275 research outputs found
Automated Manufacturability Analysis: A Survey
In the marketplace of the 21st century, there is no place for traditional ``over-the-wall'' communications between design and manufacturing. In order to ``design it right the very first time,'' designers must ensure that their products are both functional and easy to manufacture. Software tools have had some successes in reducing the barriers between design and manufacturing. Manufacturability analysis systems are emerging as one such tool---enabling identification of potential manufacturing problems during the design phase and providing suggestions to designers on how to eliminate them.In this paper, we provide a survey of current state of the art in automated manufacturability analysis. We present the historical context in which this area has emerged and outline characteristics to compare and classify various systems. We describe the two dominant approaches to automated manufacturability analysis and overview representative systems based on their application domain. We describe support tools that enhance the effectiveness of manufacturability analysis systems. Finally, we attempt to expose some of the existing research challenges and future directions.<P
Intelligent systems in manufacturing: current developments and future prospects
Global competition and rapidly changing customer requirements are demanding increasing changes in manufacturing environments. Enterprises are required to constantly redesign their products and continuously reconfigure their manufacturing systems. Traditional approaches to manufacturing systems do not fully satisfy this new situation. Many authors have proposed that artificial intelligence will bring the flexibility and efficiency needed by manufacturing systems. This paper is a review of artificial intelligence techniques used in manufacturing systems. The paper first defines the components of a simplified intelligent manufacturing systems (IMS), the different Artificial Intelligence (AI) techniques to be considered and then shows how these AI techniques are used for the components of IMS
A Methodological Approach to Knowledge-Based Engineering Systems for Manufacturing
A survey of implementations of the knowledge-based engineering approach in different technological sectors is presented. The main objectives and techniques of examined applications are pointed out to illustrate the trends and peculiarities for a number of manufacturing field. Existing methods for the development of these engineering systems are then examined in order to identify critical aspects when applied to manufacturing.
A new methodological approach is proposed to overcome some specific limitations that emerged from the above-mentioned survey. The aim is to provide an innovative method for the implementation of knowledge-based engineering applications in the field of industrial production.
As a starting point, the field of application of the system is defined using a spatial representation. The conceptual design phase is carried out with the aid of a matrix structure containing the most relevant elements of the system and their relations. In particular, objectives, descriptors, inputs and actions are defined and qualified using categorical attributes.
The proposed method is then applied to three case studies with different locations in the applicability space. All the relevant elements of the detailed implementation of these systems are described. The relations with assumptions made during the design are highlighted to validate the effectiveness of the proposed method.
The adoption of case studies with notably different applications also reveals the versatility in the application of the method
Product complexity assessment for a Proactive-DFA implementation (Simplicity + Simplicity = Complexity)
This thesis presents product complexity as a criterion for the optimisation of
product design in the light of an Assembly-Oriented Design and Design for
Assembly implementation. It takes a holistic approach to the evaluation of the
product architecture by presenting a set of indicators that help examine the product
structure at two different levels: Assembly and Component complexity. Assembly
complexity assessment is further sub-divided into Structural and Sequence
complexity. The latter is a well-known and thoroughly studied area in assembly
sequence evaluation, whereas the former gives a novel and original approach to
drawing attention to those areas in the product configuration that will consume more
resources (i.e. time and tooling required). Component complexity, on the other hand,
is sub-divided into manufacturing and process handling/manipulation complexity.
The first area has been addressed by the manufacturing analysis section of most
Design for Assembly and Manufacturing methodologies, but it has been traditionally
addressed as a manual and chart-based evaluation. This is a rigid approach that
leaves little room for expansion and has no connection with the product structure.
The metrics presented in this work embody a new approach that takes into account
the component-to-component interactions and allows the analysis of component
shape by extracting its geometry characteristics and comparing them with particular
traits of the manufacturing processes available to the designer.
Additionally, the metrics presented in this work can be used to make an
assessment of the product complexity at a particular point (static complexity) in the
development cycle. They can also be registered over a period of time to provide an
estimate of the possible consequences of the decisions made during a part of the
development cycle (dynamic complexity). By using the methods developed,
designers could reduce production costs and increase the reliability of their products.Ph
Optimization of a die insert produced through metal powder bed fusion
The study described in this paper is a reference application of HPDC and AM simulation coupling the benefits of the two manufacturing processes. The thermo-mechanical performance of traditional diecasting insert is improved by conformal cooling channels. The SLM simulation validate the 3D printing of steel material and conformal channels. The cost-benefits analysis supports the decision to maximize the benefits and reducing costs
The development of a manufacturability analysis system for micro-milling
Manufacturability analysis systems (MASs) have been developed to enable the evaluation of manufacturability aspects during the design stage. MASs have been shown to be useful for macro-manufacturing processes but less attention or effort has been put for their development in the scope of micro-manufacturing. This thesis describes the development of a MAS for a micro-machining domain (MicroMAS) with a custom-made 4-axis Miniature Machine Tool (MMT) being the scope of implementation.
There are three important components in this study which are; MAS, Uncertainty Evaluation Model (UEM) and micro-milling experiments. The integration between the results from the UEM analysis and micro-machining experiments were being incorporated into the MicroMAS to provide the system with the real condition of the MMT.
