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Die meisten traditionellen Methoden der Systemidentifikation beruhen auf der Abbildung der Meßwerte entweder im Zeit- oder im Frequenzbereich. In jüngerer Zeit wurden im Zusammenhang mit der Systemidentifikation Verfahren entwicklet, die auf der Anwendung der Wavelet-Transformation beruhen. Das Ziel dieser Arbeit war, einen Algorithmus zu entwickeln, der die Identifikation von Parametern eines Finite-Elemente-Modells, das ein experimentell untersuchtes mechanisches System beschreibt, ermöglicht. Es wurde eine Methode erarbeitet, mit deren Hilfe die gesuchten Parameter durch Lösen eines Systems von Bewegungsgleichungen im Zeit-Skalen-Bereich ermittelt werden. Durch die Anwendung dieser Darstellung können Probleme, die durch Rauschanteile in den Meßdaten entstehen, reduziert werden. Die Ergebnisse numerischer Simulation und einer experimentellen Studie bestätigen die Vorteile einer Anwendung der Wavelet-Transformation in der vorgeschlagenen Weise. ...
Finite Element Simulations of dynamically excited structures are mainly influenced by the mass, stiffness, and damping properties of the system, as well as external loads. The prediction quality of dynamic simulations of vibration-sensitive components depends significantly on the use of appropriate damping models. Damping phenomena have a decisive influence on the vibration amplitude and the frequencies of the vibrating structure. However, developing realistic damping models is challenging due to the multiple sources that cause energy dissipation, such as material damping, different types of friction, or various interactions with the environment.
This thesis focuses on thermoelastic damping, which is the main cause of material damping in homogeneous materials. The effect is caused by temperature changes due to mechanical strains. In vibrating structures, temperature gradients arise in adjacent tension and compression areas. Depending on the vibration frequency, they result in heat flows, leading to increased entropy and the irreversible transformation of mechanical energy into thermal energy.
The central objective of this thesis is the development of efficient simulation methods to incorporate thermoelastic damping in finite element analyses based on modal superposition. The thermoelastic loss factor is derived from the structure's mechanical mode shapes and eigenfrequencies. In subsequent analyses that are performed in the time and frequency domain, it is applied as modal damping.
Two approaches are developed to determine the thermoelastic loss in thin-walled plate structures, as well as three-dimensional solid structures. The realistic representation of the dissipation effects is verified by comparing the simulation results with experimentally determined data. Therefore, an experimental setup is developed to measure material damping, excluding other sources of energy dissipation.
The three-dimensional solid approach is based on the determination of the generated entropy and therefore the generated heat per vibration cycle, which is a measure for thermoelastic loss in relation to the total strain energy. For thin plate structures, the amount of bending energy in a modal deformation is calculated and summarized in the so-called Modal Bending Factor (MBF). The highest amount of thermoelastic loss occurs in the state of pure bending. Therefore, the MBF enables a quantitative classification of the mode shapes concerning the thermoelastic damping potential.
The results of the developed simulations are in good agreement with the experimental results and are appropriate to predict thermoelastic loss factors. Both approaches are based on modal superposition with the advantage of a high computational efficiency. Overall, the modeling of thermoelastic damping represents an important component in a comprehensive damping model, which is necessary to perform realistic simulations of vibration processes.
