• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    An image processing apparatus (10) and corresponding method for executing a graphic image display (21) in apparatus constructions in engineering, wherein image data (22) of a three-dimensionally shaped object by means of a CAD module (20) of the image processing apparatus (10) by linking a plurality device elements (31) are generated with device element image data (311) of a CAD database (30) and shown in a navigable manner in perspective by means of a graphical interface (50) as a graphic image representation (21) for the user (51). Each device element (31) in the CAD database (30) is assigned by means of a control module (40) dynamically changeable material property data (33) and / or cost data (33), and by means of a control client module (41) and the CAD module (20). the image data (22) of the three-dimensionally shaped object corresponding to the assigned material property data (32) and / or cost data (33) for navigation are displayed perspectively and / or graphically corrected via the interface (50) to the user (51). When changing the associated material property data (32) and / or cost data (33), the graphic image representation (21) by means of the control client module (41) and the CAD module (40) in navigation for the user dynamically perspective and / or graphical corrected shown.
    公开号:CH701969B1
    申请号:CH00434/11
    申请日:2008-09-15
    公开日:2016-07-29
    发明作者:Kunz Lukas;Simon Felix
    申请人:Prolim Eng Gmbh;
    IPC主号:
    专利说明:

    The present invention relates to an image processing apparatus and corresponding method for performing a graphic image display in device constructions in engineering, electrical engineering, construction and engineering works, etc. Image data of a three-dimensionally shaped object are by means of the image processing apparatus by linking a plurality of device elements with Device element image data of a CAD database generated and displayed in perspective by means of a graphical interface as a graphical image representation for the user. In particular, the invention relates to an image processing apparatus which perspectively displays the three-dimensional object from different pages and views by means of a navigation tool.
    State of the art
    Two- and three-dimensional image processing systems and devices are known in the art. Such systems find use in various technical fields, e.g. in Computer Aided Design (CAD) systems, in graphical guidance systems such as in aircraft or in GPS systems (Global Positioning Systems) or in the scientific field for the presentation of scientific data or topologies, e.g. in microbiology or nanophysics. The three-dimensional image representation can be output in perspective on a planar graphical user interface (GUI: Graphical User Interface).
    On the other hand, product and production management systems and methods are known. Typically, linear methods such as e.g. the top-down function approach used. In this process, one starts e.g. with an image processing system or by means of a technical drawing with the construction and design of the desired device, tool or machine, etc. If the technical design and composition is clear, materials and designs of the individual parts are defined in the product and product management system and corresponding information such as cost data, delivery conditions parameters, etc eg collected through a network such as the Internet at providers. It is clear that in the free world market, the costs, especially as regards the raw materials, never simply remain constant for a long time. The product management system thus allows an accurate estimation of the costs at any time after completion of the technical design and material and execution determination. Such cost estimates are particularly valuable because they allow one to estimate the feasibility of the planned device. The method simply allows the individual parts of the planned device to be listed, their material properties and performance characteristics recorded and / or set off.
    However, the product and production management systems are usually not or only rudimentary coupled to the image processing system with which the technical design was developed and built. The manufacture and development of a technical device usually requires the following isolated steps in the prior art: (i) design and construction, (ii) technical implementation and realization, (iii) material and processing selection, (iv) manufacturing process design, (v) cost determination ( vi) production and billing. Dynamic determination of costs and control of costs is difficult until completion of the manufacturing process. In addition, the user or technician must work with different systems that operate detached from each other. Often, the data is thus difficult to link or only transferable from one system to another with a correspondingly great amount of time and effort.
    In the prior art is also the patent US 2006/0 253 214 of the inventor William Gross. US 2006/0 253 214 shows a CAD system for Computer Aided Design (CAD: Computer Aided Design). The system can be accessed by both the designer and a variety of manufacturers. The system includes a database of data on corresponding manufacturers for components for a particular product to be designed. At least cost information on components of a product can be transmitted by the manufacturer and stored locally on the system. In addition, material information can be transferred to the components. The designer can change the design of the product based on the currently transmitted manufacturer information, and the system calculates the new manufacturing price for the product modified by the designer.