In MicroMAS, Primitive Feature Analysis (PFA) is introduced as a new technique in gathering information from a CAD model and analysing its manufacturability. The results from the manufacturability assessment in MicroMAS are successfully achieved through the manufacturability index which indicates the relative ease of machining the CAD model and list of related suggestions.
UEM is developed to analyse the influence of the errors stemmed from the MMT construction on the geometrical accuracy of the machined micro-parts. The model has allowed a methodology for the errors in a custom-made machine tool to be predicted and to further understand the origin of the errors on the machined micro-part (either from the machine or the process itself). The abilities of the MMT are evaluated through various types of experiments where the surface quality and geometrical accuracy can be concluded to be at an acceptable range.
From the experience gained from the research, the development of MicroMAS for micro-milling has been found to be practical in assisting a user to generate micro-parts using the MMT
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SUPPORTING ENGINEERING DESIGN OF ADDITIVELY MANUFACTURED MEDICAL DEVICES WITH KNOWLEDGE MANAGEMENT THROUGH ONTOLOGIES
Medical environments pose a substantial challenge for engineering designers. They combine significant knowledge demands with large investment for new product development and severe consequences in the case of design failure. Engineering designers must contend with an often-chaotic environment to which they have limited access and familiarity, a user base that is difficult to engage and highly diverse in many attributes, and a market structure that often pits stakeholders against one another. As medical care in general moves towards personalized models and surgical tools towards less invasive options emerging manufacturing technologies in additive manufacturing offer significant potential for the design of highly innovative medical devices. At the same time however these same technologies also introduce yet more challenges to the design process.
This dissertation presents a knowledge-based approach to addressing the existing and emerging challenges of medical device design. The approach aims to address these challenges using knowledge captured in a suite of modular ontologies modeling knowledge domains that must be considered in medical device design. These include ontologies for understanding clinical context, human factors, regulation, enterprise, and manufacturability. Together these ontologies support design ideation, knowledge capture, and design verification. These ontologies are subsequently used to formulate a comprehensive knowledge framework for medical device design, and to enable an innovative design process. Case studies analyzing the design of surgical tools in several medical specialties are used to assess the capabilities of this approach
An intelligent knowledge based cost modelling system for innovative product development
This research work aims to develop an intelligent knowledge-based system for product
cost modelling and design for automation at an early design stage of the product
development cycle, that would enable designers/manufacturing planners to make more
accurate estimates of the product cost. Consequently, a quicker response to customers’
expectations. The main objectives of the research are to: (1) develop a prototype system
that assists an inexperienced designer to estimate the manufacturing cost of the product,
(2) advise designers on how to eliminate design and manufacturing related conflicts that
may arise during the product development process, (3) recommend the most economic
assembly technique for the product in order to consider this technique during the design
process and provide design improvement suggestions to simplify the assembly
operations (i.e. to provide an opportunity for designers to design for assembly (DFA)),
(4) apply a fuzzy logic approach to certain cases, and (5) evaluate the developed
prototype system through five case studies.
The developed system for cost modelling comprises of a CAD solid modelling system,
a material selection module, knowledge-based system (KBS), process optimisation
module, design for assembly module, cost estimation technique module, and a user
interface. In addition, the system encompasses two types of databases, permanent
(static) and temporary (dynamic). These databases are categorised into five separate
groups of database, Feature database, Material database, Machinability database,
Machine database, and Mould database.
The system development process has passed through four major steps: firstly,
constructing the knowledge-based and process optimisation system, secondly
developing a design for assembly module. Thirdly, integrating the KBS with both
material selection database and a CAD system. Finally, developing and implementing a
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fuzzy logic approach to generate reliable estimation of cost and to handle the
uncertainty in cost estimation model that cannot be addressed by traditional analytical
methods.
The developed system has, besides estimating the total cost of a product, the capability
to: (1) select a material as well as the machining processes, their sequence and
machining parameters based on a set of design and production parameters that the user
provides to the system, and (2) recommend the most economic assembly technique for a
product and provide design improvement suggestion, in the early stages of the design
process, based on a design feasibility technique. It provides recommendations when a
design cannot be manufactured with the available manufacturing resources and
capabilities. In addition, a feature-by-feature cost estimation report was generated using
the system to highlight the features of high manufacturing cost. The system can be
applied without the need for detailed design information, so that it can be implemented
at an early design stage and consequently cost redesign, and longer lead-time can be
avoided. One of the tangible advantages of this system is that it warns users of features
that are costly and difficult to manufacture. In addition, the system is developed in such
a way that, users can modify the product design at any stage of the design processes.
This research dealt with cost modelling of both machined components and injection
moulded components.
The developed cost effective design environment was evaluated on real products,
including a scientific calculator, a telephone handset, and two machined components.
Conclusions drawn from the system indicated that the developed prototype system
could help companies reducing product cost and lead time by estimating the total
product cost throughout the entire product development cycle including assembly cost.
Case studies demonstrated that designing a product using the developed system is more
cost effective than using traditional systems. The cost estimated for a number of
products used in the case studies was almost 10 to 15% less than cost estimated by the
traditional system since the latter does not take into consideration process optimisation,
design alternatives, nor design for assembly issue
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