Oberflächenabdichtungen von Deponien sind in ihrer langfristigen Funktion häufig durch eine austrocknungsbedingter Rissbildung der mineralischen Dichtungskomponente gefährdet. Als Ursachen gelten insbesondere das standortspezifische Klima mit den stark schwankenden Randbedingungen (Niederschlag, Temperatur), Pflanzen und Tiere sowie auch ein ungeeigneter Systemaufbau. Durch einen Wasserentzug treten Schrumpfungsprozesse in der mineralischen Dichtung auf welche über negative Dehnungen zu Dehnungsbrüchen und damit zu einer Rissbildung führen. Für die Beanspruchbarkeit eines Dichtungsmaterials bei Wasserentzug sind insbesondere dessen Schrumpfverhalten und dessen Zugfestigkeit von Bedeutung. Beide Eigenschaften wurden durch eigens konzipierte Laborversuche beispielhaft an zwei typischen Dichtungsböden untersucht. Die Ergebnisse zeigen eine große Abhängigkeit von der Wasserspannung sowie von der Bodenstruktur. Für die Zugfestigkeit und dem daraus abgeleiteten Dehnungsmodul gilt z. B. jeweils eine eindeutige Zunahme mit Zunahme der Wasserspannungen. Mit Hilfe der Ergebnisse aus den Laborversuchen sowie numerischen Berechnungen des Was-serhaushaltes und der vorherrschenden Spannungen kann eine erste Rissgefährdungsabschätzung für mineralische Dichtungen in Oberflächenabdichtungen abgeleitet und angewandt werden. Weitere Erläuterungen z. B. zu den Eigenschaften und der Teilsättigung bindiger Böden, analytische Zugfestigkeitsberechnungen oder Empfehlungen zum Entwurf und der Herstellung von Oberflächenabdichtungen ergänzen die Arbeit.
Metaphosphat – modifizierte Silikatbinder als Basis säurebeständiger Beschichtungsmaterialien
(2008)
Mörtel basierend auf erhärtetem Wasserglas als Binder weisen eine ausgesprochen gute Beständigkeit im Kontakt mit stark sauren Medien auf; unzureichend hingegen ist die che-mische Beständigkeit im Kontakt mit alkalischen bis schwachsauren Medien. Ziel der Un-tersuchungen ist eine Verbesserung der Wasserbeständigkeit von Natriumsilikatbindern durch gezielte chemische Modifikation mit verschiedenen Metaphosphaten. Durch eine systematische Charakterisierung der Zusammensetzung und des strukturellen Aufbaus der Binder werden dabei die Ursachen der bindertypischen Eigenschaften aufgeklärt. Eine Modifikation der Natriumsilikatlösung mit Natriumtrimetaphosphat hat eine Erhöhung des Kondensationsgrades und eine verbesserte mechanische Beständigkeit des verfestig-ten Natriumsilikatbinders zur Folge. Durch die reaktive Bindung der Basizität der Natriumsi-likatlösung beim Abbau der Metaphosphatstruktur wird die Wasserbeständigkeit mit Natri-umtrimetaphosphat modifizierter Natriumsilikatmörtel erhöht. Die gute Beständigkeit im Kontakt mit hochkonzentrierter Schwefelsäure bleibt nahezu unverändert erhalten. Eine Modifikation der Natriumsilikatlösung mit Aluminiumtetrametaphosphat führt durch Reaktion beider Komponenten miteinander zur Bildung eines alumosilikatischen Netzwer-kes. Das alumosilikatische Netzwerk des mit Aluminiumtetrametaphosphat modifizierten Natriumsilikatbinders ist auch in einer stark alkalischen Natriumhydroxidlösung beständig. Die gute Beständigkeit des Binders im Kontakt mit hochkonzentrierter Schwefelsäure bleibt trotz des Aluminates im Bindernetzwerk erhalten.
Identification of flaws in structures is a critical element in the management of maintenance and quality assurance processes in engineering. Nondestructive testing (NDT) techniques based on a wide range of physical principles have been developed and are used in common practice for structural health monitoring. However, basic NDT techniques are usually limited in their ability to provide the accurate information on locations, dimensions and shapes of flaws. One alternative to extract additional information from the results of NDT is to append it with a computational model that provides detailed analysis of the physical process involved and enables the accurate identification of the flaw parameters. The aim here is to develop the strategies to uniquely identify cracks in two-dimensional 2D) structures under dynamic loadings.
