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Optimal design of thin-walled structures by means of efficient parameterizationUgail, Hassan January 2002 (has links)
Yes
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Automatic design and optimisation of thermoformed thin-walled structuresUgail, Hassan, Wilson, M.J. January 2004 (has links)
Yes / Here the design and functional optimisation of thermoformed thin-walled structures
made from plastics is considered. Such objects are created in great numbers especially
in the food packaging industry. In fact these objects are produced in such vast numbers
each year, that one important task in the design of these objects is the minimisation of
the amount of plastic used, subject to functional constraints. In this paper a procedure for
achieving this is described, which involves the automatic optimisation of the mold shape
taking into account the strength of the final object and its thickness distribution, thus
reducing the need to perform inefficient and expensive `trial and error¿ experimentation
using physical prototypes.
An efficient technique for parameterising geometry is utilised here, enabling to create a
wide variety of possible mold shapes on which appropriate analysis can be performed. The
results of the analysis are used within an automatic optimisation routine enabling to find
a design which satisfies user requirements. Thus, the paper describes a rational means for
the automatic optimal design of composite thermoformed thin-walled structures.
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Conceptual Development of Cable Suspension Systems for Submersible Column Pumps : Exploring Design Methods & Strategies for Reducing Cable DamageAndersson, Matilda, Vinell, Sofia January 2024 (has links)
With the global demand for reliable water management infrastructure, Xylem has identified the need for improved cable handling to prevent failures and extend the lifespan of their stormwater equipment. This thesis explores the development of an improved cable suspension system for Flygt column pumps, focusing on enhancing durability and reducing installation complexity through design and product development. The focus of the research is to improve the reliability and functionality of the cable suspension system while ensuring compatibility with existing column and pump system designs. The thesis captures the insights of industry professionals through interviews and benchmarking of other existing solutions on the market. A literature study is conducted to provide the theoretical framework for the product development of a new system. In addition, an observational study of a pump installation is carried out to gain real-life experience of installation conditions. An analysis of the current situation and system design provides the necessary information to generate ideas and formulate design requirements. The ideation phase involved a brainstorming session and a SCAMPER session aimed at generating new and diverse concepts for the cable suspension system. Initial ideas included implementing multimedia instructions through QR codes, changing the position of the cables, and improving the transportation routine. Several product development methods were employed, including the use of morphological charts. Combined User Journey Maps and storyboards were created to refine the ideas into whole-package concepts. The concepts were evaluated against the project specifications through Pugh matrix analysis and by conducting final interviews to verify the results and findings. Finally, the research questions are addressed. These include an examination of the existing cable suspension systems currently in use, an analysis of the installation process and an investigation into the reasons why some clients do not adhere to recommended practices. The study concludes with recommendations for the design of Xylem's Flygt column pumps future cable suspension system. The study proposes a new concept for the cable suspension system that improves ease of maintenance and reduces the risk of cable damage during installation and transportation. The concept includes the use of multi-media instructions, simpler components and safer installation. The recommendations also include suggestions for future research and potential improvements based on findings from the research, ideation, and development phases.
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Using genetic algorithms to optimise wireless sensor network designFan, Jin January 2009 (has links)
Wireless Sensor Networks(WSNs) have gained a lot of attention because of their potential to immerse deeper into people' lives. The applications of WSNs range from small home environment networks to large habitat monitoring. These highly diverse scenarios impose different requirements on WSNs and lead to distinct design and implementation decisions. This thesis presents an optimization framework for WSN design which selects a proper set of protocols and number of nodes before a practical network deployment. A Genetic Algorithm(GA)-based Sensor Network Design Tool(SNDT) is proposed in this work for wireless sensor network design in terms of performance, considering application-specific requirements, deployment constrains and energy characteristics. SNDT relies on offine simulation analysis to help resolve design decisions. A GA is used as the optimization tool of the proposed system and an appropriate fitness function is derived to incorporate many aspects of network performance. The configuration attributes optimized by SNDT comprise the communication protocol selection and the number of nodes deployed in a fixed area. Three specific cases : a periodic-measuring application, an event detection type of application and a tracking-based application are considered to demonstrate and assess how the proposed framework performs. Considering the initial requirements of each case, the solutions provided by SNDT were proven to be favourable in terms of energy consumption, end-to-end delay and loss. The user-defined application requirements were successfully achieved.
