Model-based enterprise

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Model-based enterprise (MBE) is a term used in manufacturing, to describe a strategy where an annotated digital three-dimensional (3D) model of a product serves as the authoritative information source for all activities in that product's lifecycle. [1] [2]

A key advantage of MBE is that it replaces digital drawings. In MBE, a single 3D model contains all the information typically found on in an entire set of engineering drawings, including geometry, topology, dimensions, tolerances, materials, finishes, and weld call-outs. [3]

MBE was originally championed by the aerospace and defense industries, with the automotive industry following. [4] It has been adopted by many manufacturers around the world, in a wide range of industries. Significant benefits for manufacturers include reduced time to market and savings in production costs from improved tool design and fabrication, fewer overall assembly hours, less rework, streamlined development and better collaboration on engineering changes. [5]

There are two prerequisites to implementing MBE: The first is the creation of annotated 3D models, known as a Model-based definitions (MBD). This requires the use of a CAD system capable of creating precise solid models, with product and manufacturing information (PMI), a form of 3D annotation which may include dimensions, GD&T, notes, surface finish, and material specifications. (The mechanical CAD systems used in aerospace, defense, and automotive industries generally have these capabilities.) The second prerequisite is transforming MBDs into a form where they can be used in downstream lifecycle activities. As a rule, CAD models are stored in proprietary data formats, so they must be translated to a suitable MBD-compatible standard format, such as 3D PDF, [6] JT, STEP AP 242, or ANSI QIF [7]

The core MBE tenet is that models are used to drive all aspects of the product lifecycle and that data is created once and reused by all downstream data consumers. Data reusability requires computer interpretability, where an MBD can be processed directly by downstream applications, and associativity of PMI to specific model features within the MBD. [1]

History

Historically, engineering and manufacturing activities have relied on hardcopy and/or digital documents (including 2D drawings) to convey engineering data and drive manufacturing processes. These documents required interpretation by skilled practitioners, often leading to ambiguities and errors. [8] [9]

In the 1980s, improvements in 3D solid modeling made it possible for CAD systems to precisely represent the shape of most manufactured goods [10] —however, even enthusiastic adopters of solid modeling technology continued to rely upon 2D drawings (often CAD generated) as the authority (or master) product representation. 3D models, even if geometrically accurate, lacked a method to represent dimensions, tolerances, and other annotative information required to drive manufacturing processes.

In the early-to-middle 2000s, the ASME Y14.41-2003 Digital Product Data Definition Practices and ISO 16792:2006 Technical product documentation—Digital product definition data practices [11] standards were released, providing support for PMI annotations in 3D CAD models, and introducing the concept of MBD (or, alternatively, digital product definition) [12]

The model-based enterprise concept first appeared about 2005. Initially it was construed broadly, referring to the pervasive use of modeling and simulation technologies (of almost any type) throughout an enterprise. [13] In the late 2000s, An active community advocating development of MBE grew, based on the collaborative efforts of the Office of the Secretary of Defense, Army Research Laboratory, Armament Research Development Engineering Center (ARDEC), Army ManTech, BAE Systems, NIST, and the NIST Manufacturing Extension Partnership (MEP). [14] The "MBE Team" included industry participants such as General Dynamics, Pratt & Whitney Rocketdyne, Elysium, Adobe, EOS, ITI TranscenData, Vistagy, PTC, Dassault Systemes Delmia, Boeing, and BAE Systems. [15]

Over time, based on community feedback, MBE became more narrowly construed, referring to the use of MBD data to drive product lifecycle activities. [16] [1] In 2011, the MBE Team published these definitions:

By 2015, with improvements to ASME Y14.41 and ISO 16792, and the development of open CAD data exchange standards capable of adequately representing PMI, MBE started to become more widely adopted by manufacturers.

