@article{JentschKulleBodeetal.,
  author    = {Jentsch, Mark F. and Kulle, Christoph and Bode, Tobias and Pauer, Toni and Osburg, Andrea and Namgyel, Karma and Euthra, Karma and Dukjey, Jamyang and Tenzin, Karma},
  title     = {Field study of the building physics properties of common building types in the Inner Himalayan valleys of Bhutan},
  series = {Energy for Sustainable Development 38},
  journal   = {Energy for Sustainable Development 38},
  doi       = {10.25643/bauhaus-universitaet.3139},
  url       = {http://nbn-resolving.de/urn:nbn:de:gbv:wim2-20170419-31393},
  pages     = {48 -- 66},
  abstract  = {Traditionally, buildings in the Inner Himalayan valleys of Bhutan were constructed from rammed earth in the western regions and quarry stone in the central and eastern regions. Whilst basic architectural design elements have been retained, the construction methods have however changed over recent decades alongside expectations for indoor thermal comfort. Nevertheless, despite the need for space heating, thermal building performance remains largely unknown. Furthermore, no dedicated climate data is available for building performance assessments. This paper establishes such climatological information for the capital Thimphu and presents an investigation of building physics properties of traditional and contemporary building types. In a one month field study 10 buildings were surveyed, looking at building air tightness, indoor climate, wall U-values and water absorption of typical wall construction materials. The findings highlight comparably high wall U-values of 1.0 to 1.5 W/m²K for both current and historic constructions. Furthermore, air tightness tests show that, due to poorly sealed joints between construction elements, windows and doors, many buildings have high infiltration rates, reaching up to 5 air changes per hour. However, the results also indicate an indoor climate moderating effect of more traditional earth construction techniques. Based on these survey findings basic improvements are being suggested.},
  subject      = {Luftdichtheit},
  language  = {en}
}
@phdthesis{Heidenreich,
  author    = {Heidenreich, Manuel},
  title     = {Untersuchungen zur Sauerstoffbereitstellung mit Perowskit- Keramik-Sch{\"u}ttungen in einem Festbett-Reaktor},
  doi       = {10.25643/bauhaus-universitaet.3607},
  url       = {http://nbn-resolving.de/urn:nbn:de:gbv:wim2-20171027-36077},
  school      = {Bauhaus-Universit{\"a}t Weimar},
  pages     = {154},
  abstract  = {Diese Arbeit belegt, dass die Belastungen auf reversibel arbeitende keramische Materialien sehr gering ausfallen. Die regenerative Sauerstoffbereitstellung stellt damit grunds{\"a}tzlich niedrigere Anforderungen an die keramischen Perowskit-Materialien zur Sauerstofferzeugung als die Membrantechnologie. Das Absinken der Diffusionskoeffizienten bei niedrigen Temperaturen ist deutlich weniger nachteilig als bei den Membranen die vergleichbare Materialien nutzen. Dies konnte gezeigt werde, indem mit der die O 2 -Entladetechnik und -Beladetechnik im Vergleich zur O 2 -Abtrennung durch keramische Membranen bei vergleichsweise niedrigen Temperaturen bereits große O 2 -Mengen erzeugt werden k{\"o}nnen. Infolge der niedrigen Temperaturen bestehen keine Probleme mit Reaktionen zwischen dem sauerstoffbereitstellenden Material und den Reaktorwerkstoffen. Dadurch gestaltet sich die Einbindung und Nutzung von Festbett-Sch{\"u}ttungen denkbar einfach. Im Vergleich dazu sind die Anbindung und der Betrieb von d{\"u}nnen keramischen Membranen in einem Reaktor deutlich aufwendiger. Es ist weniger Peripherie und verfahrenstechnischer Aufwand zur Sauerstoffabtrennung durch reversibel arbeitende Materialien n{\"o}tig als bei der kryogenen Luftzerlegung, der Druckwechseladsorption oder den Membrantechnologien. Die regenerative Sauerstoffbereitstellung kann sowohl bei neuen als auch bestehenden Anlagen, die Sauerstoff ben{\"o}tigen implementiert werden. Damit ist es m{\"o}glich den Transport des Sauerstoffs entfallen zu lassen. Eine partielle Phasenumwandlung des BSCF8020 bei erh{\"o}hter Temperatur und hohem Sauerstoffangebot spielt f{\"u}r die regenerative Sauerstoffbereitstellung eine untergeordnete Rolle, da die n{\"o}tigen Zieltemperaturen (450 ggf. bis 650 °C) zur O 2 -Beladung und -Entladung niedriger sind, als der Temperaturbereich in dem die