include an indication of a lateral boundary, an upper and lower boundary, and a distance to the inside of the wall. In addition, an elongation factor can be recorded. The elongation factor may be required to compensate for shrinkage of the material of the mat during technical welding. For other types of mats other input masks may be provided, each of which requires the indication of other parameters.

The second data object may further include manufacturing information, such as a fixed point, another point, a rotation angle, a lower left point, and / or an upper right point. The points can be determined by x and y coordinates of a Cartesian coordinate system. The lower left point and the upper right point do not have to match outer dimensions of the wall lining element. The lower left point is also called a positioning point. He indicates the arrangement of the wall lining element on a marking for the manufacture. It may be provided a rotation about the fixed point, which is executed in a mathematically negative direction. It is rotated by the smallest possible angle at which the y-coordinate of the rotated further point coincides with the y-coordinate of the fixed point.

The second data object can be assigned a journal object. In the journal object, entries for the second data object can be stored, for example descriptions in the form of text. It can be provided that a serial number, the name of the author of the entry or an identifier assigned to the author and / or a date are recorded for the entries. The entries may be associated with a version number of the wall lining element, allowing filtering of the entries. It can be provided that the entries can not be changed and / or deleted.

The mat (as a wall lining element) may have an edge, a cover, a filling, recesses and / or further details. If a mat type specifies a topology of the mat, one or more auxiliary features can be assigned to each type of mat. The auxiliary elements may further include information on local deviations of the mat and additional elements beyond a base geometry defined by the mat type. Furthermore, the auxiliary elements may include information, for example, a position and / or dimensions, to projecting out of the wall supports. This information is used to accurately map the mat in three dimensions and can be taken into account when determining the collisions.

The auxiliary elements may comprise further elements, namely a protruding edge, a fold and / or a break. The protruding edge is an additional area at one edge of the mat. It can also be provided on the mat several protruding edges. The border can be shaped as a trapezoid, as a triangle or as a rectangle. The edge may be bent at a certain angle to the mat. The margin is determined by the following information. The edge (or edges) on the mat where the edge is located and the angle between the mat and the edge. Furthermore, the dimensions of the edge are given, for example length, width and possibly angle between the edges of the edge. By means of the fold material can be introduced into certain areas of the mat. The fold is determined by its position and the amount of material inserted. It can also be formed several folds in the mat. With the change projections are covered on the edge of the mat. The projections are made by their Dimensions characterized, for example, a width and a height. The break is determined by a starting point and an end point and an angle associated with the two points.

The second data object may alternatively or additionally include lining properties. The lining properties may include various types of liners, namely, an adhesive tape, a seam, labels and patches, a representation of a material transfer (so-called splitline) and / or a drainage hole. All lining types can have a name, an activation status, and / or an associated comment. In addition, the various types of lining may include specific information for each type. The adhesive tape may be determined by type, position, length and / or orientation. For example, the variety can be read from a configuration file that is extensible by a user. The seam is determined by the same information as the adhesive tape. There may also be provided a configuration file for specifying the type that is expandable by a user. The label is determined by a position, an orientation and / or a type. The type can in turn be provided by an extensible configuration file. A label is determined by means of a position and an angle. The angle may be, for example, 0 °, 90 °, 180 ° and 270 °. The split line defines an area between two types of film, for example a transition between a refractory material and a non-refractory material. For example, the splitline may run horizontally or obliquely across the mat. A position of the split line is determined by a point (e.g., x and y coordinates) and a directed angle. The patch is determined by a starting point and an angle. The shape of the patch is determined by means of a sectional drawing that can be provided by a user. It can be specified whether the patch is placed on the front or the back of the mat. Types of patching may also be provided, for example by means of a user-expandable configuration file. The sectional drawing can be created by means of a graphical application. The graphical application allows a user to specify the geometry and dimensions of the patch. The application may include a grid on which points of the patch can be placed. You can create points, lines and circular arcs. Lines can be separated or combined with each other. The drainage hole is determined by a position and a diameter. It may be provided to arrange a plurality of drainage holes at an equal distance from each other on the wall lining element. For this purpose, for example, a distance between the holes or a total length and a total number of drainage holes can be specified. The wall lining element may have a plurality of lining properties in any combination.