A local NDT technique combined eXtended Finite Element Method (XFEM) with dynamic loading in order to identify the cracks in the structures quickly and accurately is developed in this dissertation. The Newmark-b time integration method with Rayleigh damping is used for the time integration. We apply Nelder-Mead (NM)and Quasi-Newton (QN) methods for identifying the crack tip in plate. The inverse problem is solved iteratively, in which XFEM is used for solving the forward problem in each iteration. For a timeharmonic excitation with a single frequency and a short-duration signal measured along part of the external boundary, the crack is detected through the solution of an inverse time-dependent problem. Compared to the static load, we show that the dynamic loads are more effective for crack detection problems. Moreover, we tested different dynamic loads and find that NM method works more efficient under the harmonic load than the pounding load while the QN method achieves almost the same results for both load types.
A global strategy, Multilevel Coordinate Search (MCS) with XFEM (XFEM-MCS) methodology under the dynamic electric load, to detect multiple cracks in 2D piezoelectric plates is proposed in this dissertation. The Newmark-b method is employed for the time integration and in each iteration the forward problem is solved by XFEM for various cracks. The objective functional is minimized by using a global search algorithm MCS. The test problems show that the XFEM-MCS algorithm under the dynamic electric load can be effectively employed for multiple cracks detection in piezoelectric materials, and it proves to be robust in identifying defects in piezoelectric structures. Fiber-reinforced composites (FRCs) are extensively applied in practical engineering since they have high stiffness and strength. Experiments reveal a so-called interphase zone, i.e. the space between the outside interface of the fiber and the inside interface of the matrix. The interphase strength between the fiber and the matrix strongly affects the mechanical properties as a result of the large ratio of interface/volume. For the purpose of understanding the mechanical properties of FRCs with functionally graded interphase (FGI), a closed-form expression of the interface strength between a fiber and a matrix is obtained in this dissertation using a continuum modeling approach according to the ver derWaals (vdW) forces. Based on the interatomic potential, we develop a new modified nonlinear cohesive law, which is applied to study the interface delamination of FRCs with FGI under different loadings. The analytical solutions show that the delamination behavior strongly depends on the interphase thickness, the fiber radius, the Young’s moduli and Poisson’s ratios of the fiber and the matrix. Thermal conductivity is the property of a material to conduct heat. With the development and deep research of 2D materials, especially graphene and molybdenum disulfide (MoS2), the thermal conductivity of 2D materials attracts wide attentions. The thermal conductivity of graphene nanoribbons (GNRs) is found to appear a tendency of decreasing under tensile strain by classical molecular dynamics (MD) simulations. Hence, the strain effects of graphene can play a key role in the continuous tunability and applicability of its thermal conductivity property at nanoscale, and the dissipation of thermal conductivity is an obstacle for the applications of thermal management. Up to now, the thermal conductivity of graphene under shear deformation has not been investigated yet. From a practical point of view, good thermal managements of GNRs have significantly potential applications of future GNR-based thermal nanodevices, which can greatly improve performances of the nanosized devices due to heat dissipations. Meanwhile, graphene is a thin membrane structure, it is also important to understand the wrinkling behavior under shear deformation. MoS2 exists in the stable semiconducting 1H phase (1H-MoS2) while the metallic 1T phase (1T-MoS2) is unstable at ambient conditions. As it’s well known that much attention has been focused on studying the nonlinear optical properties of the 1H-MoS2. In a very recent research, the 1T-type monolayer crystals of TMDCs, MX2 (MoS2, WS2 ...) was reported having an intrinsic in-plane negative Poisson’s ratio. Luckily, nearly at the same time, unprecedented long-term (>3months) air stability of the 1T-MoS2 can be achieved by using the donor lithium hydride (LiH). Therefore, it’s very important to study the thermal conductivity of 1T-MoS2.
The thermal conductivity of graphene under shear strain is systematically studied in this dissertation by MD simulations. The results show that, in contrast to the dramatic decrease of thermal conductivity of graphene under uniaxial tensile, the thermal conductivity of graphene is not sensitive to the shear strain, and the thermal conductivity decreases only 12-16%. The wrinkle evolves when the shear strain is around 5%-10%, but the thermal conductivity barely changes.
