Refine
Document Type
- Doctoral Thesis (18) (remove)
Institute
- Institut für Europäische Urbanistik (3)
- Institut für Strukturmechanik (ISM) (2)
- Professur Geschichte und Theorie der Kulturtechniken (2)
- Promotionsstudiengang Kunst und Design-Freie Kunst-Medienkunst (Ph.D) (2)
- Professur Baubetrieb und Bauverfahren (1)
- Professur Baustatik und Bauteilfestigkeit (1)
- Professur Denkmalpflege und Baugeschichte (1)
- Professur Interface Design (1)
- Professur Massivbau II (1)
- Professur Siedlungswasserwirtschaft (1)
Keywords
- ASR (1)
- Abjekt (1)
- Alkali-silica reaction (1)
- Architekturtheorie (1)
- BIM (1)
- Bauklimatik (1)
- Bauphysik (1)
- Beton (1)
- Bildwissenschaft (1)
- Boltanski, Christian (1)
Year of publication
- 2014 (18) (remove)
Exploratory Research into Transformation Processes of Former Industrial Complexes of Leipziger Baumwollspinnerei (Leipzig) and Mattatoio di Testaccio (Rome); New Meanings of Industrial Heritage
Physical manifestations of the Industrial Revolution left a permanent imprint on the complexion of cities. Abandonment that followed the deindustrialization contributed to an estrangement, turning derelict industrial spaces and run‐down factories into a ballast to conjure with. At present, industrial heritage management applies flexibility and creativity, partially overcoming the essentially traditional paradigm of heritage preservation. This approach permits sustainable conservation – utilization and integration of disused industrial constructs in the contemporary urban landscape. Being a part of the European cultural stock, industrial heritage is an exciting and unique setting from many perspectives. It is defined and consumed by many markets, ranging from the industrial heritage tourism to the market of special events and festivals. Reused industrial buildings and factories come into view as products of post‐industrial societies, fitting to the Western post‐industrial (consumer) culture, offering a field of activities that are at an interface between the industrial history and contemporary socio‐cultural milieu.
Alteration of values, growth of new roles and definitions of industrial heritage, generated by functional restructuring, is a subject which is often left behind the general discussion about sustainable conservation and adaptive reuse of industrial heritage. Yet, in the modified state, industrial heritage is very complex to understand and to define.
By conducting a desk and a case study research of former industrial complexes – Leipziger Baumwollspinnerei and Mattatoio di Testaccio, this doctoral thesis aims to identify industrial heritage as a contemporary (post‐industrial) concept. Observation of ideas, values and definitions that emerge as a consequence of the transformation and re‐conceptualization of industrial heritage are intended to raise awareness and appreciation of industrial heritage in the full richness of its contemporary interpretation.
This research represents an effort made towards contribute to the critical thinking from an analysis of the hegemonic neoliberal ideology, which supports the idea of the end of history and the technocratic universalism which in turn implies the imposition of a single model of life, denying, in the name of realism and the end of utopias, any other alternative possibility.
This makes it necessary to recover the critical thinking to analyze and understand the reality, thus overcoming the ideological barrier towards claiming that things can be otherwise.
It is clear from this research that the discourse of sustainable development has unquestionably transformed the context and content of political activity in Europe. This discourse has exercised and obvious influence in the Governance processes, mainly because it has contributed to the introduction of a new political field, which was then promoted, either explicitly or implicitly by policy-makers, researchers on the field and practitioners during the last three decades. Though it may be bold to affirm that the discourse of sustainable development is the sole driver of these whole set of changes, there is no doubt that it has played a key part in the way in which the governance priorities have been handled in the European continent.
A fundamental characteristic of human beings is the desire to start learning at the moment of birth. The rather formal learning process that learners have to deal with in school, on vocational training or in university, is currently subject to fundamental changes. The increasing technologization, overall existing mobile devices, the ubiquitous access to digital information, and students being early adaptors of all these technological innovations require reactions on the part of the educational system.
This study examines such a reaction: The use of mobile learning in higher education.
Examining the subject m-learning first requires an investigation of the educational model e-learning. Many universities already established e-learning as one of their educational segments, providing a wide range of methods to support this kind of teaching.
This study includes an empirical acceptance analysis regarding the general learning behavior of students and their approval of e-learning methods. A survey on the approval of m-learning supplements the results.
Mobile learning is characterized by both the mobility of the communication devices and the users. Both factors lead to new correlations, demonstrate the potential of today's mobile devices and the probability to increase the learning performance.
The dissertation addresses these correlations and the use of mobile devices in the context of m-learning. M-learning and the usage of mobile devices not only require a reflection from a technological point of view. In addition to the technical features of such mobile devices, the usability of their applications plays an important role, especially with regard to the limited display size.
