Golfový klub / Golf club

Sedláčková, Markéta

January 2015

The subject matter of my Diploma thesis is the project of a new golf club. The building has one floor and is covered by a flat mono-coated roof. Spacious terraces accessible from first floor are the integral parts. Vertical load bearing and non-load bearing walls are designed from Porotherm walling system. Horizontal load bearing ceiling constructions are designed from an prestressed ceiling panels Spiroll. Foundations are designed reinforced concrete. The building is divided into two separate operating units. The project emphasizes the layout plan, thermal technical properties and safety in use.

Problematika hodnocení stavebně statického stavu existujících objektů / The possibility of performing diagnosis of wooden structural components and parts

Pírek, Tomáš

January 2017

The aim of this thesis is to evaluate the building technical and tructural condition of the structure in the areal of Kralovopolske a.s. In this work there are proposed and subsequently implemented diagnostic work for the assesment of existing structures.

Hodnocení stavebně statického stavu existující konstrukce / Evaluation of building structural condition of the existing structure

Šmatelka, Filip

January 2017

The main goal of master's thesis is to find out the technical and structural condition of building "Children and Youth Centre". This building is situated on the Komenského street in Velké Meziříčí. The main reason for diagnostic is to find out posibilities for building edits. The second reason is to get objective informations about technical condition of structural units.

Failure Behaviour of Masonry under Compression Based on Numerical and Analytical Modeling

Michel, Kenan

11 December 2015

In this work the compression behavior of masonry was investigated. After a detailed review of code approaches and different research works, a new formula was suggested to describe the compression strength of masonry, based on the mechanical and geometrical properties of its components, when deformation properties of units are larger than the ones of mortar. Later on, a new model, Extended Drucker-Prager Cap Yielding Function, is suggested to describe the three axial compression stress state of mortar in masonry in case deformation properties of mortar are larger than the ones of mortar, and to describe the three axial compression stress state of brick in the other case. This includes defining its parameters based on test diagrams of the mortar material, implementing the model in the numerical software ANSYS, and the numerical results are evaluated for simple cube example. The controlling equations of creep based on the visco-elastic creep theory are presented in the general case of three axial creep under three axial loading conditions. The special case of three axial creep under axial loading is also presented. The “transversal creep” relevant for the compression strength of masonry was discussed and numerical examples have been added to show the effect of changed time-dependent Poisson’s ratio. In another chapter, many examples are presented showing the application of the suggested material models and discontinuous numerical method named eXtended finite element method. Conclusions and recommendations are given in the last chapter.

info:eu-repo/classification/ddc/690

ddc:690

compression, masonry, EDP-Cap

Increasing the Blast Resistance of Concrete Masonry Walls Using Fabric Reinforced Cementitious Matrix (FRCM) Composites

Perez Garcia, Ramon

07 May 2021

Unreinforced masonry (URM) walls are often used as load-bearing or infill walls in buildings in many countries. Such walls are also commonly found in existing and heritage buildings in Canada. URM walls are strong structural elements when subjected to axial loading, but are very vulnerable under out-of-plane loads. This type of loading may come from different sources , including seismic or blast events. When subjected to blast, wall elements experience large pressures on one of their faces due to the high pressure produced in the air when an explosion takes place. This wave of compressed air travels in a very short time and hits the wall causing immense stresses, which result in large shear and bending demands that may lead to wall failure, and the projection of debris at high velocities that can injure building occupants. This failure process is highly brittle due to the very low out-of-plane strength that characterize such walls. In the past years, many investigations have been carried out to enhance the structural behaviour of unreinforced masonry walls under out-of-plane loading. Different strengthening methods have been studied, which include the use of polyurea coatings, the application of advanced fiber-reinforced polymer (FRP) composites or the use of concrete overlays in combination with high performance reinforcement. Fabric-reinforced cementitious matrix (FRCM) is a new composite material that overcomes some of the drawbacks of FRP. This composite material consists of applying coatings which consist of one or more layers of cement-based mortar reinforced with a corresponding open mesh of dry fibers (fabric). This material has been studied as a strengthening technique to improve in-plane and out-of-plane capacity of existing URM walls as well as other structural elements, mostly under seismic actions. This thesis presents an experimental and analytical study which investigates the effectiveness of using FRCM composites to improve the out-of-plane resistance of URM walls when subjected to blast loading. As part of the experimental program, three large-scale URM masonry walls were constructed and strengthened with 1,2 and 3 layers of FRCM using unidirectional carbon fabrics. In all cases the specimens were built as load-bearing concrete masonry (CMU) walls. To increase shear resistance, two of the walls were also grouted with a flowable self-compacting concrete (SCC) mortar. Blast tests were conducted using the University of Ottawa Shock Tube and the results are compared with control walls tested in previous research at the University of Ottawa. The experimental results show that the FRCM retrofit significantly improved the blast performance of the URM load-bearing walls, allowing for increased blast capacity and improved control of displacements. The performance of the retrofit was found to be dependent on the number of retrofit layers. As part of the analytical research, Single Degree of Freedom (SDOF) analysis was carried out to predict the blast behaviour of the strengthened walls. This was done by computing wall flexural strength using plane sectional analysis and developing idealized resistance curves for use in the SDOF analysis. In general, the analysis procedure is found to produce reasonably accurate results for both the resistance functions and wall mid-height displacements under blast loading.