The thermal conductivities of single-layer 1H-MoS2(1H-SLMoS2) and single-layer 1T-MoS2 (1T-SLMoS2) with different sample sizes, temperatures and strain rates have been studied systematically in this dissertation. We find that the thermal conductivities of 1H-SLMoS2 and 1T-SLMoS2 in both the armchair and the zigzag directions increase with the increasing of the sample length, while the increase of the width of the sample has minor effect on the thermal conductions of these two structures. The thermal conductivity of 1HSLMoS2 is smaller than that of 1T-SLMoS2 under size effect. Furthermore, the temperature effect results show that the thermal conductivities of both 1H-SLMoS2 and 1T-SLMoS2 decrease with the increasing of the temperature. The thermal conductivities of 1HSLMoS2 and 1T-SLMoS2 are nearly the same (difference <6%) in both of the chiral orientations under corresponding temperatures, especially in the armchair direction (difference <2.8%). Moreover, we find that the strain effects on the thermal conductivity of 1HSLMoS2 and 1T-SLMoS2 are different. More specifically, the thermal conductivity decreases with the increasing tensile strain rate for
1T-SLMoS2, while fluctuates with the growth of the strain for 1HSLMoS2. Finally, we find that the thermal conductivity of same sized 1H-SLMoS2 is similar with that of the strained 1H-SLMoS2 structure.
In der Arbeit wurde eine Methode für eine kulturübergreifende Vergleichsstudie zwischen China und dem Westen erarbeitet. Diese Methode ermöglicht Unternehmensentwicklung in China aus dem eignen historischen Zusammenhang zu verstehen, statt nur aus einem rein theoretischen Blickwinkel. Weil heutige wissenschaftliche Theorien meist aus der westlichen Kultur stammen und mit Wertvorstellungen sowie mit Begriffen aus dem westlichen Kulturkreis verbunden sind, müssen sie im historischen Kontext des westlichen Kulturkreises betrachtet werden.
Im ersten Teil der Arbeit wird der westliche moderne Staat als Untersuchungsbegriff herangezogen, seine Entstehungsbedingungen und seine Verwendungsart und -weise, besonders wie er die ökonomische Theorie und die Praxis im Westen beeinflusst, dabei spielt das moderne Staatsprinzip eine wichtige Rolle. Die Neue Institutionenökonomik dient als theoretischer Referenzrahmen für diese Arbeit. Mittels einer theoretischen Erweiterung mit dem westlichen modernen Staatsverständnis werden wichtige westliche konstitutionelle Institutionen analysiert, da sie die Handlungsrechte und -pflichten der Bürger sowie die Bildung der kapitalistischen Unternehmung beeinflussen.
Im zweiten Teil der Arbeit wird das chinesische Staatsverständnis analysiert – vom traditionellen „Tianxia“ zum „modernen“ Staat. Mithilfe abgeleiteter Kriterien wird die chinesische Unternehmensentwicklung in drei zeitlichen Querschnittsphasen betrachtet, wie sich chinesische Unternehmen vom traditionellen bis zum „modernen“ entwickelten. Als Fallbeispiel werden chinesische Buchdruckunternehmen herangezogen. Zuerst wird das Buchdrucksystem sowie seine Veränderungen in drei Zeitphase betrachtet. Dabei wird auf die Aspekte Buchdruckorganisation, staatliche Verwaltung, wie Zensur und Urheberrecht sowie Lehrmaterial fokussiert, die für die Buchdruckunternehmensentwicklung von Bedeutung sind und ein System darstellen. Aus Mikrosicht werden drei Buchdruckunternehmen in den Zeitphasen analysiert. Im Ergebnis der Arbeit werden Schlussfolgerungen abgeleitet, bspw. dass Modernisierung als Aktualisierung verstanden werden sollte, aber nicht als Zerstörung.
