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1	Elastic Properties of Jet-Grouted Ground and Applications Juge, Benjamin 2012 May 1900 (has links) With the development of urban areas and the constant need to change or improve the existing structures, a need for creative and less destructive soil reinforcement processes has occurred. Jet-grouting is one possible ground improvement technique. The behavior of the soil improved by jet-grouting is still not well understood. In this thesis, the mechanical behavior of the injected soil is modeled in order to determine the different parameters needed for the engineering design of a soil reinforcement based on jet-grouting. At first several models are presented in order to determine the extent of the injected zone within the soil mass, based on engineering parameters (cement poroelastic properties, injection rate). A model based on an energetic balance is proposed to compute the lower bound of the injection radius. The second part of the thesis focuses on the characterization of the uniaxial compressive strength of the soilcrete created in the injected area determined in the first part. Three different methods have been adapted to the problem. A hollow sphere model has been calibrated against published data. After calibration, both Eshelby's and averaging methods proved to provide results close to the reference data. The last part of this report presents numerical studies of the pile and of a group of piles. The study of the group of piles focuses on the effect of arching between soilcrete columns to reduce the vertical settlements due to urban tunneling at the surface. It appears that the values obtained for settlements in the presence of jet-grouted columns are much less important than in usual tunneling problems (with no reinforcement). Jet-Grouting Elastic Properties Radius of Injection
2	Escavações multi-escoradas em solos moles incorporando laje de fundo de jet grout e pré-esforço nas escoras Mateus, Ricardo Daniel da Costa January 2010 (has links) Tese de mestrado integrado. Engenharia Civil. Faculdade de Engenharia. Universidade do Porto. 2010 Escavações escoradas Solos argilosos Modelação numérica Sistemas Jet Grouting
3	Escavações em maciços terrosos suportados por paredes de Jet Grouting Pereira, Manuel Ricardo Martins de Carvalho Lima January 2009 (has links) Tese de mestrado integrado. Engenharia Civil (Especialização em Construções). Faculdade de Engenharia. Universidade do Porto. 2009 Comportamento das escavações Muros de suporte Sistemas Jet Grouting Maciços rochosos
4	Aterros sobre solos moles reforçados com colunas de Jet Grout encabeçadas por geossintéticos Caramelo, Tiago André Lima Mimoso January 2011 (has links) Tese de mestrado integrado. Engenharia Civil (Construções). Universidade do Porto. Faculdade de Engenharia. 2011 Aterros Solos moles Colunas de jet grouting Tratamento de solos Modelação numérica
5	Contenção com paredes autoportantes de Jet Grouting em escavações cilíndricas Guerra, Gonçalo Miguel Torrão January 2009 (has links) Tese de mestrado integrado. Engenharia Cívil (Especialização em Construções). Faculdade de Engenharia. Universidade do Porto. 2009 Escavações cilíndricas Sistemas Jet Grouting Maciços rochosos Modelação numérica
6	Pagrindų injekcijos metodų naudojimo pastatų rekonstrukcijai tyrimai / Investigation of use of ground injections methods for reconstruction of buildings Černiavska, Irena 26 June 2008 (has links) Baigiamajame magistro darbe apžvelgiami pamatų ir pagrindų stiprinimo būdai. Laboratorijoje atliktas sustiprinto natrio silikato tirpalu grunto tyrimas, nustatyta jo mechaninių savybių priklausomybė nuo bandinių kietėjimo laiko. Nagrinėjamas pagrindų injekcijos metodų naudojimas pastatų rekonstrukcijai. Taikant COSMOS programinį paketą įražos apskaičiuotos šiais atvėjais: 1. Sudarius erdvinį grunto masyvo modelį, kai gruntas po pastato pamatu nesustiprintas; 2. Kai gruntas sustiprintas porų injekcijos (angl. Grouting) metodu; 3. Kai gruntas sustiprintas srautinės injekcijos (angl. Jet-grouting) metodu. Palyginamas įtempių sklidimas ir poslinkių kaita grunte (smėlis). Gautų atsakymų analizavimas. / Foundations and grounds strengthening methods were reviewed in this Master thesis work. The test of soil strengthened with sodium silicate solution was accmlished in the laboratory. Dependence of soil mechanical characteristics from samples solidification time was ascertained. Usage of grounds injection menthods for reconstruction of buildings was investigated. Applying COSMOS program package the efforts were estimated in such cases: 1. forming the dimensional model of soil solid when the soil under the foundations of the building is not strengthened; 2. when the soil is sthrengthened using the Grounting method; 3. when the soil is strengthened using the Jet-grounting method. Spread of strains and vicissitude of shifts in the soil (sand) were compared. The analysis of obtained results was made. Civil Enginering Porų ir srautinė injekcija Įtempimai Poslinkiai Grounds Grouting Jet-grouting
7	Založení výrobního zařízení v hale / Foundation of heavy equipment in industrial facility Minarčík, Jan January 2020 (has links) The main topic of diploma thesis is foundation of Heavy equipment in industrial facility and the selecting of the appropriate method foundation with respect to the boundary condition. The first part contains the theoretical basis of the chosen special foundation technology. In the second part, there is the design of the foundation itself. To solve the design was used special numerical softwares and also there was some calculation without using it. The necessary design documentation was also created.