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Application of multidisciplinary design optimisation to engine calibration optimisationYin, Xuefei January 2012 (has links)
Automotive engines are becoming increasingly technically complex and associated legal emissions standards more restrictive, making the task of identifying optimum actuator settings to use significantly more difficult. Given these challenges, this research aims to develop a process for engine calibration optimisation by exploiting advanced mathematical methods. Validation of this work is based upon a case study describing a steady-state Diesel engine calibration problem. The calibration optimisation problem seeks an optimal combination of actuator settings that minimises fuel consumption, while simultaneously meeting or exceeding the legal emissions constraints over a specified drive cycle. As another engineering target, the engine control maps are required as smooth as possible. The Multidisciplinary Design Optimisation (MDO) Frameworks have been studied to develop the optimisation process for the steady state Diesel engine calibration optimisation problem. Two MDO strategies are proposed for formulating and addressing this optimisation problem, which are All At Once (AAO), Collaborative Optimisation. An innovative MDO formulation has been developed based on the Collaborative Optimisation application for Diesel engine calibration. Form the MDO implementations, the fuel consumption have been significantly improved, while keep the emission at same level compare with the bench mark solution provided by sponsoring company. More importantly, this research has shown the ability of MDO methodologies that manage and organize the Diesel engine calibration optimisation problem more effectively.
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A finite element based optimisation tool for electrical machinesGerber, Stiaan 03 1900 (has links)
Thesis (MSc (Electrical and Electronic Engineering))--University of Stellenbosch, 2011. / ENGLISH ABSTRACT: Knowledge of the magnetic fields in the domain of electrical machines is required in order
to model machines accurately. It is difficult to solve these fields analytically because of
the complex geometries of electrical machines and the non-linear characteristics of the
materials used to build them. Thus, finite element analysis, which can be used to solve
the magnetic field accurately, plays an important part in the design of electrical machines.
When designing electrical machines, the task of finding an optimal design is not simple
because the performance of the machine has a non-linear dependence on many variables.
In these circumstances, numerical optimisation using finite element analysis is the most
powerful method of finding optimal designs.
In this thesis, the work of improving an existing finite element simulation package, formerly
known as the Cambridge package among its users, and the use of this package in the
optimisation of electrical machine designs, is presented. The work involved restructuring
the original package, expanding its capabilities and coupling it to numerical optimisers.
The developed finite element package has been dubbed SEMFEM: the Stellenbosch Electrical
Machines Finite Element Method.
The Cambridge package employed the air-gap element method, first proposed by Razek
et. al. [2], to solve the magnetic field for different positions of the moving component
in a time-stepped finite element simulation. Because many new machine topologies have
more than one air-gap, the ability to model machines with multiple air-gaps is important.
The Cambridge package was not capable of this, but during the course of this work, the
ability to model machines with multiple air-gaps using the air-gap element method was
implemented.
Many linear electrical machines have tubular, axisymmetric topologies. The functionality
to simulate these machines was newly implemented because the original program was not
capable of analysing these machines. Amongst other things, this involved the derivation
of the coefficients of an axisymmetric air-gap element’s stiffness matrix. This derivation,
along with the original air-gap element derived by Razek et. al. [2] and the extension of
the method to the Cartesian coordinate system by Wang et. al. [29, 30], completes the
derivation of all two-dimensional air-gap elements. In order to speed the numerical optimisation process, which is computationally expensive,
parallelisation was introduced in two areas: at the level of the finite element simulation
and at the level of the optimisation program.