Material failure can be tackled by so-called nonlocal models, which introduce an intrinsic length scale into the formulation and, in the case of material failure, restore the well-posedness of the underlying boundary value problem or initial boundary value problem. Among nonlocal models, peridynamics (PD) has attracted a lot of attention as it allows the natural transition from continuum to discontinue and thus allows modeling of discrete cracks without the need to describe and track the crack topology, which has been a major obstacle in traditional discrete crack approaches. This is achieved by replacing the divergence of the Cauchy stress tensor through an integral over so-called bond forces, which account for the interaction of particles. A quasi-continuum approach is then used to calibrate the material parameters of the bond forces, i.e., equating the PD energy with the energy of a continuum. One major issue for the application of PD to general complex problems is that they are limited to fairly simple material behavior and pure mechanical problems based on explicit time integration. PD has been extended to other applications but losing simultaneously its simplicity and ease in modeling material failure. Furthermore, conventional PD suffers from instability and hourglass modes that require stabilization. It also requires the use of constant horizon sizes, which drastically reduces its computational efficiency. The latter issue was resolved by the so-called dual-horizon peridynamics (DH-PD) formulation and the introduction of the duality of horizons.
Within the nonlocal operator method (NOM), the concept of nonlocality is further extended and can be considered a generalization of DH-PD. Combined with the energy functionals of various physical models, the nonlocal forms based on the dual-support concept can be derived. In addition, the variation of the energy functional allows implicit formulations of the nonlocal theory. While traditional integral equations are formulated in an integral domain, the dual-support approaches are based on dual integral domains. One prominent feature of NOM is its compatibility with variational and weighted residual methods. The NOM yields a direct numerical implementation based on the weighted residual method for many physical problems without the need for shape functions. Only the definition of the energy or boundary value problem is needed to drastically facilitate the implementation. The nonlocal operator plays an equivalent role to the derivatives of the shape functions in meshless methods and finite element methods (FEM). Based on the variational principle, the residual and the tangent stiffness matrix can be obtained with ease by a series of matrix multiplications. In addition, NOM can be used to derive many nonlocal models in strong form.
The principal contributions of this dissertation are the implementation and application of NOM, and also the development of approaches for dealing with fractures within the NOM, mostly for dynamic fractures. The primary coverage and results of the dissertation are as follows:
-The first/higher-order implicit NOM and explicit NOM, including a detailed description of the implementation, are presented. The NOM is based on so-called support, dual-support, nonlocal operators, and an operate energy functional ensuring stability. The nonlocal operator is a generalization of the conventional differential operators. Combining with the method of weighted residuals and variational principles, NOM establishes the residual and tangent stiffness matrix of operate energy functional through some simple matrix without the need of shape functions as in other classical computational methods such as FEM. NOM only requires the definition of the energy drastically simplifying its implementation. For the sake of conciseness, the implementation in this chapter is focused on linear elastic solids only, though the NOM can handle more complex nonlinear problems. An explicit nonlocal operator method for the dynamic analysis of elasticity solid problems is also presented. The explicit NOM avoids the calculation of the tangent stiffness matrix as in the implicit NOM model. The explicit scheme comprises the Verlet-velocity algorithm. The NOM can be very flexible and efficient for solving partial differential equations (PDEs). It's also quite easy for readers to use the NOM and extend it to solve other complicated physical phenomena described by one or a set of PDEs. Several numerical examples are presented to show the capabilities of this method.
-A nonlocal operator method for the dynamic analysis of (thin) Kirchhoff plates is proposed. The nonlocal Hessian operator is derived from a second-order Taylor series expansion. NOM is higher-order continuous, which is exploited for thin plate analysis that requires $C^1$ continuity. The nonlocal dynamic governing formulation and operator energy functional for Kirchhoff plates are derived from a variational principle. The Verlet-velocity algorithm is used for time discretization. After confirming the accuracy of the nonlocal Hessian operator, several numerical examples are simulated by the nonlocal dynamic Kirchhoff plate formulation.