8	Jet Grout Bottom Plug in Deep Excavations : Numerical Analysis of a Tunnel Project Schjelderup, Ida January 2022 (has links) This master thesis has investigated the performance of a deep excavation with a jet grout bottom plug used to prevent bottom heave and hydraulic uplift failure. The concept of a jet grout plug as a structural and sealing component in a specific case was studied, namely one of the tunnel sections of The West Link tunnel project in Gothenburg. The section was to be built as a cut-and-cover tunnel with the excavation shaft consisting of secant pile walls, struts and a jet grout bottom plug. It is to be established where there are a lot of sensitive buildings and constructions close to the excavation site. This makes it important not to disturb the surroundings during construction with, for example, settlements.The study was carried out by doing a literature study, analytical calculations and numerical simulations in the finite element software PLAXIS 2D. More specifically, the checks evaluated were uplift equilibrium of the jet grout plug and of the whole structure, structural performance of the jet grouted plug and hydraulic conductivity of the jet grouted mass.The results show a design of a jet grout plug that together with the additional structures works sufficiently enough to make a secure construction for a deep excavation below the ground water table. The structural performance of the jet grouted plug to function as a strut level is fulfilled even if the jet grout is not perfectly performed. To work as a sealing component the jet grout column pattern and the centre-to-centre distance between the columns are important factors together with the alignment and diameter of the jet grout columns. To make a completely watertight construction is however almost impossible in this case since the jet grout plug is located at a large depth (around 20 m). To work properly against failure by uplift it does not need to be completely watertight. Instead, the use of relief wells makes sure that the pore water pressure is not larger than the vertical stress from the soil, otherwise failure by uplift is a real danger. Furthermore, to work properly against settlements it is not only the water tightness of the jet grout plug that decides whether it will work properly. Instead, it is also the pumping and infiltration system together with the, in this case, sensitivity of the lower aquifer that decides the risk of settlements. Jet grouting jet grout bottom plug cut-and-cover tunnel tunnel design Engineering and Technology Teknik och teknologier
9	Jet grouting as a method for sealing sheet pile excavations in Swedish conditions : A probabilistic approach Brinck, Mårten, Stigenius, Karl January 2019 (has links) Jet grouting is a groundimprovement method that creates cemented columns in the soil. The soil isinjected with different pressurized fluids, through the monitor, to replace andcement the soil, often with water cement grout. There are three different commonsystems for ejecting the fluids, the single, double and triple fluid system.The process is performed from the ground surface by drilling to desired depthand then withdrawing the monitor while rotating and ejecting and thus creatinga column. There are many applications for this technique. However, this thesisfocus on using jet grouted columns in formation to seal sheet pile excavationsfrom water. Jet-grouting probabilistic model water Monte-Carlo holes Geotechnical Engineering Geoteknik
10	Strukturella förbättringar av en markstabiliseringsmast Skog, Axel January 2021 (has links) This report has examined the possibilities of stiffening and strengthening a ground stabilization mast, in a way that a small production company can manufacture. The soil stabilization technique in question is Jet-Grouting also called injection drilling, which involves drilling to the desired depth and then letting high-pressure water jets mixed with filling mass to erode the surrounding soil mass and form pillars below the ground surface. The study intends to explore the possibility of placing a simplified model in the simulation program ANSYS that uses the finite element method (FEM) to obtain its results. The product development method described by Karl T. Ulrich and Steven D. Eppinger in the book "Product Design and Development" is then used to produce improvement proposals that will strengthen the mast. The purpose of this study was to identify the strength of a ground stabilization mast and then produce and present an improvement proposal, based on the rotation head that is now mounted on the ground stabilization mast. This rotary head is named "RH24X HP 67 TS" and is produced by Eurodrill, and it generates a maximum torque of 24 kNm. The simulations on the mast with the given torque resulted in the highest stress of 158 MPa to which the mast body was exposed to. With the design that the mast current design, it entails a 2.3 factor