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11	Effektivisering av stålbalkar i en takkonstruktion med avseende på utsläpp av växthusgaser / Steel beam effectivization in a roof construction, Considering greenhouse gas emissions Fasihikoli, Dorsa, Filippa, Kjellander January 2024 (has links) Introduktion (och mål) – Jordens medeltemperatur har ökat exponentiellt sedan industrialismen i slutet av 1800-talet. En ökad medeltemperatur leder till klimatförändringar som värmeböljor, översvämningar, smältande polarisar och stigande havsnivåer. För att motverka den globala uppvärmningen krävs det att Sverige och alla andra länder minskar sina utsläpp av växthusgaser. Bygg- och fastighetssektorn står för en femtedel av Sveriges totala utsläpp av växthusgaser, därmed är det viktigt att minska utsläppen från sektorn. Stål är ett vanligt material som används inom byggsektorn. Produktionen av stål är energikrävande och leder till stora utsläpp av CO2. Det är utmanande att helt undvika användningen av stål inom byggsektorn, men det finns möjligheter att minska mängden stål i konstruktioner och därmed minska klimatpåverkan. Ett sätt att reducera materialåtgången och minska klimatpåverkan i en stålkonstruktion är att effektivisera konstruktionen och undvika överdimensionering. Målet med studien är att undersöka om det är möjligt att ändra de befintliga takbalkarna av HEB-profiler i ett reningsverk till IPE-profiler, med hänsyn till vippning, buckling och nedböjning. Målet är även att beräkna klimatrelaterade skillnader mellan de befintliga takbalkar av HEB-profilerna och de IPE-profiler som kan ersätta dem. Metod – Forskningsstrategin för studien tillämpas i form av en fallstudie, då studien syftar till att få en djupare förståelse kring undersökningsobjektet som är ett reningsverk. Datainsamlingsmetoden är en dokumentstudie där dokument används som sekundärdata för att sedan analyseras. Därefter används den analyserade datan för att besvara frågeställningarna i studien. Resultat – Resultaten av studien visar att genom att undvika överdimensionering kan mängden stål minskas för de befintliga takbalkarna i reningsverket, vilket också resulterade i minskade utsläpp av kg CO2eq. Analys – Analysen av studien visar att de befintliga takbalkar av HEB-profiler i takkonstruktionen i reningsverket kan effektiviseras genom att ersätta de med IPE-profiler. Det är gynnsamt att ändra de befintliga takbalkarna av HEB-profiler mot IPE-profiler för att minska mängden av stål och därmed utsläppen av koldioxidekvivalenter. Diskussion – Studien visar att kritiska faktorer som vippning, buckling och nedböjning är avgörande vid dimensionering av takbalkar. Vippning och nedböjning var mer avgörande än buckling vid dimensioneringen av takbalkarna i studien. Studien påvisar att de befintliga balkar av HEB-profiler i takkonstruktionen kunde ersättas med IPE-profiler både med och utan trapetsprofilerad plåt för sidostagning. Genom att införa sidostagning med trapetsprofilerad plåt minskades risken för vippning, vilket möjliggjorde en ytterligare minskning av dimensionerna på IPE-profiler och därmed minskning av stålanvändningen i takkonstruktionen. / Introduction (and aim) – The earth's middle temperature has risen exponentially since the industrialization in end of the 19th century. A rising middle temperature leads to climate changes such as heatwaves, floods, melting of the polar ice and rising of the see levels. It depends on Sweden and other countries to reduce the emissions from greenhouse gases. The construction and real estate industry causes one fifth of Sweden´s total emissions of greenhouse gases. Steel is a common construction material but the production of steel results in large emissions of CO2 and demands a lot of energy. It is challenging to cancel out steel from the construction sector, but possibilities exist to decrease the amount of steel which benefits the environment. One way to reduce the amount of steel is to optimize the construction and to avoid over dimensioning. The aim of this thesis is to research if it is possible to change HEB-roofbeams to IPE-roofbeams in a sewage plant, considering tilting, buckling and deflection. The aim is also to research the environmental impact between HEB 220 and the IPE-roofbeams whom can replace it. Method – The research strategy for this study is a case study which refers to a deeper understanding of an object. In this case the object is the sewage plant. The data collection method is a document study where documents are used as secondary data to be analyzed. The analyzed data is then used to answer the research questions of the study. Results – The results show that it is possible to avoid oversizing beams and that effectivization leads