The final product is a more powerful, more usable package, geared for the optimisation
of electrical machines. / AFRIKAANSE OPSOMMING: Kennis van die magnetiese velde in die gebied van elektriese masjiene word benodig om
masjiene akkuraat te modelleer. Dit is moeilik om hierdie velde analities op te los as
gevolg die komplekse geometrieë van elektriese masjiene en die nie-lineêre karakteristieke
van die materiale wat gebruik word om hulle te bou. Dus speel eindige element analise ’n
belangrike rol in die ontwerp van elektriese masjiene omdat dit gebruik kan word om die
magnetiese veld akkuraat te bepaal.
Wanneer elektriese masjiene ontwerp word, is dit nie ’n eenvoudige taak om ’n optimale
ontwerp te vind nie omdat die werkverrigting van die masjien nie-lineêr afhanklik is van
baie veranderlikes. Onder hierdie omstandighede is numeriese optimering, tesame met
eindige element analise, die kragtigste metode om optimale ontwerpe te vind.
In hierdie tesis word die verbetering van ’n bestaande eindige element simulasie pakket,
wat onder gebruikers van die pakket as die Cambridge pakket bekend staan, en die gebruik
van hierdie pakket vir die optimering van elektriese masjiene, voorgelê. Die werk het die
herstrukturering van die oorspronklike pakket, die uitbreiding van die pakket se vermoëns
en die koppeling van die pakket aan numeriese optimeerders behels. Die ontwikkelde
eindige element pakket word SEMFEM genoem: die Stellenbosch Elektriese Masjiene
Finite Element Method.
Die Cambridge pakket het van die lugspleet element metode, soos oorspronlik deur Razek
et. al. [2] voorgestel, gebruik gemaak om die magnetiese veld vir verskillende posisies
van die bewegende komponent in ’n tyd-stapsgewyse eindige element simulasie op te los.
Omdat baie nuwe masjien topologieë meer as een lugspleet het, is die vermoë om masjiene
met meer as een lugspleet te kan modelleer belangrik. Die Cambridge pakket was nie hier
toe in staat nie, maar die vermoë om masjiene met meervoudige lugsplete te modelleer is
gedurende hierdie werk geïmplementeer.
Baie lineêre masjiene het tubulêre, assimmetriese topologieë. Die funksionaliteit om hierdie
masjiene te simuleer is nuut geïmplementeer omdat die oorspronlike program nie in
staat was om hierdie masjiene te analiseer nie. Dit het onder andere behels dat die koeffisiënte
van ’n assimmetriese lugspleetelement se styfheidsmatriks afgelei moes word. Hierdie
afleiding, tesame met die oorspronlike lugspleetelement afgelei deur Razek et. al. [2]
en die uitbreiding na die Cartesiese koördinaatstelsel deur Wang et. al. [29, 30], voltooi
die afleiding van alle twee-dimensionele lugspleet elemente.
Om die numeriese optimeringsproses, wat tipies tydsgewys duur is, te versnel, is parallellisering
op twee vlakke ingebring: op die vlak van die eindige element simulasie en op die
vlak van die optimeringsprogram.
Die finale produk is ’n kragtiger, meer bruikbare pakket, goed aangepas vir die optimering
van elektriese masjiene.
