Oxymoron,progetto di un grattacielo direzionale a Shenzhen, Cina applicazione della Soft Kill Option (SKO) nella progettazione architettonica

Lo scopo della tesi è quello di affrontare la progettazione con un approccio,quanto più attuale e per certi versi avanguardista, chiamato Parametric design (progettazione parametrica), accoppiato efficacemente col concetto di Arte generativa (in questo caso Architettura). Già nel 1957 Luigi Moretti affrontò il tema dell’architettura parametrico-generativa fondando l’IRMOU (Istituto per la Ricerca Matematica e Operativa applicata all'Urbanistica) e oggi è una mentalità molto diffusa nei più grandi studi del mondo. Il tema non è solo tecnologico o informatico strumentale, ma è proprio un modo di pensare e immaginare il possibile, costruito o naturale che sia. E’ un modo di vivere la propria creatività. L’aggettivo “generativa” è legato al fatto che l’arte in esame è generata seguendo regole preimpostate e ben definite dal progettista, coerentemente agli obiettivi e alle finalità del progetto. L’evoluzione delle stesse, seguendo relazioni molto semplici, può dar vita a risultati sorprendenti e inaspettati, dotati di una notevole complessità che però, se letta nell’insieme, è perfettamente in armonia con l’idea progettuale di partenza. Il fascino di questa materia è il legame entusiasmante che crea tra architettura, ingegneria, poesia, filosofia, matematica, biologia, fisica, pittura ecc ecc. Questo perché i concetti di evoluzione, di relazione e di generazione appartengono a tutto ciò che ci circonda, e quindi alla concezione umana di vita. E’ possibile in questo modo permeare il costrutto progettuale con principi e regole oggettivamente riconoscibili e apprezzabili dallo spettatore perché instrisi di una forte veridicità processuale. Il titolo "Oxymoron" è la traduzione inglese della figura retorica ossimoro,la quale è strettamente connessa all’ispirazione progettuale: proviene dall’indagine approfondita di processi evolutivi (distruttivi in questo caso) caratterizzanti realtà naturali che, esplorate con sempre più accuratezza, determinano morfologie e forme aventi profonde radici strutturali. La distruzione che crea lo spazio. La genesi stessa della forma segue predominanti algoritmi matematici governati e corretti da variabili di diversa natura che definiscono l'enviroment di influenze interagenti ed agenti sul campione di studio. In questo caso la ricerca è focalizzata su processi erosivi fisici e chimici, di agenti esterni (quali vento e sali rispettivamente) ,di cui materiali inorganici, quali minerali e aggregati degli stessi (rocce), sono soggetti. In particolare, l’interesse è approfondito su fenomeni apparentemente emergenti dei tafoni e dei cosiddetti Micro canyon. A tal scopo si sfrutterà un metodo di soft kill option (SKO) di ottimizzazione topologica (optimization topology) attraverso gli strumenti informatici più idonei quali software di modellazione parametrica e di calcolo computazionale. La sperimentazione sta proprio nell'utilizzare uno strumento concepito per uno scopo, con un'ottica strettamente ingegneristica, per un'altra meta, ossia ricavare e ottenere se possibile un metodo di lavoro o anche solo un processo generativo tale da riprodurre o simulare casi e situazioni riscontrabili in natura negli eventi soggetti a erosione. Il tutto coerente con le regole che stanno alla base della genesi degli stessi. Il parallelismo tra singolarità naturale e architettura risiede nella generazione degli spazi e nella combinazione di questi. L’ambizioso obiettivo è quello di innescare un ciclo generativo, che messo in comunicazione diretta con un contesto variegato ed eterogeneo, dia vita a una soluzione progettuale dall'alto contenuto morfologico e spaziale.

"Offshore tower or platform foundations: numerical analysis of a laterally loaded single pile or pile group in soft clay and analysis of actions on a jacket structure"

Laterally loaded piles are a typical situation for a large number of cases in which deep foundations are used. Dissertation herein reported, is a focus upon the numerical simulation of laterally loaded piles. In the first chapter the best model settings are largely discussed, so a clear idea about the effects of interface adoption, model dimension, refinement cluster and mesh coarseness is reached. At a second stage, there are three distinct parametric analyses, in which the model response sensibility is studied for variation of interface reduction factor, Eps50 and tensile cut-off. In addition, the adoption of an advanced soil model is analysed (NGI-ADP). This was done in order to use the complex behaviour (different undrained shear strengths are involved) that governs the resisting process of clay under short time static loads. Once set a definitive model, a series of analyses has been carried out with the objective of defining the resistance-deflection (P-y) curves for Plaxis3D (2013) data. Major results of a large number of comparisons made with curves from API (America Petroleum Institute) recommendation are that the empirical curves have almost the same ultimate resistance but a bigger initial stiffness. In the second part of the thesis a simplified structural preliminary design of a jacket structure has been carried out to evaluate the environmental forces that act on it and on its piles foundation. Finally, pile lateral response is studied using the empirical curves.