to a reduction of CO2eq emissions. Analysis – The analysis of the study indicates that the existing roof beams, composed of HEB profiles in the building's roof structure, can be effectives by replacing them with IPE beams. It is beneficial to change the existing roof beams from HEB profiles to IPE profiles in order to reduce the amount of steel and thus the emissions of CO2 equivalents. Discussion – The study shows dimensioning factors such as tilting, buckling and deflection determine the dimensions of the beams. Tilting and deflection were more critical than buckling in the dimensioning of the roof beams in the study. The study demonstrates that the existing beams made of HEB profiles in the roof structure could be replaced with IPE profiles, both with and without trapezoidal sheet metal for lateral bracing. By introducing lateral bracing with trapezoidal sheet metal, the risk of tipping was reduced, which enabled a further reduction in the dimensions of the IPE profiles and thus a reduction in steel usage in the roof structure. Buckling Carbon dioxide equivalents Deflection Environmental product declaration Production av steel beams Steel beams Tilting. Buckling Koldioxidekvivalenter Miljövarudeklaration Nedböjning Produktion av stålbalkar Stålbalkar Vippning. Building Technologies Husbyggnad
12	STEEL BEAMS STRENGTHENED WITH ULTRA HIGH MODULUS CFRP LAMINATES Peiris, Nisal Abheetha 01 January 2011 (has links) Advanced composites have become one of the most popular methods of repairing and/or strengthening civil infrastructure in the past couple of decades. While the use of Fiber Reinforced Polymer laminates and sheets for the repair and strengthening of reinforced concrete structures is well established, research on the application of FRP composites to steel structures has been limited. The use of FRP material for the repair and rehabilitation of steel members has numerous benefits over the traditional methods of bolting or welding of steel plates. Carbon FRPs (CFRPs) have been preferred over other FRP material for strengthening of steel structures since CFRPs tend to posses higher stiffness. The emergence of high modulus CFRP plates, with an elastic modulus higher than that of steel, enables researchers to achieve substantial load transfer in steel beams before the steel yields. This research investigates both analytically and experimentally, the bond characteristics between ultra high modulus CFRP strengthened steel members and the flexural behavior of these members. A series of double strap joint tests with two different CFRP strip widths are carried out to evaluate the development length of the bond. Both ultra high modulus and normal modulus CFRP laminates are used to compare strengthened member performance. Steel plates reinforced with CFRP laminates on both sides are loaded in tension to evaluate the load transfer characteristics. Debonding under flexural loads is also studied for ultra high modulus CFRP strengthened steel girders. Flexural tests are carried out under 4-point bending on several small scale wide flange beams. This study also introduces the novel ultra high modulus CFRP plate strip panels for strengthening of steel bridge girders. The first field application of ultra high modulus CFRP laminates in strengthening steel bridge girders in the United States is also carried out as part of the research. Full scale load tests carried out before and after the strengthening are utilized to measure the degree of strengthening achieved and checked against the expected results. A finite element model is developed and calibrated using data obtained from the field testing of the bridge. The model is then used to evaluate the behavior of the bridge under different conditions before and after the strengthening process. Carbon Fiber Plates Adhesive Steel Beams Bond Behavior Bridge Strengthening Civil Engineering Engineering
13	Quenching and tempering hardness response of front axle steel beams : Different material properties during quenching and tempering / Släckhärdning och anlöpning av hårdhetsresponsen hos fram axel balkar : Olika materialegenskaper vid släckning och härdning Zemui, Simon January 2017 (has links) The aim of this thesis was to investigate what the relation is between as-quench hardness and final surface hardness for steel beams is, depending on what tempering temperature is used. Also explain how chemistry, dimension and microstructure effects the final mechanical properties of the front axle beam. For this a review of literature concerning the effects was completed.Hardness measurement on the surface was performed on the ends of the beam (bottom and top). This hardness measurement was performed on 6 different front axle articles of the same