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Thin-walled composite deployable booms with tape-spring hingesMallikarachchi, H. M. Yasitha Chinthaka January 2011 (has links)
Deployable structures made from ultra-thin composite materials can be folded elastically and are able to self-deploy by releasing the stored strain energy. Their lightness, low cost due to smaller number of components, and friction insensitive behaviour are key attractions for space applications. This dissertation presents a design methodology for lightweight composite booms with multiple tape-spring hinges. The whole process of folding and deployment of the tape-spring hinges under both quasi-static and dynamic loading has been captured in detail through finite element simulations, starting from a micro-mechanical model of the laminate based on the measured geometry and elastic properties of the woven tows. A stress-resultant based six-dimensional failure criterion has been developed for checking if the structure would be damaged. A detailed study of the quasi-static folding and deployment of a tape-spring hinge made from a two-ply plain-weave laminate of carbon-fibre reinforced plastic has been carried out. A particular version of this hinge was constructed and its moment-rotation profile during quasi-static deployment was measured. Folding and deployment simulations of the tape-spring hinge were carried out with the commercial finite element package Abaqus/Explicit, starting from the as-built, unstrained structure. The folding simulation includes the effects of pinching the hinge in the middle to reduce the peak moment required to fold it. The deployment simulation fully captures both the steady-state moment part of the deployment and the final snap back to the deployed configuration. An alternative simulation without pinching the hinge provides an estimate of the maximum moment that could be carried by the hinge during operation. This moment is about double the snap-back moment for the particular hinge design that was considered. The dynamic deployment of a tape-spring hinge boom has been studied both experimentally and by means of detailed finite-element simulations. It has been shown that the deployment of the boom can be divided into three phases: deployment; latching, which may involve buckling of the tape springs and large rotations of the boom; and vibration of the boom in the latched configuration. The second phase is the most critical as the boom can fold backwards and hence interfere with other spacecraft components. A geometric optimisation study was carried out by parameterising the slot geometry in terms of slot length, width and end circle diameter. The stress-resultant based failure criterion was then used to analyse the safety of the structure. The optimisation study was focused on finding a hinge design that can be folded 180 degrees with the shortest possible slot length. Simulations have shown that the strains can be significantly reduced by allowing the end cross-sections to deform freely. Based on the simulations a failure-critical design and a failure-safe design were selected and experimentally verified. The failure-safe optimised design is six times stiffer in torsion, twice stiffer axially and stores two and a half times more strain energy than the previously considered design. Finally, an example of designing a 1 m long self-deployable boom that could be folded around a spacecraft has been presented. The safety of this two-hinge boom has been evaluated during both stowage and dynamic deployment. A safe design that latches without any overshoot was selected and validated by a dynamic deployment experiment.
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Application of Multidisciplinary Design Optimisation to Engine Calibration Optimisation.Yin, Xuefei January 2012 (has links)
Automotive engines are becoming increasingly technically complex and associated legal emissions standards more restrictive, making the task of identifying optimum actuator settings to use significantly more difficult. Given these challenges, this research aims to develop a process for engine calibration optimisation by exploiting advanced mathematical methods. Validation of this work is based upon a case study describing a steady-state Diesel engine calibration problem.
The calibration optimisation problem seeks an optimal combination of actuator settings that minimises fuel consumption, while simultaneously meeting or exceeding the legal emissions constraints over a specified drive cycle. As another engineering target, the engine control maps are required as smooth as possible.
The Multidisciplinary Design Optimisation (MDO) Frameworks have been studied to develop the optimisation process for the steady state Diesel engine calibration optimisation problem. Two MDO strategies are proposed for formulating and addressing this optimisation problem, which are All At Once (AAO), Collaborative Optimisation. An innovative MDO formulation has been developed based on the Collaborative Optimisation application for Diesel engine calibration.
Form the MDO implementations, the fuel consumption have been significantly improved, while keep the emission at same level compare with the bench mark solution provided by sponsoring company. More importantly, this research has shown the ability of MDO methodologies that manage and organize the Diesel engine calibration optimisation problem more effectively. / Jaguar Land Rover
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Numerical design optimisation for the Karoo Array TelescopeJoubert, N. J. D. 03 1900 (has links)
Thesis (MScEng (Mechanical and Mechatronic Engineering))--University of Stellenbosch, 2009. / Although mass minimisation is an important application within structural
optimisation, other applications include: (1) concept generation, (2) concept
evaluation, (3) design for structural feasibility and (4) data matching. These
applications, except data matching, are discussed and illustrated on a prototype
design of the Karoo Array Telescope (KAT) antenna. The KAT passed through
the design process and a full scale prototype was built, but was found to be too
expensive. A detailed finite element model of the finalised design was considered
as a test bed for reducing costs.
Size-, shape- and topology optimisation are applied to three KAT components,
while considering wind, temperature and gravity loads. Structural- and nonstructural
constraints are introduced. Coupling of the structural optimisation
code with an external analysis program to include non-structural responses and
the parallelisation of the sensitivity calculations are presented.