    Technical task
    It is an object of this invention to provide a new image processing and product development apparatus and corresponding method for performing a graphical image display in device constructions in engineering, electrical engineering, construction and engineering without the above-mentioned disadvantages. In this case, the image processing system and product management system for the engineer should be implemented in such a way that it allows a comprehensive and easy handling. By integrating the individual steps and systems, a new level of automation in the design of machines or devices is to be achieved. In particular, a dynamic cost monitoring by means of the system should be possible.
    According to the present invention, these objects are achieved in particular by the elements of the independent claims. Further advantageous embodiments are also evident from the dependent claims and the description.
    In particular, these objects are achieved by the invention in that generated to generate a multi-dimensional graphic image representation in device designs in engineering image data of a three-dimensionally shaped object by linking a plurality of device elements with device element image data of a CAD database and by means of a graphical Interfaces are displayed as a graphical image representation in perspective for the user, wherein each device element in the CAD database dynamically variable material property data and / or cost data are assigned, the image data of the three-dimensionally shaped object based on the device element image data depending on the associated material property data and / or Cost data are generated, and wherein the graphical image representation when changing the associated material property data and / or cost data, in particular for Navigation, perspective and / or graphically displayed corrected for the user. The graphic image representation may be displayed by the image processing apparatus e.g. be corrected according to the dynamically changed material property data and / or cost data at least in perspective and / or color. The invention has i.a. the advantage that for the development of technical designs image processing device and product management system are integrated into a single device integrated for the user. In the perspectively different representation of a multi-dimensional object by means of navigation within the image representation, material properties and cost parameters will be experienced directly by the perspective and / or graphically corrected representation and thus can already have an effect during the development process. Due to the fact that material and cost parameters can be taken over and displayed dynamically by means of the inventive image processing device, errors or deficiencies or optimization possibilities in technical constructions can be detected and changed at an early stage. In particular, the image processing apparatus makes possible a new type of automation in the development process of technical devices.
    In one embodiment, the cost data of the device elements include threshold parameters for actual and target costs, wherein the device elements of the three-dimensionally shaped object by means of a deviation analysis module according to the threshold parameters for actual and expected cost data are displayed in perspective and / or graphically corrected. This variant has u.a. the advantage that information of the CAD data or the CAD database can be used and cost relations can be determined by analysis of key features and manufacturing / material properties of the selected device elements. This means that outliers can also be detected automatically, i. Device elements, e.g. are unusually expensive compared to the other device elements or compared to the market. These parts may be replaced by the system e.g. then be further analyzed and / or corrected.
    In another embodiment, a topological navigation map with respect to the device elements according to the associated material property data and / or cost data is generated for navigation, corrected when changing the perspective material property data and / or cost data and displayed accessible to the user as a graphical image representation. This variant has u.a. the advantage that for the navigation or changing the view of the three-dimensional object, the representation can be easily and automatically perspective and / or graphically corrected the user displayed.
    In particular, material properties data and / or cost data can be displayed to the user with the topological navigation map.
    In a further embodiment variant, one of several embodiments concerning material property data and / or cost data is selected by the user for at least one device element of the CAD database, wherein when selecting the graphical image representation for the user is corrected in perspective or graphically. This variant has u.a. the advantage that the user can select from a selection of embodiments for a device element, wherein the representation for the user automatically, perspectively and / or graphically corrected. The different selectable embodiments may be automatically generated by the image processing device or e.g. be transferred via a network to the image processing device.
    In yet another embodiment variant can be extracted by means of an extraction module of the image processing device via a network at decentralized databases periodically and / or on request material property data and / or cost data, wherein the graphical image representation dynamically based on the extracted material property data and / or cost data corrected for the user in perspective or graphically. This variant has u.a. the advantage of being able to dynamically access databases from suppliers of materials or device elements. Thus, during the development and the manufacturing process, the currently most optimal embodiment for each device element can always be selected.