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<span class="mw-page-title-main">Engineering drawing</span> Type of technical drawing used to define requirements for engineered items

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<span class="mw-page-title-main">Computer-aided engineering</span> Use of software for engineering design and analysis

Computer-aided engineering can be defined as the general usage of technology to aid in tasks related to engineering analysis. Any use of technology to solve or assist engineering issues falls under this umbrella.

<span class="mw-page-title-main">Geometric dimensioning and tolerancing</span> System for defining and representing engineering tolerances

Geometric Dimensioning and Tolerancing (GD&T) is a system for defining and communicating engineering tolerances and relationships. It uses a symbolic language on engineering drawings and computer-generated three-dimensional solid models that explicitly describe nominal geometry and its allowable variation. It tells the manufacturing staff and machines what degree of accuracy and precision is needed on each controlled feature of the part. GD&T is used to define the nominal geometry of parts and assemblies, to define the allowable variation in form and possible size of individual features, and to define the allowable variation between features.

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ASME Y14.41 is a standard published by American Society of Mechanical Engineers (ASME) which establishes requirements and reference documents applicable to the preparation and revision of digital product definition data, which pertains to CAD software and those who use CAD software to create the product definition within the 3D model. ASME issued the first version of this industrial standard on Aug 15, 2003 as ASME Y14.41-2003. It was immediately adopted by several industrial organizations, as well as the Department of Defense (DOD). The latest revision of ASME Y14.41 was issued on Jan 23, 2019 as ASME Y14.41-2019.

Model-based definition (MBD), sometimes called digital product definition (DPD), is the practice of using 3D models within 3D CAD software to define individual components and product assemblies. The types of information included are geometric dimensioning and tolerancing (GD&T), component level materials, assembly level bills of materials, engineering configurations, design intent, etc. By contrast, other methodologies have historically required accompanying use of 2D engineering drawings to provide such details.

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<span class="mw-page-title-main">STEP-NC</span> Machine tool control language

STEP-NC is a machine tool control language that extends the ISO 10303 STEP standards with the machining model in ISO 14649, adding geometric dimension and tolerance data for inspection, and the STEP PDM model for integration into the wider enterprise. The combined result has been standardized as ISO 10303-238.

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Siemens Digital Industries Software is an American computer software company specializing in 3D & 2D Product Lifecycle Management (PLM) software. The company is a business unit of Siemens, operates under the legal name of Siemens Industry Software Inc, and is headquartered in Plano, Texas.

References

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  5. Rouse, Margaret. "Model-based enterprise". TechTarget. TechTarget. Retrieved 28 June 2017.
  6. 3D PDF Consortium
  7. "Quality Information Framework"
  8. John Willats. "Ambiguity in drawing" (PDF). TRACEY the online journal of contemporary drawing research. Retrieved 2017-06-27.
  9. Tandler, Bill. "GD&T Workshop: A Top Down View". Quality Magazine. BNP Media. Retrieved 28 June 2017.
  10. Weisberg, David. "The Engineering Design Revolution" (PDF).
  11. "Technical product documentation -- Digital product definition data practices". ISO TC 10 Technical product documentation. Retrieved 2018-10-29.
  12. "Quality Assurance Standard For Digital Product Definition At Boeing Suppliers" (PDF). Boeing D6-51991. Retrieved 2017-06-27.
  13. Neal, Richard, "Next Generation Manufacturing Technology Initiative and the Model-Based Enterprise", NDIA Systems Engineering Conference, San Diego, California October 26, 2005. Retrieved on 27 June 2017.
  14. Leonarf, Scott. "Advanced Manufacturing Enterprise Strategic Baseline" (PDF). DoD ManTech. US Department of Defense. Retrieved 28 June 2017.
  15. 1 2 Whittenburg, Mitzi. "Model Based Enterprise and its Impact on Small Businesses" (PDF). osd.mil. Office of the Secretary of Defense. Retrieved 28 June 2017.
  16. Frechette, S. "Model Based Enterprise for Manufacturing". NIST. National Institute of Standards and Technology. Retrieved 28 June 2017.
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