Zersetzung auftreten kann (750 bis 800 °C). Des Weiteren ist die Zeitspanne (O 2 -Beladungsteilzyklus) in der das BSCF8020 ausreichend hohen Sauerstoffgehalten (p O2 > 10 -3 bar) ausgesetzt ist, zu kurz um diese Umwandlungen zu vollziehen. Der O 2 -Entladungsteilzyklus sorgt zus{\"a}tzlich immer daf{\"u}r, dass sich u. U. beginnende Zersetzung zur{\"u}ckbildet, da die kubische Phase in Richtung niedrigerer p O2 stabilisiert wird. Es konnte belegt werden, dass die elektronische Steuerung des zyklischen Sauerstoffausbaus und -einbaus beherrschbar ist. Der hohe Abtrenngrad der keramischen Materialien f{\"u}hrt dazu, dass der Sauerstoff elektrolytisch rein zu Verf{\"u}gung gestellt wird. Grunds{\"a}tzlich sind weitere Forschungen zur Steigerung der Sauerstoffmengen, die pro eingesetzter Masseeinheit an Keramik gewonnen werden k{\"o}nnen, immer anzustreben, da damit u. U. der Materialeinsatz weiter gesenkt oder auch die energetischen Aufwendungen weiter reduziert werden k{\"o}nnen. Bei dem, f{\"u}r die multizyklischen Untersuchungen dieser Arbeit ausgew{\"a}hlten BSCF8020(SVT) hat die Cobalt-Komponente mit ca. 80 \% den {\"u}berwiegenden Kostenanteil am Sauerstoff bereitstellenden Material. BSCF-Keramiken mit h{\"o}herem Eisen-Anteil sollten f{\"u}r multizyklische Anwendungen in Festbett-Reaktoren einer vertiefenden Charakterisierung unterzogen werden, um weitere geeignete Perowskite mit niedrigen Materialkosten zu erschließen.},
  subject      = {Perowskit},
  language  = {de}
}
@phdthesis{Abeltshauser,
  author    = {Abeltshauser, Rainer},
  title     = {Identification and separation of physical effects of coupled systems by using defined model abstractions},
  doi       = {10.25643/bauhaus-universitaet.2860},
  url       = {http://nbn-resolving.de/urn:nbn:de:gbv:wim2-20170314-28600},
  school      = {Bauhaus-Universit{\"a}t Weimar},
  abstract  = {The thesis investigates at the computer aided simulation process for operational vibration analysis of complex coupled systems. As part of the internal methods project "Absolute Values" of the BMW Group, the thesis deals with the analysis of the structural dynamic interactions and excitation interactions. The overarching aim of the methods project is to predict the operational vibrations of engines. Simulations are usually used to analyze technical aspects (e. g. operational vibrations, strength, ...) of single components in the industrial development. The boundary conditions of submodels are mostly based on experiences. So the interactions with neighboring components and systems are neglected. To get physically more realistic results but still efficient simulations, this work wants to support the engineer during the preprocessing phase by useful criteria. At first suitable abstraction levels based on the existing literature are defined to identify structural dynamic interactions and excitation interactions of coupled systems. So it is possible to separate different effects of the coupled subsystems. On this basis, criteria are derived to assess the influence of interactions between the considered systems. These criteria can be used during the preprocessing phase and help the engineer to build up efficient models with respect to the interactions with neighboring systems. The method was developed by using several models with different complexity levels. Furthermore, the method is proved for the application in the industrial environment by using the example of a current combustion engine.},
  subject      = {Strukturdynamik},
  language  = {en}
}
@phdthesis{Schwedler,
  author    = {Schwedler, Michael},
  title     = {Integrated structural analysis using isogeometric finite element methods},
  doi       = {10.25643/bauhaus-universitaet.2737},
  url       = {http://nbn-resolving.de/urn:nbn:de:gbv:wim2-20170130-27372},
  school      = {Bauhaus-Universit{\"a}t Weimar},
  pages     = {209},