    In one embodiment, by means of an optimization module, a graphical image representation optimized with regard to the extracted material property data and / or cost data can be generated. This variant has u.a. the advantage that the optimization for each device element can be automated by means of the optimization module, the optimization module e.g. as an expert system, the different embodiments are analyzed and / or updated. In the next step, the optimization module selects the different combination options and optimizes with regard to material property and / or cost parameters.
    Embodiments of the present invention will be described below by way of examples. The examples of the embodiments are illustrated by the following enclosed figures:
    Fig. 1 shows a block diagram which schematically illustrates the architecture of an embodiment of an inventive image processing apparatus 10 for performing a graphic image representation 21 in device constructions in mechanical engineering, wherein image data 22 of a three-dimensionally shaped object by means of a CAD module 20 of the Imaging device 10 by linking a plurality of device elements 31 with device element image data 311 a CAD database 30 are generated and displayed by means of a graphical interface 50 of the image processing device 10, the generated image data 22 as a graphical image representation 21 for navigation to the user 51 in perspective.
    Fig. 2 illustrates the course of the known costs at the stage of development of the object / device to be developed according to a prior art image processing apparatus. The effective cost parameters and / or material property parameters can only be determined and optimized after the design and procurement department has submitted the corresponding data. In two of the three development phases (concept, prototype, series) the effective cost parameters can not be practically determined. Only e.g. in the prototype phase can be reacted to costs and optimizations are carried out.
    Fig. 3 illustrates the course of the known costs to the development stage of the object / device to be developed according to an inventive image processing device 10. Immediately after determining the target cost parameters and / or material property parameters, the effective costs can be analyzed according to the stage of development. The first e.g. Estimated cost 33 and material property data 32 are continually automated and replaced by offers by the image processing device 10. At the same time as technical development, costs can be more finely subdivided, analyzed and automated by means of the image processing device 10.
    4 and 5 show different view options, as they can be generated by means of the CAD module 20.
    Fig. 1 illustrates an architecture that may be used to implement the invention. In this embodiment, image device 22 of a three-dimensionally shaped object is coupled by means of a CAD module 20 of the image processing device 10 by linking a plurality of device elements 31 with device element image data 311 of a CAD system by means of an image processing device 10 for performing a graphic image representation 21 in mechanical engineering device designs. Database 30 generated. The three-dimensional shaped article may be a technical equipment, apparatus, machine or other construction such as e.g. also relate to non-movable constructions in construction or architecture, which is composed of different device parts or elements. These elements are referred to herein as device elements 31. Device elements 31 can have a functional effect on or in the three-dimensional object to be produced. But they can also include purely constructive elements or elements with design effect. Under mechanical engineering, e.g. Machine system technology, in particular product development, manufacturing technology, piston machine and automotive engineering, general mechanical engineering, etc. This also includes the whole range of research, planning, development, construction, production of machines and technical aggregates as well as entire production facilities. More generally, it concerns all areas where technical elements are developed, designed and manufactured.