It can be provided that the second data object comprises production properties, for example a stamp, an production slot, a foam, a text, a dimension, an elevation and / or a material web. All manufacturing properties may have common attributes, such as a name, an activation status, and / or a comment. In addition, the manufacturing properties may each include specific features. The stamp is clearly determined by a position. The manufacturing slot and the foam are each characterized by the specification of a starting point and an end point. The text is determined by a position and an orientation. Furthermore, the text and a font size can be stated. The dimension is determined by a starting point and an end point, and an orientation (for example, horizontal or vertical). Furthermore, a length of a extension guideline can be specified. The dimension is created on the right side of an imaginary line between the starting point and the end point if the length of the extension line has a positive value. If the length of the extension line has a negative value, the dimension is created on the left side. The elevation is determined by a start point and an end point and the width of a rectangle. The rectangle is created on the right side of an imaginary line between the two points if a positive value for the width is specified. If the width value is negative, the rectangle on the left will be generated. The web spans a gap in the wall lining element that is free of the material of the wall lining element. The material web is determined by a starting point, an end point and a width. The two points must lie on opposite sides of the gap. The dimensions of the material web are automatically determined taking into account the surrounding geometry.

The output of the status information can be done, for example, to a display device and / or in a file.

The method is carried out by means of a data processing device. The data processing device can have, for example, one or more processors as well as a memory with a volatile (eg main memory) and / or a non-volatile (eg hard disk) memory area. Furthermore, the data processing device can be used for communication devices for Receiving and / or transmitting data and / or data streams, for example a network connection (LAN - local area network), a connection for a wireless network (WLAN - wireless local area network), a USB port (USB - universal serial bus) , a Bluetooth adapter and / or a Firewire port ( IEEE 1394 ). The data processing device may comprise a device for detecting a user input, for example a keyboard, a mouse and / or a touchpad. The data processing device can be connected to a display device. Alternatively, a display device can be integrated into the data processing device. The display device may include a touch screen for detecting a user input.

According to one embodiment, it can be provided that the method comprises storing the status information together with the second data object.

According to a further development, it is provided that the method comprises the further following steps: A change of the first data object and / or of the second data object is detected. Collisions are determined taking into account the change of the first data object or the second data object. Finally, a new status information is output, which includes the collisions determined in consideration of the change. The output of the new status information can also be done to a display device and / or in a file. It can be provided that the new status information is stored together with the second data object. The change of the first and / or second data object can be done for example by means of a user input.

After the (first or renewed) collision check, the following status parameters can be specified in the result. The status is "open" if a collision was previously determined and this was not taken into account in the changes made. As a recommendation for action, the "open" collision should be treated with a further change. The status is "KO", if a previously determined collision was handled with the change, but it was not resolved. Further treatment (modification of the first and / or second data object) is required to eliminate the collision. The status is "OK" if the collision was handled successfully. After changing the first and / or second data object, no collision was detected during the new collision check. The status is "ignored" if a previously determined collision is considered by a user to be eliminated. The status is "unknown" if a previously determined collision has been dealt with but no further collision check has been performed yet. The status is "not resolved" if no collision is found in an area that has been handled. The status is "obsolete" if, in one area of an untreated collision, another collision is no longer determined in another test.

For example, after providing the first and second data objects, the collision check is performed for the first time. Several collisions are determined and assigned the status "open" as a collision marker. By means of a user input, for example, some of the detected collisions are treated. These receive the status "unknown". The untreated collisions retain the status "open". Now, if the collision check is repeated, newly determined collisions are compared with the previously determined collisions. For new collisions, new collision markers with the status "open" are generated. Detected collisions that have been handled previously receive the status "OK" or "KO" depending on the result of the new check. Detected collisions that have not been dealt with continue to be in the "open" state. Already previously determined collision markers for which no collision was determined with the new check receive a status depending on whether they have been handled. If they have not been treated, the status is "obsolete". If they have been treated, the status is "not resolved". Collision parameters with the status "not resolved" or "obsolete" can be deleted by a user.

It can be provided to assign colors to the different status parameters that are output with the status information. For example, "open" is orange, "KO" is red, "OK" is green, "ignored" is yellow, "unknown" is white, "not fixed" is orange, and "obsolete" is light blue. It can be provided to assign a collision object to the status information and / or the new status information, for example a collision input mask. In the collision input mask, the treatment of the collision and its result can be entered by a user.

The change may include changing the position indication of at least one protrusion in the first data object. Alternatively or additionally, the change may include a new geometry of the wall.

It can be provided that the change comprises determining a recess in a region of the wall lining element for which a collision was previously determined. The recess may have various shapes, which may have common and specific features. A circular recess is defined by a center point and a radius. Of the Midpoint can be specified as the x and y coordinates. It can be provided that the position of the center point and the radius are automatically determined. The following criteria are taken into account for this. The circular recess should be as small as possible. The diameter is at least 40 mm in size and is an integer multiple of 10 mm. There is a gap of at least 5 mm to the colliding projection all around. Rectangular recesses are defined by a position, an orientation and a width and a length. For a rectangular recess may be indicated whether it is formed as a continuous recess which pierces the entire material of the wall lining element or as a thinning in the wall lining element which concerns only a part of the wall lining element. It can be provided to automatically determine a rectangular recess according to the following criteria. The rectangular recess is as small as possible. Neither the length nor the width are smaller than 40 mm. The length and width are integer multiples of 5 mm. There is a gap of at least 5 mm to the colliding projection all around. Furthermore, recesses may be provided with a free form whose shape and dimensions can be arbitrarily determined by a sectional drawing. It may alternatively or additionally be provided a slot with a width of 0 mm, which is determined by a position. A slot always completely penetrates the wall lining element. As a further type of recess, a window may be provided which is determined by a position, an orientation and a window type. The window type can be provided by means of a configuration file. By means of a configuration file further predetermined recesses can be provided. They are determined by a position, an orientation and a type.