For the purpose of evaluating mobile apps and browser-based applications, various analytical methods are suitable.
The concluding heuristic evaluation points out the vulnerability of an established m-learning application, reveals the need for improvement, and shows an approach to rectify the shortcoming.
This thesis concerns the physical and mechanical interactions on carbon nanotubes and polymers by multiscale modeling. CNTs have attracted considerable interests in view of their unique mechanical, electronic, thermal, optical and structural properties, which enable them to have many potential applications.
Carbon nanotube exists in several structure forms, from individual single-walled carbon nanotubes (SWCNTs) and multi-walled carbon nanotubes (MWCNTs) to carbon nanotube bundles and networks. The mechanical properties of SWCNTs and MWCNTs have been extensively studied by continuum modeling and molecular dynamics (MD) simulations in the past decade since the properties could be important in the CNT-based devices. CNT bundles and networks feature outstanding mechanical performance and hierarchical structures and network topologies, which have been taken as a potential saving-energy material. In the synthesis of nanocomposites, the formation of the CNT bundles and networks is a challenge to remain in understanding how to measure and predict the properties of such large systems. Therefore, a mesoscale method such as a coarse-grained (CG) method should be developed to study the nanomechanical characterization of CNT bundles and networks formation.
In this thesis, the main contributions can be written as follows: (1) Explicit solutions for the cohesive energy between carbon nanotubes, graphene and substrates are obtained through continuum modeling of the van der Waals interaction between them. (2) The CG potentials of SWCNTs are established by a molecular mechanics model. (3) The binding energy between two parallel and crossing SWCNTs and MWCNTs is obtained by continuum modeling of the van der Waals interaction between them. Crystalline and amorphous polymers are increasingly used in modern industry as tructural materials due to its important mechanical and physical properties. For crystalline polyethylene (PE), despite its importance and the studies of available MD simulations and continuum models, the link between molecular and continuum descriptions of its mechanical properties is still not well established. For amorphous polymers, the chain length and temperature effect on their
elastic and elastic-plastic properties has been reported based on the united-atom (UA) and CG MD imulations in our previous work. However, the effect of the CL and temperature on the failure behavior is not understood well yet. Especially, the failure behavior under shear has been scarcely reported in previous work. Therefore, understanding the molecular origins of macroscopic fracture behavior such as fracture energy is a fundamental scientific challenge.
In this thesis, the main contributions can be written as follows: (1) An analytical molecular mechanics model is developed to obtain the size-dependent elastic properties of crystalline PE.
(2) We show that the two molecular mechanics models, the stick-spiral and the beam models, predict considerably different mechanical properties of materials based on energy equivalence. The difference between the two models is independent of the materials. (3) The tensile and shear failure behavior dependence on chain length and temperature in amorphous polymers are scrutinized using molecular dynamics simulations. Finally, the influence of polymer wrapped two neighbouring SWNTs’ dispersion on their load transfer is investigated by molecular dynamics (MD) simulations, in which the SWNTs' position, the polymer chain length and the temperature on the interaction force is systematically studied.
Alkali-silica reaction causes major problems in concrete structures due to the rapidity of its deformation which leads to the serviceability limit of the structure being reached well before its time. Factors that affect ASR vary greatly, including alkali and silica content, relative humidity, temperature and porosity of the cementitious matrix,all these making it a very complex phenomenon to consider explicitly. With this in mind, the finite element technique was used to build models and generate expansive pressures and damage propagation due to ASR under the influence of thermo-hygrochemoelastic loading. Since ASR initializes in the mesoscopic regions of the concrete,
the accumulative effects of its expansion escalates onto the macroscale level with the development of web cracking on the concrete surface, hence solution of the damage model as well as simulation of the ASR phenomenon at both the macroscale and mesoscale levels have been performed. The macroscale model realizes the effects of ASR expansion as a whole and shows how it develops under the influence of moisture, thermal and mechanical loading. Results of the macroscale modeling are
smeared throughout the structure and are sufficient to show how damage due to ASR expansion orientates. As opposed to the mesoscale model, the heterogeneity of the model shows us how difference in material properties between aggregates and the cementitious matrix facilitates ASR expansion. With both these models, the ASR phenomenon under influence of thermo-chemo-hygro-mechanical loading can be better understood.