  abstract  = {The gradual digitization in the architecture, engineering, and construction industry over the past fifty years led to an extremely heterogeneous software environment, which today is embodied by the multitude of different digital tools and proprietary data formats used by the many specialists contributing to the design process in a construction project. Though these projects become increasingly complex, the demands on financial efficiency and the completion within a tight schedule grow at the same time. The digital collaboration of project partners has been identified as one key issue in successfully dealing with these challenges. Yet currently, the numerous software applications and their respective individual views on the design process severely impede that collaboration. An approach to establish a unified basis for the digital collaboration, regardless of the existing software heterogeneity, is a comprehensive digital building model contributed to by all projects partners. This type of data management known as building information modeling (BIM) has many benefits, yet its adoption is associated with many difficulties and thus, proceeds only slowly. One aspect in the field of conflicting requirements on such a digital model is the cooperation of architects and structural engineers. Traditionally, these two disciplines use different abstractions of reality for their models that in consequence lead to incompatible digital representations thereof. The onset of isogeometric analysis (IGA) promised to ease the discrepancy in design and analysis model representations. Yet, that initial focus quickly shifted towards using these methods as a more powerful basis for numerical simulations. Furthermore, the isogeometric representation alone is not capable of solving the model abstraction problem. It is thus the intention of this work to contribute to an improved digital collaboration of architects and engineers by exploring an integrated analysis approach on the basis of an unified digital model and solid geometry expressed by splines. In the course of this work, an analysis framework is developed that utilizes such models to automatically conduct numerical simulations commonly required in construction projects. In essence, this allows to retrieve structural analysis results from BIM models in a fast and simple manner, thereby facilitating rapid design iterations and profound design feedback. The BIM implementation Industry Foundation Classes (IFC) is reviewed with regard to its capabilities of representing the unified model. The current IFC schema strongly supports the use of redundant model data, a major pitfall in digital collaboration. Additionally, it does not allow to describe the geometry by volumetric splines. As the pursued approach builds upon a unique model for both, architectural and structural design, and furthermore requires solid geometry, necessary schema modifications are suggested. Structural entities are modeled by volumetric NURBS patches, each of which constitutes an individual subdomain that, with regard to the analysis, is incompatible with the remaining full model. The resulting consequences for numerical simulation are elaborated in this work. The individual subdomains have to be weakly coupled, for which the mortar method is used. Different approaches to discretize the interface traction fields are implemented and their respective impact on the analysis results is evaluated. All necessary coupling conditions are automatically derived from the related geometry model. The weak coupling procedure leads to a linear system of equations in saddle point form, which, owed to the volumetric modeling, is large in size and, the associated coefficient matrix has, due to the use of higher degree basis functions, a high bandwidth. The peculiarities of the system require adapted solution methods that generally cause higher numerical costs than the standard procedures for symmetric, positive-definite systems do. Different methods to solve the specific system are investigated and an efficient parallel algorithm is finally proposed. When the structural analysis model is derived from the unified model in the BIM data, it does in general initially not meet the requirements on the discretization that are necessary to obtain sufficiently accurate analysis results. The consequently necessary patch refinements must be controlled automatically to allowfor an entirely automatic analysis procedure. For that purpose, an empirical refinement scheme based on the geometrical and possibly mechanical properties of the specific entities is proposed. The level of refinement may be selectively manipulated by the structural engineer in charge. Furthermore, a Zienkiewicz-Zhu type error estimator is adapted for the use with isogeometric analysis results. It is shown that also this estimator can be used to steer an adaptive refinement procedure.},