FRCM

Fabric Reinforced Cementitious Matrix

Composites

URM walls

Blast

Masonry walls

Dynamic Analysis and Seismic Retrofit of the Point Sur Lighthouse

Dekker, Nicholas M

01 June 2020

The Point Sur Lighthouse is an unreinforced stone masonry building completed in 1889 on the central coast of California. The lighthouse is listed on the National Register of Historic Places and is still an active aid to navigation. The original first-order Fresnel lens was removed from the lantern room and placed in safekeeping due to its high risk of damage in the event of a strong earthquake. The lens has been approved to return to its original setting but the seismic performance of the building must first be assessed in order to ensure the safety of the lens and lighthouse, specifically the out-of-plane behavior of the unreinforced masonry walls, the implementation of possible seismic retrofit schemes, and the effects of the lens’s added weight. This research focuses on the dynamic behavior of the lighthouse in its current state and the changes in the dynamic behavior each of the proposed seismic retrofit schemes might cause. For the purposes of this research, dynamic behavior is considered as natural frequencies, mode shapes, and related structural properties. The dynamic behavior of the lighthouse was assessed using two main methods: forced vibration testing and finite element computer modeling. Forced vibration testing is a nondestructive testing method that can be used to directly characterize dynamic behavior of a structure, and finite element computer modeling is useful for the design and simulation of dynamic behavior of both new and existing structures. The combination of these two methods on the Point Sur Lighthouse will work to develop and prove state-of-the-art seismic retrofitting techniques.

Unreinforced Masonry

Seismic Retrofit

Forced Vibration Testing

Finite Element

Architectural Engineering

Mateřská škola Rajhrad / Kindergarten in Rajhrad

Murín, Marek

January 2022

The topic of my thesis is the design of a kindergarten in Rajhrad. The building is one storey with a flat roof. In the middle of the building there are technical facilities, a kitchen, a director's office and facilities for staff. On the sides there are classrooms with bathrooms and cloakrooms. The load-bearing masonry is designed of Heluz ceramic blocks. The perimeter masonry is insulated with the ETICS contact insulation system. The roof structure is made of prefabricated floor slabs SPIROLL. The building is covered by a green flat roof. The building will be heated by a gas condensing boiler. It will have an air handling unit located on the roof along with photovoltaic panels. Intelligent LED lighting will be deployed throughout the building. The third part deals with the comparison between masonry construction and the more environmentally friendly clay construction. Specifically, it compares the CO2 production of masonry and clay construction of the same building using the SBToolCZ methodology. The results obtained showed that the clay building produces approximately 30% less CO2 than the masonry building. I created my thesis using ArchiCAD and DEKsoft software.

Development of Stability Evaluation Methods for Soil-Masonry Structure Interactive Problems and Application to Historic Structures / 地盤-石積複合構造物の安定性評価手法の開発と歴史的構造物への適用に関する研究

Hashimoto, Ryota

23 March 2017

京都大学 / 0048 / 新制・課程博士 / 博士(工学) / 甲第20327号 / 工博第4264号 / 新制||工||1661(附属図書館) / 京都大学大学院工学研究科都市社会工学専攻 / (主査)教授 三村 衛, 教授 大津 宏康, 准教授 肥後 陽介 / 学位規則第4条第1項該当 / Doctor of Philosophy (Engineering) / Kyoto University / DFAM

masonry structure

soil-structure interaction

stability evaluation

bearing capacity

numerical analysis

500

Investigating the Behavioral Factors that Influence Regional Lithic Assemblage Variability in the Upper Basin, Northern Arizona

Phillips, Emily P.

25 July 2019

No description available.

Archaeology

lithic scatters

archaeology

mobility patterns

masonry structures

fire-cracked-rock piles

arizona

Exploring forms of masonry vaults built without centering

Neupane, Babita

16 December 2020

No description available.

Architectural

Architecture

Design

Unreinforced masonry vaults

Equilibrium approach

Design

Architecture

Algorithm

Parametric design

Python script