material (41CrS4) and 2 different front axle articles of another material (40CrMo4). The relation diagram gives an estimation of what type of tempering temperature is needed to achieve the final hardness that is desired. Because the relation was done with some inconsistences it can’t be said to give a perfect answer. The relation diagrams only work for material 41CrS4 and 40CrMo4. For the core hardness test, 2 articles of 41CrS4 and one article of 40CrMo4 was measured on 5 different position on the cross-section, the beams for the respective articles were taken from quenched state and quenched+tempered. The beam dimensions have a significant effect when it comes to cooling down the part and achieve as close to uniform hardness as possible. Even though the Middle point of the I-section sample is one of the closest cores to the surface, it has a softer core compared with the other cores. While there exists hardness difference after quenching between different points in the core they even out after tempering. When comparing the core hardness with the surface hardness it can be said that the surface hardness is not as hard as the core because of decarburization. The microstructure analysis was done on 2 articles of 41CrS4 and one article of 40CrMo4. Samples from the 3 articles is taken from both the as-quenched state and quenched+tempered state. From the optical microscope it could be seen, that the surface of the beams decarbonizes leading to a higher amount of ferrite at the structure and softer surface. Because of this 15 mm into the material is harder than at-surface. Decarburization of the 41CrS4 steels made it so that what should have been a martensite and bainite dominated surface became a ferrite and bainite dominated.To decide the actual amount of retained austenite in the sample an XRD-analysis was performed. The XRD-analysis is done only for one article type of 41CrS4. From the front axle beam three samples of three different locations (bottom, middle, top) was taken for the analysis. For the theoretical calculation of the retained austenite vs the actual amount it can be said that is a very good representation of the total amount of retained austenite in the product. But the theoretical calculation deviates a bit from the actual amount at the top part of the beam. / Syftet med denna avhandling var att undersöka vad relationen är mellan härdat ythårdhet och slut ythårdhet för stålbalkar är, beroende på vilken anlöpnings temperatur som används. Tar också upp hur kemi, dimension och mikrostruktur påverkar de sista mekaniska egenskaperna hos framaxel balken. För detta genomfördes en genomgång av litteraturen om effekterna.Hårdhetsmätning på ytan utfördes på balkens ändar (botten och toppen). Denna hårdhetsmätning utfördes på 6 olika främre axelartiklar av samma material (41CrS4) och 2 olika främre axelartiklar av annat material (40CrMo4). Relationsdiagrammet ger en uppskattning av vilken typ av anlöpningstemperatur som behövs för att uppnå den slutliga hårdheten som önskas. Eftersom förhållandet gjordes med vissa inkonsekvenser kan det inte sägas ge ett perfekt svar. Relationsdiagrammen fungerar endast för material 41CrS4 och 40CrMo4.För kärnhårdhetstestet mättes 2 artiklar av 41CrS4 och en artikel av 40CrMo4 i 5 olika positioner på tvärsnittet, stålen för respektive artiklar togs från härdat tillstånd och härdat + anlöpt. Dimensionerna har en signifikant effekt när det gäller att kyla ner delen och uppnå så nära enhetlig hårdhet som möjligt. Även om mittpunkten i I-sektionsprovet är en av de närmaste kärnorna till ytan, så har det en mjukare kärna jämfört med de andra kärnorna. Det finns hårdhetsskillnad efter härdning mellan de olika punkter men de jämnar ut sig efter anlöpningen. När man jämför kärnhårdheten med ythårdheten kan man säga att ythårdheten inte är så hård på grund av avkolning.Mikrostrukturanalysen gjordes på 2 artiklar av 41CrS4 och en artikel av 40CrMo4. Prover från de 3 artiklarna tas från både härdat tillstånd och härdat + anlöpt tillstånd. Från det optiska mikroskopet kunde man se att stålbalkens yta har blivit utsatt för avkolning vilket leder till en högre mängd ferrit vid strukturen och en mjukare yta. På grund av detta, så är 15 mm in i materialet hårare än vid ytan. Avkolning av 41CrS4 stål gjorde så att det som borde ha varit ett martensit och bainit dominerat yta blev istället ferrit och bainit dominerat.XRD-analysen görs endast för en artikelart av 41CrS4. Från fram axelbalken togs tre prov från tre olika platser (botten, mitten, toppen) för analysen. För att bestämma den verkliga mängden restaustenit i provet utfördes en XRD-analys. För den teoretiska beräkningen av den rest austeniten jämfört med det faktiska beloppet kan man säga det är en mycket bra representation av den totala mängden kvarhållen austenit i produkten. Men den teoretiska beräkningen avviker lite från den faktiska mängden vid stålens övre del. Axle steel beams hardness Quenching tempering Bearbetnings-, yt- och fogningsteknik