Safety factors in sheet pile wall design: considerations by using traditional methods and FEM analysis

The purpose of the work is: define and calculate a factor of collapse related to traditional method to design sheet pile walls. Furthermore, we tried to find the parameters that most influence a finite element model representative of this problem. The text is structured in this way: from chapter 1 to 5, we analyzed a series of arguments which are usefull to understanding the problem, while the considerations mainly related to the purpose of the text are reported in the chapters from 6 to 10. In the first part of the document the following arguments are shown: what is a sheet pile wall, what are the codes to be followed for the design of these structures and what they say, how can be formulated a mathematical model of the soil, some fundamentals of finite element analysis, and finally, what are the traditional methods that support the design of sheet pile walls. In the chapter 6 we performed a parametric analysis, giving an answer to the second part of the purpose of the work. Comparing the results from a laboratory test for a cantilever sheet pile wall in a sandy soil, with those provided by a finite element model of the same problem, we concluded that:in modelling a sandy soil we should pay attention to the value of cohesion that we insert in the model (some programs, like Abaqus, don’t accept a null value for this parameter), friction angle and elastic modulus of the soil, they influence significantly the behavior of the system (structure-soil), others parameters, like the dilatancy angle or the Poisson’s ratio, they don’t seem influence it. The logical path that we followed in the second part of the text is reported here. We analyzed two different structures, the first is able to support an excavation of 4 m, while the second an excavation of 7 m. Both structures are first designed by using the traditional method, then these structures are implemented in a finite element program (Abaqus), and they are pushed to collapse by decreasing the friction angle of the soil. The factor of collapse is the ratio between tangents of the initial friction angle and of the friction angle at collapse. At the end, we performed a more detailed analysis of the first structure, observing that, the value of the factor of collapse is influenced by a wide range of parameters including: the value of the coefficients assumed in the traditional method and by the relative stiffness of the structure-soil system. In the majority of cases, we found that the value of the factor of collapse is between and 1.25 and 2. With some considerations, reported in the text, we can compare the values so far found, with the value of the safety factor proposed by the code (linked to the friction angle of the soil).

Evolution of the structural and fracture design of the ISS payloads due to the new launchers, specifically applied to Biolab IEC-2 projects

The relatively young discipline of astronautics represents one of the scientifically most fascinating and technologically advanced achievements of our time. The human exploration in space does not offer only extraordinary research possibilities but also demands high requirements from man and technology. The space environment provides a lot of attractive experimental tools towards the understanding of fundamental mechanism in natural sciences. It has been shown that especially reduced gravity and elevated radiation, two distinctive factors in space, influence the behavior of biological systems significantly. For this reason one of the key objectives on board of an earth orbiting laboratory is the research in the field of life sciences, covering the broad range from botany, human physiology and crew health up to biotechnology. The Columbus Module is the only European low gravity platform that allows researchers to perform ambitious experiments in a continuous time frame up to several months. Biolab is part of the initial outfitting of the Columbus Laboratory; it is a multi-user facility supporting research in the field of biology, e.g. effect of microgravity and space radiation on cell cultures, micro-organisms, small plants and small invertebrates. The Biolab IEC are projects designed to work in the automatic part of Biolab. In this moment in the TO-53 department of Airbus Defence & Space (formerly Astrium) there are two experiments that are in phase C/D of the development and they are the subject of this thesis: CELLRAD and CYTOSKELETON. They will be launched in soft configuration, that means packed inside a block of foam that has the task to reduce the launch loads on the payload. Until 10 years ago the payloads which were launched in soft configuration were supposed to be structural safe by themselves and a specific structural analysis could be waived on them; with the opening of the launchers market to private companies (that are not under the direct control of the international space agencies), the requirements on the verifications of payloads are changed and they have become much more conservative. In 2012 a new random environment has been introduced due to the new Space-X launch specification that results to be particularly challenging for the soft launched payloads. The last ESA specification requires to perform structural analysis on the payload for combined loads (random vibration, quasi-steady acceleration and pressure). The aim of this thesis is to create FEM models able to reproduce the launch configuration and to verify that all the margins of safety are positive and to show how they change because of the new Space-X random environment. In case the results are negative, improved design solution are implemented. Based on the FEM result a study of the joins has been carried out and, when needed, a crack growth analysis has been performed.

Microchannel heat exchangers: An attractive option for the regenerator of a mobile orc waste heat recovery system

The performance of microchannel heat exchangers was assessed in gas-to-liquid applications in the order of several tens of kWth . The technology is suitable for exhaust heat recovery systems based on organic Rankine cycle. In order to design a light and compact microchannel heat exchanger, an optimization process is developed. The model employed in the procedure is validated through computational fluid-dynamics analysis with commercial software. It is shown that conjugate effects have a significant impact on the heat transfer performance of the device.

Computational design of a new type of sandwich cross-section for a defined solution of a tree-like column produced by wire-and-arc additive manufacturing

When it comes to designing a structure, architects and engineers want to join forces in order to create and build the most beautiful and efficient building. From finding new shapes and forms to optimizing the stability and the resistance, there is a constant link to be made between both professions. In architecture, there has always been a particular interest in creating new shapes and types of a structure inspired by many different fields, one of them being nature itself. In engineering, the selection of optimum has always dictated the way of thinking and designing structures. This mindset led through studies to the current best practices in construction. However, both disciplines were limited by the traditional manufacturing constraints at a certain point. Over the last decades, much progress was made from a technological point of view, allowing to go beyond today's manufacturing constraints. With the emergence of Wire-and-Arc Additive Manufacturing (WAAM) combined with Algorithmic-Aided Design (AAD), architects and engineers are offered new opportunities to merge architectural beauty and structural efficiency. Both technologies allow for exploring and building unusual and complex structural shapes in addition to a reduction of costs and environmental impacts. Through this study, the author wants to make use of previously mentioned technologies and assess their potential, first to design an aesthetically appreciated tree-like column with the idea of secondly proposing a new type of standardized and optimized sandwich cross-section to the construction industry. Parametric algorithms to model the dendriform column and the new sandwich cross-section are developed and presented in detail. A catalog draft of the latter and methods to establish it are then proposed and discussed. Finally, the buckling behavior of this latter is assessed considering standard steel and WAAM material properties.