-A nonlocal fracture modeling is developed and applied to the simulation of quasi-static and dynamic fractures using the NOM. The phase field's nonlocal weak and associated strong forms are derived from a variational principle. The NOM requires only the definition of energy. We present both a nonlocal implicit phase field model and a nonlocal explicit phase field model for fracture; the first approach is better suited for quasi-static fracture problems, while the key application of the latter one is dynamic fracture. To demonstrate the performance of the underlying approach, several benchmark examples for quasi-static and dynamic fracture are solved.
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.
The Variability of the Void Ratio of Sand and its Effect on Settlement and Infinite Slope Stability
(2018)
The uncertainty of a soil property can significantly affect the physical behavior of soil, so as to influence geotechnical practice. The uncertainty can be expressed by its stochastic parameters, including the mean, the standard deviation, and the spatial correlation length. These stochastic parameters are regarded as constant value in most of the former studies. The main aim of this thesis is to prove whether they are depth-dependent, and to evaluate the effect of this depth-dependent character on both the settlement and the infinite slope stability during rainwater infiltration.
A stochastic one-dimensional settlement simulation is carried out using random finite element method with the von Wolffersdorff hypoplastic model, so as to evaluate the effect of stress level on the stochastic parameters of void ratio related parameters of sand. It is found that these stochastic parameters are both stress-dependent and depth-dependent.
The non-stationary random field, considering the depth-dependent character of these stochastic parameters, can be generated through the distortion of the stationary random field.
The one-dimensional settlement analysis is carried out to evaluation the effect of the depth-dependent character of the stochastic parameters of void ratio on the strain. It is found that the depth-dependent character has low effect on the strain.
The deterministic analysis of infinite slope stability during rainwater infiltration is simulated.
The transient seepage is carried out using finite difference method, while the steady state seepage is simulated using the analytical solution. The saturated hydraulic conductivity (ks) is taken as the only variable. The results show that the depth-dependent ks has a significant influence on the stability of the slope when the negative flux is high. Without considering the depth-dependent character, can overestimate the factor of safety of the slope. A slope can fail if the depth-dependent character is considered, while it is stable if the depth-dependent character is neglected. The failure time of the slope with a greater depth-dependent ks is earlier during transient infiltration.
Meanwhile, the stochastic infinite slope stability analysis during infiltration, is also carried out to highlight the effect of the depth-dependent character of the stochastic parameters of ks. The results show that: the probability of failure is significantly increased if the depth-dependent character of mean is considered, while, it is moderately reduced if the depth-dependent character of the standard deviation is accounted. If the depth-dependent character of both the mean and standard deviation of ks is considered, the depth-dependent mean value plays a dominant influence on the results. Furthermore, the depth-dependent character of the spatial correlation length can slightly reduce the probability of failure.
Die fachlichen und organisatorischen Aufgaben der Informationsverarbeitung im Prozeß der Bauauftragsrechnung werden als theoretische Grundlage für die Anpassung und Neukonzeption netzverteilter Informationssysteme formal beschrieben. Hierzu erfolgen Untersuchungen von Methoden, Verfahren, Strukturen und Abläufen sowie der in Bauunternehmen angewendeten Informationssysteme. Grundlage einer Modellierungsmethode sind Abstraktionen von Prozeßschritten und Ereignissen in einer Ereignisgesteuerten Prozeßkette, Entitytypen in einem Entity Relationship Model, Funktionsbäume und Organisationseinheiten sowie deren mögliche Relationen. Mit dieser Methodik werden die Prozesse, Informationsdefinitionen, Funktionen und die Organisationsstruktur einzeln modelliert und Relationen zwischen den Modellelementen gebildet. Aus der fachlichen Auswertung der Modelle und Relationen folgen fachgebietsspezifische Prozeßabläufe und Arbeitsumgebungen. Deren Anwendung wird für ein Customizing vorhandener Informationsysteme und bei einer Neuimplementierung betrachtet. Neben einer umfangreichen fachlichen Problemanalyse leistet die Arbeit einen Beitrag zum methodischen Vorgehen bei Neukonzeption baubetrieblicher Informationssysteme.