    By means of a graphical interface 50, the generated image data 22 are shown as a graphical image representation 21 for the user 51 in perspective. By means of the perspective representation 21 of the image data 22, the user 51 can change the representation view in perspective over the graphic interface 50, e.g. via one-, two- or multi-dimensional input elements (keyboard, mouse pad, etc.) of the image processing device 10. That is, the user has the ability to change the perspective or the view / cut / projection of the graphic image representation or among them navigate. The graphic interface 50, also called GUI (Graphical User Interface), can not only display on a two-dimensional screen surface, such as a screen. in the usual flat or tube screens or image projectors (beamer) include. The three-dimensional graphical image representation 21 may be provided to the user 51 via the graphical interface 50, e.g. also by providing an azimuth difference object image to both eyes of the user 51. With this principle, three-dimensional images can be shown to the user 51. For this, e.g. By means of the analglyph method, the user 51 may be provided with a red image for the right eye and a blue image for the left eye through the graphic interface 50. In this case, the user 51 additionally wears glasses with blue and red foils, so that only the red image reaches the right eye and only the blue image reaches the left eye. Thereby, the individual eyes of the user 51 can receive only one of the two images corresponding to the respective eyes. In another possible method, the polarization glasses method, the graphical interface 50 comprises a right eye image display device and a left eye image display device, and polarization plates whose polarization planes are orthogonal to each other. Also in this method, the user 51 wears glasses, but now with polarizing plates, which are also orthogonal to each other, so that only the corresponding images reach the corresponding eyes of the user 51. Further possible methods for the technical realization of the graphical interface 50 may be e.g. the so-called time-share closure method, the parallel barrier method, or the lenticular lens principle (see, e.g., U.S. Patent 6,392,690). Of course, this enumeration is not exhaustive, but includes any method that is suitable for displaying multidimensional images, such as e.g. also retina projections. The CAD module 20 may also include, in part, known computer-aided computer aided design (CAD) programming groups for electronic drawing. By means of the CAD module 20, for example, three-dimensional area and volume models, based on image data 22, can be displayed graphically. By means of the CAD module 20, digital descriptions and analog reproduction of geometric structures can be generated in a very general way. The CAD module may e.g. generating the image data 22 in two dimensions (Cartesian XY coordinate system of the plane) deposited or generated in three dimensions (Cartesian XYZ coordinate system of the space). In particular, the CAD module 20 may include at least partially known solutions such as AutoCAD. Thus, the CAD module 20 may include all functions that are used for 2D and 3D interactive geometric modeling with description, development, manipulation, storage, and presentation components. The CAD module 20 may e.g. be implemented in terms of hardware and / or software. 4 and 5 show examples of different viewing options, as they can be generated by means of the CAD module 20.
    The image processing device 10 comprises a control module 40, wherein each device element 31 in the CAD database 30 associated and by means of the control module 40 dynamically changeable material property data 33 and / or cost data 33 includes. Material property data 32 may e.g. mechanical properties such as density, elasticity, strength, hardness, compliance (ductility), brittleness; physical properties such as electrical conductivity, dielectric constant, magnetic peculiarities, optical properties, e.g. Refractive index, thermal behavior (melting point, thermal conductivity, heat capacity ...), nuclear properties (radioactivity, cross sections ...); chemical properties (surface properties) such as corrosion, oxidation, abrasion, wear, cleanliness / cleanliness; Manufacturing and processing properties such as extraction, processing, processing, disposal, bonding, thin-film technology, etc .; economic characteristics such as availability, transport, value added, image, market position; or ecological characteristics such as recyclability, techniques, potential hazards, environmental impact, disposal. The cost data 33 may be e.g. Include cost data and cost parameters at all levels. Of course, it is also possible that e.g. the value added parameters are assigned to the cost data 33. The CAD database 30 may be e.g. for at least one device element 31, multiple embodiments 321-323, 331-333 regarding material property data 32 and / or cost data 33 selectably, wherein upon selection of a specific embodiment, the graphical image representation 21 for the user 51 is shown in perspective or graphically corrected. Perspectively corrected means that e.g. View / plan / cut according to the material property data 32 and / or cost data 33 for the user is changed for navigation. This can e.g. concern the angle of view or proximity / magnification to the three-dimensionally shaped object. Device elements 31 that are distinguished by their material property data 32 and / or cost data 33 may be e.g. enlarged and / or centered. The representation may e.g. be chosen so that the navigation to such excellent device elements 31 changed or completely unnecessary.