14	The analysis of partial and damaged fire protection on structural steel at elevated temperature Krishnamoorthy, Renga Rao January 2011 (has links) Intumescent coating fire protection on steel structures is becoming widely popular in the UK and Europe. The current assessment for the fire protection performance method using the standard fire resistance tests is not accurate, owing to the reactive behaviour of intumescent coating at elevated temperature. Moreover, the available intumescent coating temperature assessment method provided in the Eurocode for structural steel at elevated temperature does not incorporate the steel beam's behaviour and/or assessment for partial protection and/or damaged protection. The research work presented provides additional information. on the assessment of partial and/or damaged intumescent coating at elevated temperature. In the scope of the investigation on the thermal conductivity of intumescent coating, it was found that the computed average thermal conductivity was marginally sensitive to the density and emissivity at elevated temperature. However, the thermal conductivity was found to be reasonably sensitive to the differences in initial dft's (dry film thicknesses). In this research, a numerical model was developed using ABAQUS to mimic actual indicative test scenarios to predict and establish the temperature distribution and the structural fire resistance of partial and/or damaged intumescent coating at elevated temperatures. Intumescent coating actively shields when the charring process occurs when the surface temperature reaches approximately 250°C to 350°C. Maximum deflection and deflection failure times for each damage scenario were analyzed by applying specified loading conditions. It was also found that the structural fire resistance failure mode of intumescent coating on protected steel beams was particularly sensitive to the applied boundary conditions. Careful selection of nodes in the element was necessary to avoid numerical instability and unexpected numerical error during analysis. An assessment of various numerical models subjected to a-standard fire with partially protected 1 mm intumescent coating was analysed using ABAQUS. An available unprotected test result was used as a benchmark. The outcome suggests that the fire resistances of the beams were found to be sensitive to the location of the partial and/or damage protection. The overall fire resistance behaviour of intumescent coating at elevated temperature was summarized in a 'typical deflection regression' curve. An extensive parametric analysis was performed on localized intumescent coating damage with various intumescent coating thicknesses between 0.5mm to 2.0mm. It was found that the average deflection was linear for the first 30 mins of exposure for all the variables, damage locations and intumescent thicknesses. It was concluded that a thicker layered intumescent coating may not be a better insulator or be compared to a much less thick intumescent coating at elevated temperature. The use of passive fire protection, however, does enhance the overall fire resistance of the steel beam, in contrast to a naked steel structure. The research work investigated the intumescent coating behaviour with different aspects of protection and damage and the outcome of the assessment provided a robust guide and additional understanding of the performance of intumescent coating at elevated temperature. 620.1717
15	Optimalizace technologie perlitizace masivních vývalků / Optimization of heat treatement for steel beams Dyčka, Martin January 2017 (has links) This thesis deals with heat treatment of pearlitic steel beams with using of induction heating. The aim of this heat treatment is to improve mechanical properties of steel beams. In theoretical part are described pearlitic steels and theory of induction heating. In experimental part of this thesis analysis of current state of technology with its results was made. Numerical model describing current state of technology was assembled. Then this model was used to recommend adjustments in current technology of heat treatment, which leads to enlargement of heat treated depth. Experiments with adjusted parameters were executed on heat treating machine. Analysis of microstructure using LM and EM, measurement of hardness and fractographic analysis were done. The result of adjustments is enlargement of heat treated depth about half compared with current technology.