of safety, which is considered acceptable since the recommended factor of safety for this type of heavy machine is about 2 (Khan, et al., 2016). When the torque was increased to the limit of the mast, i.e., when the factor of safety is close to 1, it resulted in a maximum torque of 54 kNm. Mounting a rotary head with a torque of 54 kNm is therefore not recommended due to the low safety margin that it would entail. Market research has been done and the proposals presented in this study presents similar manufactures and series as of the current rotary head. The recommended rotary heads come from the Eurodrill X-series and are called "RH32X HP 67 TS" and it produces a maximum torque of 32 kNm, alternatively "RH 4300 HP 48 TSS" which produces a torque of 34 kNm. The improvement proposals presented in this report are developed by evaluating the results of the simulations performed and then identifying the weakest areas. Then, based on the product development method, generate a proposal that can stiffen and strengthen the ground stabilization mast. The improvement proposal on the cradle showed with the rotary head "RH24X HP 67 TS" a 4.8 factor of safety, compared to the current cradle which has a 2.6 factor of safety, it is almost a doubling in strength. A new design of trusses was presented and resulted in a 35% increase in rigidity without the need to add any new material. This means that by re-examining the structure of the truss you can strengthen and possibly check the rigidity of the mast, which among other things leads to better manoeuvrability without any real extra costs being needed. / Denna rapport har undersökt möjligheterna att styva och styrka upp en markstabiliseringsmast på ett sätt som ett mindre produktionsföretag klarar av att tillverka. Markstabiliseringstekniken i fråga är Jet-Grouting även kallad injiceringsborrning, som går ut på att man borrar till önskat djup för att sedan låta högtrycksvattenjetstrålar blandat med fyllnadsmassa erodera den kringliggande jordmassan och bilda pelare under markytan. Studien ämnar utforska möjligheten med att placera en förenklad modell i simuleringsprogrammet ANSYS som använder finit elementmetod (FEM) för att få fram sina resultat. Därefter används produktutvecklingsmetoden som beskrivs av Karl T. Ulrich och Steven D. Eppinger i boken ”Product Design and Development”, för att ta fram förbättringsförslag som ska styrka upp masten. Studien har haft som syfte att ta reda på hållfastheten hos en markstabiliseringsmast och sedan ta fram och presentera ett förbättringsförslag, utifrån det rotationshuvud som nu är monterat på markstabiliseringsmasten. Detta rotationshuvud har benämningen ”RH24X HP 67 TS” och är producerad av Eurodrill och genererar ett maximalt vridmoment på 24 kNm. Simuleringarna på masten med det givna vridmomentet resulterade i den högsta spänningen på 158 MPa som mastkroppen utsattes för. Med det utförande som masten är idag medför det en 2,3 säkerhetsfaktor, vilket är anses vara acceptabelt eftersom den rekommenderade säkerhetsfaktorn för denna typ av tungmaskin ligger på cirka 2 (Khan, et al., 2016). När man sedan ökade vridmomentet till mastens bristgräns, det vill säga när säkerhetsfaktorn tangerar 1, resulterade det i ett maximalt vridmoment på 54 kNm. Att montera ett rotationshuvud med ett vridmoment på 54 kNm är därför inte att rekommendera på grund av den låga säkerhetsmarginalen som det skulle innebära. Därför presenteras förslag på rotationshuvuden som masten kan klara av, genom en marknadsundersökning gjord på liknade tillverkare och serier som dagens rotationshuvud. De rotationshuvud som rekommenderas kommer från Eurodrill X-serie och heter ”RH32X HP 67 TS” och den producerar ett maximalt vridmoment på 32 kNm, alternativt ”RH 4300 HP 48 TSS” som producerar ett vridmoment på 34 kNm. Förbättringsförslagen som presenteras i denna rapport är framtagna genom att utvärdera resultaten av de utförda simuleringarna och sedan identifiera de svagaste områdena. Därefter genereras förslag utifrån produktutvecklingsmetoden som kan styva och stärka upp markstabiliseringsmasten. Förbättringsförslaget på släden visade med rotationshuvudet ”RH24X HP 67 TS” en 4,8 säkerhetsfaktor, jämfört med den nuvarande släden som har en 2,6 säkerhetsfaktor vilket är nästan en fördubbling i hållfasthet. En ny design av fackverk presenterades och resulterade i 35 % ökad styvhet utan att behöva addera något nytt material. Det innebär att man genom att ompröva fackverkets struktur kan stärka och eventuellt kontrollera mastens styvhet, vilket bland annat leder till bättre manövrerbarhet utan några egentliga extra kostnader behövs. ANSYS FEA SpaceClaim SolidWorks Jet-Grouting Camatec Scandinavian Pile Driving ground stabilization CAE CAD ANSYS FEM SpaceClaim SolidWorks Jet-Grouting Camatec Scandinavian Pile Driving markstabilisering CAE CAD Mechanical Engineering Maskinteknik

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