    The image processing apparatus 10 comprises a control client module 41, wherein by means of the control client module 41 and the CAD module 20, the image data 22 of the three-dimensionally shaped object according to the associated material property data 32 and / or cost data 33 are generated perspective and / or graphically corrected and by means of Interface 50 can be presented to the user. The correction of the graphical image representation 21 may include at least perspective and color changes corresponding to the changed material property data 32 and / or cost data 33. The graphic image representation 21 is displayed by the control client module 41 and the CAD module 40) when the associated material property data 32 and / or cost data 33 are changed in a perspective and / or graphical manner for the user 52. As a variant embodiment, the cost data 33 of the device elements 31 may comprise threshold parameters for actual and target cost data, wherein the device elements 31 of the three-dimensionally shaped object are represented in perspective and / or graphically corrected by means of a deviation analysis module 42 corresponding to the actual and target cost data. For navigation by means of the image processing apparatus 10, e.g. a topological navigation map with respect to the device elements 31 corresponding to the associated material property data 32 and / or cost data 33 are generated, for navigation when changing the material property data 32 and / or cost data 33, the image data 22 perspective and / or graphically corrected and accessible to the user as a graphical image Representation 21 are shown. The market decisively dictates the price of the item to be developed. In one exemplary embodiment, the total costs are distributed to different sub-functions by means of the image processing device 10, from which the image processing device 10 automatically creates placeholders in the CAD database 30 or the CAD module 20. These placeholders are replaced by the user 51 during development by more detailed models. When creating each machine part or a device element 31, cost parameters are recorded as a price. This refines the cost information in the CAD database 30 at the same time. the target price and an estimated price are entered. By means of an offer request, concrete offers are requested and, if they are available, these are also assigned to the cost data 33 in the CAD database 30. Thus, it can be guaranteed with the image processing apparatus 10 that the complete production costs can be dynamically determined and updated taking into account the shares and uncertainties by estimated cost data. This has the advantage that, in parallel to the technology, cost certainty also develops. The combination of offers and automatic or manual estimates allows continuous tracking of costs by means of the image processing device 10. The costs and materials used, in particular e.g. their production status, etc., can be analyzed via an entire machine, machine parts or product groups. Again, this was not possible in the prior art in any way.
    When the development phase is complete, all material property and cost information, e.g. by means of a suitable interface to an ERP (Enterprise Resource Planning) or PLM (Product Lifecycle Management) system. The database generated and updated dynamically by the image processing device 10 in the CAD database 30 optimizes the process for follow-up projects. With the image processing apparatus 10 according to the invention, it is possible to increase not only the design competence but also the cost and material know-how in a new and inventive way. Another advantage is that in the prior art the implementation of ERP or PLM systems is often organizationally complex and involves considerable costs. This is mainly related to the data to be collected. In addition to the implemented ERP implementations, therefore, the state of the art also includes a number of sometimes spectacular cases of failed ERP introductions. Given the significant costs associated with implementing an ERP and the importance of completing the projects, it is of great interest to identify those factors that are critical to the success of an ERP implementation (Critical Success Factors, CSF ). Incidentally, the significance of this CSF is also reflected in the increasing number of publications dealing with the identification and analysis of CSF for ERP introductions. The inventive image processing apparatus 10 with the dynamic CAD database 30 with material property data 32 and cost data 33 allows for the first time in the prior art a simple easy introduction of such ERF or PLM systems. As an alternative embodiment, such systems can also be implemented as integrated modules with corresponding interfaces. In the interest of optimizing, the image processing apparatus 10 may also comprise a temporal module which perspectively and / or graphically allows to observe and analyze the temporal changes in the material property data 32 and / or cost data 33 of the device elements 31 on the three-dimensionally shaped object via the interface 50 ,
    By means of an extraction module 43 of the image processing apparatus 10 can be extracted as a variant via a network 70 at decentralized databases 601/611/621 periodically and / or on request material property data 32 and / or cost data 33, wherein the graphical image representation 21 dynamically based is displayed on the extracted material property data 32 and / or cost data 33 for the user 51 in perspective or graphically corrected. The communication network 70 may be, for example, a landline network such as a Local Area Network (LAN) or Wide Area Network (WAN), Public Switched Telephone Network (PSTN) and / or Integrated Services Digital Network (ISDN), the Internet or a In particular, the image processing device 10 may be connected to the device element providers 60/61 or material providers 62 via a telecommunications network 70 and / or a direct data transmission network 70. The communication between the image processing device 10 and the device element providers 60/61 or material providers 62 may, for example via a TCP / IP interface and / or CORPA interface, an ATM module, an SMS and / or USSD gateway using special short messages, such as SMS (Short Message Services) -, USSD (Unstructured Supplementary Services Data ) Messages or other techniques such as MExE (Mobile Execution Environmen t) via protocols such as GPRS (Generalized Packet Radio Service), WAP (Wireless Application Protocol) or via a traffic channel. The data transfer between the image processing device 10 and the device element providers 60/61 or material providers 62 is e.g. initiated and carried out via software or hardware implemented transfer modules of the image processing device 10 and the device element provider 60/61 or material supplier 62.