Die Dissertation Staubaufwirbeln oder die Kunst der Partizipation stellt die Frage, ob und inwiefern künstlerische Interventionen zur Aktualisierung und Entwicklung demokratischer Teilhabe beitragen können. Im Zentrum der Untersuchung stehen sechs Projektgruppen, die experimentelle Freiräume gestalten, in denen neue Formen von Demokratielernen, Stadtnutzung, gesellschaftlicher Repräsentation und Symbolpolitik erprobt werden. Die Kunst der Partizipation wird in fünf Dimensionen beschrieben: Initiative, Kollektivität, Inszenierung, Öffentlichkeit und Kooperation. Sie erweitert damit das Repertoire demokratischer Beteiligungsformen sowie gegenwärtige Kunstbegriffe. Ihre heimliche Relevanz besteht darin, sich immer wieder dem Risiko auszusetzen, von allen Seiten als unzureichend betrachtet zu werden. Demokratie konstituiert sich hier als ästhetische Erfahrung. Die Kunst besteht darin, die Flüchtigkeit demokratischer Teilhabe erfahrbar zu machen, also gestaltbar und veränderbar.
Structural vibration control of high-speed railway bridges using tuned mass dampers, semi-active tuned mass dampers, fluid viscous dampers and magnetorheological dampers to reduce resonant structural vibrations is studied. In this work, the addressed main issues include modeling of the dynamic interaction of the structures, optimization of the parameters of the dampers and comparison of their efficiency.
A new approach to optimize multiple tuned mass damper systems on an uncertain model is proposed based on the H-infinity optimization criteria and the DK iteration procedure with norm-bounded uncertainties in frequency domain. The parameters of tuned mass dampers are optimized directly and simultaneously on different modes contributing significantly to the multi-resonant peaks to explore the different possible combinations of parameters. The effectiveness of the present method is also evaluated through comparison with a previous method.
In the case of semi-active tuned mass dampers, an optimization algorithm is derived to control the magnetorheological damper in these semi-active damping systems. The use of the proposed algorithm can generate various combinations of control gains and state variables. This can lead to the improvement of the ability of MR dampers to track the desired control forces. An uncertain model to reduce detuning effects is also considered in this work.
Next, for fluid viscous dampers, in order to tune the optimal parameters of fluid viscous dampers to the vicinity of the exact values, analytical formulae which can include structural damping are developed based on the perturbation method. The proposed formulae can also be considered as an improvement of the previous analytical formulae, especially for bridge beams with large structural damping.
Finally, a new combination of magnetorheological dampers and a double-beam system to improve the performance of the primary structure vibration is proposed. An algorithm to control magnetorheological dampers in this system is developed by using standard linear matrix inequality techniques. Weight functions as a loop shaping procedure are also introduced in the feedback controllers to improve the tracking ability of magnetorheological damping forces. To this end, the effectiveness of magnetorheological dampers controlled by the proposed scheme, along with the effects of the uncertain and time-delay parameters on the models, are evaluated through numerical simulations.
Additionally, a comparison of the dampers based on their performance is also considered in this work.
Druckbeanspruchte Bauteile aus Beton können mit zugfesten Umschnürungen von außen verstärkt werden. Mit dieser etablierten Methode konnten axiale Traglast und Duktilität von unzureichend bewehrten Stützen bereits verbessert werden. Es wurde jedoch festgestellt, dass der umschnürte Betonkern dennoch an Festigkeit verliert. Um die Wirksamkeit der Umschnürung zu erhöhen, wird deshalb vorgeschlagen, das umschnürende Material vorzuspannen. Dieser Vorschlag wird insbesondere von der neuen Materialgruppe der Formgedächtnislegierungen inspiriert, die thermisch vorspannbar sind.
Bisher sind die Auswirkungen der Vorspannung einer Umschnürung auf das Tragverhalten von Betondruckgliedern kaum untersucht worden. Diese Lücke wird durch systematische Versuche an Betonzylindern mit vorgespannter Umschnürung aus Stahl und kohlenstofffaserverstärktem Kunststoff geschlossen. Die Abbildung der Versuchsergebnisse durch geeignete Modelle ermöglicht auch Aussagen zum Verhalten von Betondruckgliedern mit Umschnürungen aus anderen Materialien, beispielsweise Formgedächtnislegierungen. Um diese in den Berechnungen zu simulieren, wird eine für das Bauwesen infrage kommende eisenbasierte Legierung in separaten axialen Versuchen charakterisiert und thermisch vorgespannt. Die in der vorliegenden Arbeit entwickelten neuen Modelle orientieren sich im Wesentlichen an zwei Zielen: dem Abbilden des mehraxialen Spannungs-Dehnungs-Verhaltens des vorgespannt umschnürten Betons und dem Berechnen der Restfestigkeit des Betons.
Die durchgeführten Versuche und Parameterstudien auf Basis der Modelle zeigen: Die Vorspannung der Umschnürung beeinflusst vor allem die Restfestigkeit des Betons wesentlich. Die gewonnenen Erkenntnisse und neuen Methoden können eingesetzt werden, um das Tragverhalten von Betondruckgliedern mit Umschnürungen aus Stahl, faserverstärktem Kunststoff oder Formgedächtnislegierungen zu bewerten.