It is shown that if a finite element model is available, it is generally possible
to apply structural optimisation to improve an existing design. A reduction of
2673 kg steel was accomplished for the existing KAT components. The total cost
saving for the project will be significant, when considering that a large amount
of antennas will be manufactured.
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Design, comparison and experimental evaluation of non-overlap winding radial flux permanent magnet hub drives for electric vehiclesRix, Arnold Johan 03 1900 (has links)
Thesis (PhD (Electrical and Electronic Engineering))--University of Stellenbosch, 2011. / ENGLISH ABSTRACT: The focus of this thesis is on the optimal design, control and evaluation of 3-phase permanent
magnet radial flux synchronous machines with non-overlapping, concentrated-coil, double
layer stator windings for EV hub drive applications.
A simple analytical method is developed that can be used as a first design tool. The method
uses and predicts the MMF harmonic content for a certain pole-slot combination as well as
the harmonic content for the air gap permeance function. These harmonics are then used to
calculate the torque and torque ripple of machines with large stator slot openings and surface
mounted permanent magnets.
A different approach to calculate the iron, stator copper eddy current and magnet losses
is presented. This method specifically looks at the machine during field weakening operation
when the flux paths are changing in the machine. Flux density information throughout the
machine is extracted from a series of static FE solutions, to calculate the losses and to combine
this with an empirical formula.
Some machine topology choices are compared for use as hub drives in small electric ve-
hicles. The parameters that influence the machine design are discussed and evaluated after
a multidimensional design optimization is done and an efficient control algorithm is imple-
mented. The algorithm works through the entire operating speed range and make use of,
automatically generated, 2D look up tables to determine the correct current reference.
A stator lamination design is proposed, that combines the use of rectangular preformed
coils and semi-closed stator slots. Two prototype machines, one with a good winding factor
and the other with a low winding factor, are built and compared. The manufacturing and
testing of the two prototype machines are described and shown in detail. / AFRIKAANSE OPSOMMING: Die fokus van hierdie tesis is op die optimale ontwerp, beheer en evaluasie van 3-fase per-
manent magneet radiale vloed sinchroon masjiene met nie-oorvleuelende, gekonsentreerde,
dubbel laag stator wikkelinge vir EV hub motor toepassings.
’n Eenvoudige analitiese metode is ontwikkel wat as ’n eerste ontwerp gereedskap stuk
gebruik kan word. Die metode gebruik en voorspel die MMF se frekwensie inhoud vir ’n
sekere pool-gleuf kombinasie sowel as die frekwensie inhoud vir die lug spleet permeansie
funksie. Hierdie frekwensie inhoud word dan gebruik om die draaimoment en draaimoment
riffel van masjiene met groot stator gleuf openinge en oppervlak magnete te voorspel.
’n Ander benadering om yster, stator koper werwel stroom en magneet verliese te bepaal
word voorgestel. Hierdie metode kyk spesifiek na masjiene onder veld verswakking beheer
wanneer die vloed paaie verander vanaf die normale. Die vloeddigtheid, regdeur die masjien,
word verkry deur om van ’n reeks statiese eindige element oplossings gebruik te maak en dit
te kombineer met ’n empiriese verliesberekening.
Die parameters wat die masjienontwerp beïnvloed, word bespreek en geëvalueer na ’n mul-
tidimensionele ontwerp optimering gedoen is en ’n effektiewe beheer algoritme geïmplimen-
teer is. Die algoritme werk vir enige spoed en is gebaseer op die outomaties gegenereerde 2D
opsoek tabelle wat die korrekte stroomverwysing gee.
’n Stator laminasie ontwerp word voorgestel wat die gebruik van vooraf vervaardigde
spoele en gedeeltelik toe stator gleuwe moontlik maak. Twee prototipe masjiene, een met ’n
goeie windingsfaktor en een met ’n swakker windingsfaktor is gebou en vergelyk. Die ver-
vaardiging en toetsing van die twee prototipe masjiene word in detail beskryf en gewys.
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