    By means of an optimization module 44 of the image processing apparatus 10, e.g. a graphical image representation 21 optimized with respect to the extracted material property data 32 and / or cost data 33 is generated. As a further embodiment, e.g. also by means of the control module 40 periodically and / or on request an offer request to device element provider 60/61 or material provider 62 are transmitted, by means of which the material property data 32 and / or cost data 33 of the different embodiments 321-323, 331-333 in the device element providers 60/61 or material providers 62 are queried and updated. As another embodiment, when the threshold cost parameter of the target cost data is reached, an order request may be automatically supersized and, e.g. stored in data storage 602, 612, 622 of the device element provider 60/61 or material provider 62 associated with the user and the order are triggered automatically.
    The image processing apparatus 10 according to the invention makes it possible, e.g. to control and optimize the cost and materials used by engineering companies throughout the concept and development phase of a device / machine to be developed. In the concept phase, a backbone of the device / machine is determined with associated target costs. At the beginning of development, the user 51 can gradually build and develop this framework through detailed designs. Each item may have cost data 33 as target values and e.g. minimum material requirements are assigned by means of the material property data 33. The image processing device 10 then dynamically calculates the cost of the three-dimensional object to be produced. All cost / material information is directly assigned to the CAD files. This eliminates the synchronization of databases, as is common in the prior art. The cost structure is always verifiable and can be optimized 1: 1 of the machine structure. In a specific embodiment, the user can define specific cost parameters or customer-specific cost parameters for a client of the three-dimensionally shaped article to be developed. Thus, e.g. Generate views that artificially cost more than actually incurred. The image processing apparatus 10 according to the invention furthermore makes it possible, by means of the CAD database 30, for the design department, project manager and purchaser to work together with the same data. If a user 51, e.g. When a designer inserts a new component into the machine to be developed (three-dimensionally shaped object), the image processing apparatus 10 changes the parts list automatically and the new part is included in the cost accounting. The influence of design changes and variants on the manufacturing costs is thus apparent in real time. The image processing device 10 thus allows the simultaneous development of technology and manufacturing costs without dead times. This was not possible in the prior art so far. Fig. 2 illustrates the course of the known costs at the stage of development of the object / device to be developed according to a prior art image processing apparatus. The effective cost parameters and / or material property parameters can only be determined and optimized after the design and procurement department has submitted the corresponding data. In two of the three development phases (concept, prototype, series) the effective cost parameters can not be practically determined. Only e.g. in the prototype phase can be reacted to costs and optimizations are carried out. In contrast, Fig. 3 shows the course of the known costs to the development stage of the object / device to be developed according to an inventive image processing device 10. Immediately after setting the target cost parameters and / or material property parameters, the effective cost can be analyzed according to the stage of development. The first e.g. Estimated cost 33 and material property data 32 are continually being automatically replaced by offers by the image processing device 10. At the same time as technical development, costs can be more finely subdivided, analyzed and automated by means of the image processing device 10.
    It is also possible, as an embodiment, to associate risk parameter data with the cost data 33. This has the advantage that by means of the image processing device 10 risks can be detected and probabilities of occurrence can be automatically generated for effective costs and made available to the user. If the image processing device 10 has e.g. Via a connection to a financial institution via the communication network 70 or the like, it is thus possible to automatically create reserves for the object to be developed and to adapt it dynamically dynamically throughout the development process. This is possible with no known prior art and requires the dynamic structure of the image processing apparatus 10 according to the invention.