According to a further embodiment, it may be provided that the change comprises a change in the dimensions of the wall lining element in the second data object.

According to a further development, it can be provided that the change comprises a change of the specific section in which the wall lining element is arranged on the wall.

It can be provided that manufacturing data is determined from the second data object. The production data can be determined automatically from the information in the second data object. If necessary, they are converted into a format that is required to control a production facility. The manufacturing data can then be transmitted to the production facility for processing the wall lining element. Based on the automatically generated manufacturing data can then be made a production of the wall lining element. The manufacturing data may include a bill of material, a drawing of the wall lining element, a work drawing, marking data and / or a blank drawing. The bill of material may include a material identification number, a material name, a title, a unit, a material usage and / or a material weight. The list of materials may be provided in the form of a table, wherein a table header has one or more of the aforementioned material attributes. The material list can be provided, for example, in the form of a csv file. Based on the information in the second data object can be provided to automatically determine the required material and enter the result in the bill of materials. The marking data may include the lining properties of the wall lining element or mat together with the particulars required for their characterization. The work drawing may include a drawing of the wall lining element along with indications necessary to make a cover for the element. The work drawing can be transmitted, for example, to a beam welding machine, with which the cover is processed. The blank drawing may include a drawing of the wall lining element, optionally with the data / properties described above. The blank drawing can be created in HP GL 2 or IGES-2D format. To do this, the blank drawing is first created in a CATIA V5 format and then written to a text file using an HPGL2 printer driver. A suitable 3DPLM printer should be installed on the data processing device for this purpose. The blank drawing can be transmitted to a cutting device, which cuts the wall lining element according to the given data. The cutting device can be, for example, a mechanical cutting device or a laser cutting machine.

It can be provided that the properties or data encompassed by the first and / or second data object can be changed, for example by means of a user input. For example, a graphical input mask may be provided for entering and / or changing the properties / data. It can be provided that each of the above-mentioned properties is assigned a special input mask which has input fields corresponding to the property.

Furthermore, it may be provided to carry out an authorization of a user before carrying out the method. There may be a local authorization on the data processing device occur. This requires, for example, the specification of a user ID and a password. Alternatively or additionally, a server-based authorization may be provided. A server application runs on a server that is integrated into a network. The server application receives an authorization request from a computing device in the network. Depending on the result of testing various criteria, the use of the method is enabled or disabled by the server application. Furthermore, the use of a license file can be provided. The license file contains the facilities that have a valid license to perform the procedure. Before executing the method, it is checked whether the data processing device on which the method is to be executed is listed in the license file. Only if the result is positive will the procedure be released.

Description of exemplary embodiments

Further embodiments are explained in more detail below with reference to figures of a drawing. Hereby show:

1 a schematic representation of a collision test,

2 a schematic representation of a collision check after changing the output configuration and

3 a schematic representation of a process flow.

1 shows a representation of the steps for a collision check. With a first data object, the geometry of a wall and the positions of multiple protrusions 1 . 2 . 3 certainly. In 1a the starting position is displayed. A second data object is provided that represents a mat to be placed on the wall. By way of example, it is provided a rectangular mat on the in 1a To arrange wall section shown.

The collision check determines three collisions, one for each of the three protrusions 1 . 2 . 3 , The detected collisions are given the status "open" and are highlighted in orange ( 1b ).

A user handles the collisions as in 1c is shown. There are circular recesses 4 . 5 . 6 defined in the mat, through which the projections 1 . 2 . 3 should protrude. Two of the recesses are each assigned to a projection. In the embodiment shown, the upper recess 4 the upper projection 1 and the middle recess 5 the middle projection 2 assigned.

The result of a new collision check is in 1d shown. One treatment was successful, namely for the upper projection 1 , The upper projection 1 receives the status "OK" and is highlighted in green. Treatment of collision with the middle recess 5 was not successful. The status for the middle projection 2 is set to "KO" and it is highlighted in red. The status of the lower tab 3 is still "open" (orange) because the treatment was not assigned and was therefore not taken into account in the new collision check.

The treatment of collisions is improved ( 1e ). The position of the middle recess 5 gets to the position of the middle projection 2 customized. The lower recess 6 gets the lower lead 3 assigned.