16	FRP Strengthening of Steel I-Beams with Web Openings Humagain, Santosh January 2021 (has links) No description available. Civil Engineering FEA ANSYS steel beams web openings FRP CFRP AFRP BFRP strengthening
17	Determining the effective width of composite beams with precast hollowcore slabs El-Lobody, E., Lam, Dennis January 2005 (has links) This paper evaluates the effective width of composite steel beams with precast hollowcore slabs numerically using the finite element method. A parametric study, carried out on 27 beams with different steel cross sections, hollowcore unit depths and spans, is presented. The effective width of the slab is predicted for both the elastic and plastic ranges. 8-node three-dimensional solid elements are used to model the composite beam components. The material non-linearity of all the components is taken into consideration. The non-linear load-slip characteristics of the headed shear stud connectors are included in the analysis. The moment-deflection behaviour of the composite beams, the ultimate moment capacity and the modes of failure are also presented. Finally, the ultimate moment capacity of the beams evaluated using the present FE analysis was compared with the results calculated using the rigid – plastic method. Effective width Precast Hollowcore slabs Finite element Modelling Composite design Steel Concrete Composite steel beams
18	Capacities of headed stud shear connectors in composite steel beams with precast hollowcore slabs. Lam, Dennis January 2007 (has links) In steel¿concrete composite beams, the longitudinal shear force is transferred across the steel flange/concrete slab interface by the mechanical action of the shear connectors. The ability of the shear connectors to transfer these longitudinal shear forces depends on their strength, and also on the resistance of the concrete slab against longitudinal cracking induced by the high concentration of shear force. Most of the research in composite construction has concentrated on the more traditional reinforced concrete and metal deck construction, and little information is given on shear capacity of the headed studs in precast hollowcore slabs. In this paper, a standard push test procedure for use with composite beams with precast hollowcore slabs is proposed. Seven exploratory push tests were carried out on headed studs in solid RC slabs to validate the testing procedures, and the results showed that the new test is compatible with the results specified in the codes of practice for solid RC slabs. Once a standard procedure is established, 72 full-scale push tests on headed studs in hollowcore slabs were performed to determine the capacities of the headed stud connectors in precast hollowcore slabs and the results of the experimental study are analysed and findings on the effect of all the parameters on connectors¿ strength and ductility are presented. Newly proposed design equations for calculating the shear connectors¿ capacity for this form of composite construction are also be given. Precast Headed stud Connectors Composite steel beams Shear connection Push test Hollowcore slabs
19	Recent Research and Development in Composite Steel Beams with Precast Hollow Core Slabs. Lam, Dennis, Uy, B. January 2003 (has links) no / The recently published report on Rethinking Construction in the UK has highlighted the need to reduce on-site activities as part of its drive for greater efficiency, improved quality and greater certainty in the delivery of construction projects. For multi-storey buildings, the use of precast slabs in the floors - particularly if this can be done without the need for in-situ screeds - drastically reduces the volume of on-site concreting required. Although the use of precast hollow core slabs in steel framed buildings are common, their use in composite design with steel beams is relatively new. By designing the steel beams and precast hollow core slabs compositely, a reduction in beam size and overall floor depth can be achieved, which would lead to an overall reduction in construction cost. This paper summarises the recent developments and on-going research on composite construction with precast hollow core slabs. Construction Composite Tall buildings Concrete slabs Structural engineering Precast hollow core slabs Composite steel beams
20	Experiments on Cold-Formed Steel Beams with Holes Soroori Rad, Behrooz H. 22 June 2010 (has links) Experimental testing and elastic buckling studies were performed on 68 C-section cold-formed steel joists with unstiffened rectangular web holes. Four Steel Stud Manufacturers Association (SSMA) cross-section types; 800S200-33, 800S200-43, 1000S162-54, and 1200S162-97, were evaluated to explore the influence of holes on local, distortional, and global bucking failure modes. Hole depth was varied in the tests to identify trends in ultimate strength. Ultimate strength was observed to decrease with increasing hole depth for 800S200-33, 1200S162-97 cross-sections. Due to small number of specimen and unidentified behavior of the beams, a more in depth study of the behavior of 800S200-43 and 1000S162-54 beams are necessary. Local buckling of the unstiffened strip above the hole was observed to accompany distortional buckling at the hole for the locally slender 800S200-33 and 1000S162-54 cross-sections. Thin shell finite element eigen-buckling analysis of each joist specimen, including measured cross-section dimensions and tested boundary and loading conditions, were conducted in parallel with the experiments to identify those elastic buckling mode shapes which influence load-deformation response. The distortional and lateral-torsional buckling moments were observed to decrease with increasing hole depth while a contrasting behavior was captured for local buckling modes. A modification to the AISI Direct Strength Method equations for beams with slotted web-holes was compared against the experimental results with predictions lower than tested strength. Initial cross-section imperfections led to inclined webs which decreased the capacity of the beams. The use of a water-jet cutting process was employed successfully to produce accurate holes sizes and locations in each joist specimen and is recommended for researchers and manufacturers as a method for custom fabrication of cold-formed steel members. / Master of Science Cold-Formed Steel Beams Holes Elastic Buckling Finite element method Direct Strength Method

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