    By means of the control module 40, the information integrated in the CAD data can be analyzed and filtered. The control module 40 may also be used by the user 51 to capture information directly in the CAD. The control module 40 may also be implemented, at least in part, as an embodiment, independently of the image processing apparatus 10, whereby third parties, such as e.g. Project managers and purchasers can use it to perform cost analyzes or to capture offers received. In this sense, it is possible to integrate in the image processing device 10 an authorization system to obtain a user-specific access control: individual user groups can be prohibited in this way to see certain areas and / or to change certain areas. Thus, by means of the image processing device 10, several users 51 can collaborate on different levels of design and manufacture and benefit from the dynamically updated and generated data of the CAD database 30. Likewise, third parties can access accordingly without compromising the security of the system. Thus, e.g. In one embodiment, customers access the image processing device 10 via the network 70, and e.g. to query or track the cost trend depending on the course of development. Likewise, customers in this embodiment can e.g. online, i. over the network 70, buy cost analyzes that determine the optimization potential or extrapolate or estimate using appropriate algorithms.
    权利要求:
    Claims (12)
    [1]
    An image processing apparatus (10) for executing a graphic image display (21) in apparatus constructions, wherein image data (22) of a three-dimensionally shaped object is detected by a CAD module (20) of the image processing apparatus (10) by linking a plurality of apparatus elements (10). 31) can be generated with device element image data (311) of a CAD database (30) and can be displayed in perspective by means of a graphical interface (50) as graphical image representation (21) for the user (51), wherein by means of an extraction module (43) of the image processing device (10) Extracting material property data (32) and / or cost data (33) via a network (70) for decentralized databases (601/611/621) and the graphical image representation (21) based on the extracted material property data (32) and / or cost data (33) of the decentralized databases (601/611/621) for the user (51) can be represented, and wherein the Bildverarb comprises a control module (40), each device element (31) comprising material property data (33) and / or cost data (33) assigned in the CAD database (30) and modifiable by the control module (40), characterizedin that the material property data (32) and / or cost data (33) can be extracted periodically and / or on request by means of the extraction module (43) via the network (70) in the decentralized databases (601/611/621),in that the image processing device (10) comprises a control client module (41), wherein the image data (22) of the three-dimensionally shaped object is generated by means of the control client module (41) and the CAD module (20) according to the assigned material property data (32) and / or cost data (33 ) graphically, in particular perspective, corrected generated and by means of the interface (50) are displayed to the user, andby means of the control client module (41) and the CAD module (40) when changing the assigned material property data (32) and / or cost data (33) for navigation by means of a topological navigation map corresponding to the extracted material property data (32) and / or cost data (33) the image data (22) are graphically, in particular perspective, corrected and accessible to the user for navigation as a graphical representation (21) can be displayed.
    [2]
    2. The image processing apparatus according to claim 1, characterized in that the control client module (41) additionally comprises means for corrected generation of the image data (22) of the three-dimensionally shaped object by at least perspective and color changes according to the changed material property data (32) and / or cost data (33). includes.
    [3]
    3. The image processing apparatus according to claim 1, wherein the control client module additionally comprises means for corrected generation of the image data of the three-dimensionally shaped object by at least perspective and color changes according to actual and target cost data, the cost data (33) of the device elements (31) comprise threshold parameters for actual and target cost data.
    [4]
    4. An image processing apparatus (10) according to any one of claims 1 to 3, characterized in that the CAD database (30) for at least one device element (31) a plurality of embodiments (321-323, 331-333) concerning material property data (32) and / or cost data (33) for the user (51) selectable, wherein for the selection of a specific embodiment, the control client module (41) additionally means for corrected generating the image data (22) of the three-dimensionally shaped object by at least perspective and color changes according to the selection of a specific embodiment.
    [5]
    5. An image processing device (10) according to claim 4, characterized in that by means of an optimization module (44) with respect to the extracted material property data (32) and / or cost data (33) optimized graphic image representation (21) is generated, wherein by means of the optimization module as an expert system, the different embodiments can be analyzed and updated and wherein by means of the optimization module (44) the different combination options optimized with respect to material property and / or cost parameters can be selected.