  subject      = {Finite-Elemente-Methode},
  language  = {en}
}
@phdthesis{Msekh,
  author    = {Msekh, Mohammed Abdulrazzak},
  title     = {Phase Field Modeling for Fracture with Applications to Homogeneous and Heterogeneous Materials},
  doi       = {10.25643/bauhaus-universitaet.3229},
  url       = {http://nbn-resolving.de/urn:nbn:de:gbv:wim2-20170615-32291},
  school      = {Bauhaus-Universit{\"a}t Weimar},
  pages     = {190},
  abstract  = {The thesis presents an implementation including different applications of a variational-based approach for gradient type standard dissipative solids. Phase field model for brittle fracture is an application of the variational-based framework for gradient type solids. This model allows the prediction of different crack topologies and states. Of significant concern is the application of theoretical and numerical formulation of the phase field modeling into the commercial finite element software Abaqus in 2D and 3D. The fully coupled incremental variational formulation of phase field method is implemented by using the UEL and UMAT subroutines of Abaqus. The phase field method considerably reduces the implementation complexity of fracture problems as it removes the need for numerical tracking of discontinuities in the displacement field that are characteristic of discrete crack methods. This is accomplished by replacing the sharp discontinuities with a scalar damage phase field representing the diffuse crack topology wherein the amount of diffusion is controlled by a regularization parameter. The nonlinear coupled system consisting of the linear momentum equation and a diffusion type equation governing the phase field evolution is solved simultaneously via a Newton- Raphson approach. Post-processing of simulation results to be used as visualization module is performed via an additional UMAT subroutine implemented in the standard Abaqus viewer. In the same context, we propose a simple yet effective algorithm to initiate and propagate cracks in 2D geometries which is independent of both particular constitutive laws and specific element technology and dimension. It consists of a localization limiter in the form of the screened Poisson equation with, optionally, local mesh refinement. A staggered scheme for standard equilibrium and screened Cauchy equations is used. The remeshing part of the algorithm consists of a sequence of mesh subdivision and element erosion steps. Element subdivision is based on edge split operations using a given constitutive quantity (either damage or void fraction). Mesh smoothing makes use of edge contraction as function of a given constitutive quantity such as the principal stress or void fraction. To assess the robustness and accuracy of this algorithm, we use both quasi-brittle benchmarks and ductile tests. Furthermore, we introduce a computational approach regarding mechanical loading in microscale on an inelastically deforming composite material. The nanocomposites material of fully exfoliated clay/epoxy is shaped to predict macroscopic elastic and fracture related material parameters based on their fine-scale features. Two different configurations of polymer nanocomposites material (PNCs) have been studied. These configurations are fully bonded PNCs and PNCs with an interphase zone formation between the matrix and the clay reinforcement. The representative volume element of PNCs specimens with different clay weight contents, different aspect ratios, and different interphase zone thicknesses are generated by adopting Python scripting. Different constitutive models are employed for the matrix, the clay platelets, and the interphase zones. The brittle fracture behavior of the epoxy matrix and the interphase zones material are modeled using the phase field approach, whereas the stiff silicate clay platelets of the composite are designated as a linear elastic material. The comprehensive study investigates the elastic and fracture behavior of PNCs composites, in addition to predict Young's modulus, tensile strength, fracture toughness, surface energy dissipation, and cracks surface area in the composite for different material parameters, geometry, and interphase zones properties and thicknesses.},
  subject      = {Finite-Elemente-Methode},
  language  = {en}
}