A new collision check now shows an overall positive result ( 1f ). All three protrusions 1 . 2 . 3 have been successful recesses 4 . 5 . 6 assigned so that the collisions were resolved. The middle and the lower projection 2 . 3 thus also receive the status "OK" and are also marked in green. The collision check has been successfully completed.

2 shows a new starting situation after the first data object has been changed by adding a new lead 7 was added. The three upper protrusions 1 . 2 . 3 are still treated successfully and have the status "OK" (green mark). The status for the new (fourth) lead 7 is "open" and the fourth lead 7 is marked in orange ( 2a ).

A further change of the first data object leads to a further changed situation, which in 2 B is shown. The fourth lead 7 has been removed. The second and third protrusions (counted from above) 2 . 3 have been moved.

Another collision check leads to the conclusion that there is a need for action ( 2c ). The first advantage 1 is unchanged and therefore still "OK" (green). For the second lead 2 the positions of the projection agree 2 and the recess 5 no longer match. A collision is determined and the second projection 2 receives the status "KO" (red). The third lead 3 has been shifted so far that the shift is no longer considered a shift. Instead, the process is interpreted as deleting the third projection 3 and adding another protrusion to the right of it. For the "cleared" lead, therefore, the status "not resolved" ( orange). The "new" lead 3 gets the status "open" (orange), because a collision with the mat was detected here. The actually erased lower projection 7 now gets the status "obsolete" (light blue). A treatment is not required for the deleted tab.

2d shows the handling of collisions by a user. The second and third projections 2 . 3 were new recesses 5 ' . 6 ' assigned in the mat. The old (no longer applicable) recesses 5 . 6 were deleted. The information for the fourth (now deleted) lead has been removed.

As a result of another collision check, all collisions have been successfully resolved ( 1e ). The second and third lead 2 . 3 now also have the status "OK" (green).

3 shows a cycle between construction and manufacturing, in the course of which the first data object 8th and / or second data object 9 is accessed. First, the first data object 8th and the second data object 9 provided. To the second data object 9 a journal entry can be created and assigned to it (not shown). This is followed by the collision check 10 , In connection with the collision check, which may be carried out several times, as explained above, the first and / or the second data object 8th . 9 to be changed.

Upon completion of the collision test become lining properties 11 added in the second data object. From the thus supplemented second data object can both a list of materials 12 as well as a drawing of the mat 13 be extracted.

The second data object will now come with manufacturing information 14 added. The second data object is transferred to the production department with all information and data 15 , For this purpose, another journal entry can be created (not shown). There are manufacturing properties 16 added to the second data object.

Finally, manufacturing data automatically 17 determined from the supplemented second data object, such as marking data 18 , a blank drawing 19 and a work drawing 20 , The cut data 19 can be transmitted to a cutting device, which then cut from a given material, such as glass wool, the mat.

The data of the first and / or the second data object 8th . 9 can be changed, for example to meet new project specifications. With the changed data objects, the cycle can then be run through again, initially again a collision check 10 for the changed data objects. The revolving use of the first and second data objects 8th . 9 enables a continuity in the process and possibly a reuse of already existing data.

The features disclosed in the foregoing description, claims and figures may be relevant to the practice of the invention both individually and in any combination with each other.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited non-patent literature

• IEEE 1394 [0019]

Claims (9)

Method for collision checking, the method being carried out by means of a data processing device and comprising the following steps: - providing a first data object ( 8th ) representing a wall with a plurality of protrusions protruding from the wall, wherein the first data object ( 8th ) Comprises position information of the plurality of protrusions, - providing a second data object ( 9 ) representing a wall lining element for lining the wall, the second data object comprising dimensions of the wall lining element, determining collisions of the plurality of projections with the wall lining element when the wall lining element is placed in a certain portion on the wall, and outputting status information; which includes the detected collisions. The method of claim 1, wherein the method includes storing the status information together with the second data object ( 9 ). The method of claim 1 or 2, further comprising the steps of: - detecting a change of the first data object ( 8th ) and / or the second data object ( 9 ), - determining collisions taking into account the change of the first data object ( 8th ) or the second data object ( 9 ) and - outputting new status information, which comprises the collisions determined in consideration of the change. The method of claim 3, wherein the change comprises changing the position indication of at least one protrusion in the first data object. The method of claim 3 or 4, wherein the change comprises determining a recess in a region of the wall lining element for which a collision has previously been detected. The method of any of claims 3 to 5, wherein the change comprises changing the dimensions of the wall lining element in the second data object. The method of any one of claims 3 to 6, wherein the change comprises changing the particular portion by placing the wall lining member on the wall. Method according to one of the preceding claims, wherein from the second data object ( 9 ) Manufacturing data ( 17 ) be determined. A computer program product executing, when executed by a data processing device, a method according to any one of the preceding claims.

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