    [6]
    6. The image processing device (10) according to any one of claims 4 to 5, characterized in that by periodically by additional means of the control module (40) to device element provider (60/61) or material provider (62) transmitted Quotes the material property data (32) and / or Cost data (33) of the different embodiments (321-323, 331-333) are updatable, these being the cost data 33 attributable by means of the CAD database (30), and when reaching the threshold parameters of the target cost data automatically an order request transmitted and stored in data storage (602, 612, 622) of the device element providers (60/61) or material providers (62) is storable.
    [7]
    A method of executing a graphic image display (21) in device constructions in engineering by means of an image processing apparatus (10) according to any one of claims 1 to 6, wherein image data (22) of a three-dimensionally shaped object is obtained by linking a plurality of device elements (31 ) are generated with device element image data (311) of a CAD database (30) and represented by means of a graphical interface (50) as a graphic image representation (21) in perspective for the user (51) and wherein each device element (31) in the CAD Database (30) dynamically changeable material property data (31) and / or cost data (32) are assigned, characterizedin that the image data (22) of the three-dimensionally shaped object are generated based on the device element image data (311) as a function of the assigned material property data (32) and / or cost data (33),that the graphic image representation (21) when changing the assigned material property data (32) and / or cost data (33) by means of the image processing device (10) for navigation according to the new material property data (32) and / or cost data (33) graphically, in particular perspectively for which user (51) is displayed corrected, andthat material data (32) and / or cost data (33) are extracted periodically and / or on request by means of an extraction module (43) of the image processing device (10) via a network (70) in the case of decentralized databases (601/611/621) graphic image representation (21) is corrected dynamically based on the extracted material property data (32) and / or cost data (33) for the user (51) graphically, in particular perspectively.
    [8]
    8. The method according to claim 7, characterized in that the graphic image representation (21) is corrected according to the dynamically changed material property data (32) and / or cost data (33) at least in perspective and / or color, wherein the control client module (41) additionally Comprising means for corrected generation of the image data (22) of the three-dimensionally shaped object by at least perspective and color changes in accordance with the changed material property data (32) and / or cost data (33).
    [9]
    9. The method according to any one of claims 7 or 8, characterized in that the cost data (33) of the device elements (31) include threshold parameters for actual and target costs, wherein the control client module (41) additionally means for corrected generation of the image data (22) of the comprising three-dimensionally shaped object by at least perspective and color changes according to actual and target cost data, wherein the cost data (33) of the device elements (31) include threshold parameters for actual and target cost data.
    [10]
    10. The method according to any one of claims 7 to 9, characterized in that for navigation a topological navigation map with respect to the device elements (31) corresponding to the associated material property data (32) and / or cost data (33) is generated, wherein when changing the material property data (32 ) and / or cost data (33) the image data (22) in perspective and / or graphically corrected and for the user (51) navigable as a graphical image representation (21) are displayed.
    [11]
    11. The method according to any one of claims 7 to 10, characterized in that the CAD database (30) for at least one device element (31) one of several embodiments (321-323, 331-333) concerning material property data (32) and / or Cost data (33) for the user (51) selectable, wherein for the selection of a specific embodiment, the control client module (41) additionally means for corrected generating the image data (22) of the three-dimensionally shaped object by at least perspective and color changes according to the selection of a specific Embodiment comprises.
    [12]
    12. The method according to claim 11, characterized in that by means of an optimization module (44) with respect to the extracted material property data (32) and / or cost data (33) optimized graphic image representation (21) is generated, wherein by means of the optimization module as an expert system different embodiments can be analyzed and updated and wherein by means of the optimization module (44) the different combination options optimized with respect to material property and / or cost parameters can be selected.
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    同族专利:
    公开号 | 公开日
    WO2010028694A1|2010-03-18|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    US7603191B2|2005-02-16|2009-10-13|Idealab|System and method for design of a component|
    法律状态:
    2013-11-29| NV| New agent|Representative=s name: THOMANNFISCHER, CH |
    2014-01-31| AZW| Rejection (application)|
    优先权:
    申请号 | 申请日 | 专利标题
    PCT/EP2008/062254|WO2010028694A1|2008-09-15|2008-09-15|Multi-dimensional image-processing and product development device, and corresponding method|
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