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1	Desenvolvimento de processo de extrusão e prensagem de rebites de aço inox Vagliatti, Rafael Brufatto January 2017 (has links) Este trabalho analisou as diferenças entre o processo de conformação de rebites de Alumínio da liga AA 5052 e de aço inoxidável das ligas ABNT 420, ABNT 430 e ABNT 302, os quais são utilizados em grande escala na indústria cuteleira. Levando em conta as particularidades de cada material em estudo, foram analisadas as forças de conformação, tensões, deformações e temperaturas. A partir delas buscou-se chegar a um modelo de processo viável para se obter rebites de Aço inoxidável. Apesar da fabricação do rebite de Alumínio ser menos crítica, no que diz respeito a força necessária para conformação, a qualidade do produto é inferior, quando se compara com o Aço inoxidável. Este confere maior resistência mecânica e resistência à corrosão. Para modelamento do processo desenvolvido com o Alumínio AA5052 e com as ligas de Aço inoxidável utilizadas utilizou-se o software de simulação por elementos finitos SIMUFACT 11.0. Os resultados das simulações com o aço inoxidável com temperaturas a morno demonstraram grande dependência da temperatura para obtenção de tensões e forças suportadas pelo ferramental. Alguns resultados alcançados com o aço inoxidável aquecido, quando se variaram as temperaturas de 25ºC até 500ºC, geraram o grau de tensões e esforços no ferramental menor ou igual à condição onde o Alumínio é conformado a frio. Também, critérios como resistência à corrosão foram determinantes para a aprovação das ligas de aço inoxidável 302 e 430 estudadas. Esse resultado confirmou o que é indicado na bibliografia, onde são recomendadas ligas austeníticas e ferríticas, ao invés de martensíticas, para a fabricação de produtos de aço inoxidável que exigem alta resistência à corrosão, como é o caso dos rebites. / This study analyzed the differences between the rivet manufacturing process made by Aluminum of alloy AA5052 and Stainless Steel of alloys AISI 420, AISI 430 and AISI 302, wich are widely used in the cutlery industry. Taking into account the particularities of both materials, it was analyzed forming forces, stresses, strains and temperatures in order to find a viable process to manufacture stainless steel rivets. Even the manufacturing of Aluminum rivets is less critical, regarding the forming forces, the quality of the product is inferior than the stainless steel, wich provides more mechanical and corrosion resistance. The study of the process of forming Aluminum AA5052 and Stainless Steel rivets was developed using the finite elements software SIMUFACT 11.0. The simulation results of the Stainless Steel with warm temperatures showed big influence of the temperature to obtain lower stresses and forces, wich are supported by the tools. Some results with heated Stainless steel, considering temperatures from 25ºC to 500ºC, resulted in lower stress and tool forces than in the Aluminum with cold temperatures. Also, criteria like corrosion resistance was very important to the approval of the Stainless Steel AISI 302 and AISI 430. Those results confirm the information available in the bibliography, where it is preferential austenitic and ferritic alloys of stainless steel instead of martensitic alloys, when used to manufacture stainless steel rivets, wich require high corrosion resistance. Rebite (Engenharia) Aço inoxidável Extrusão Prensagem Backward extrusion Finite Elements Method Stainless steel Rivets Pressing
2	Desenvolvimento de processo de extrusão e prensagem de rebites de aço inox Vagliatti, Rafael Brufatto January 2017 (has links) Este trabalho analisou as diferenças entre o processo de conformação de rebites de Alumínio da liga AA 5052 e de aço inoxidável das ligas ABNT 420, ABNT 430 e ABNT 302, os quais são utilizados em grande escala na indústria cuteleira. Levando em conta as particularidades de cada material em estudo, foram analisadas as forças de conformação, tensões, deformações e temperaturas. A partir delas buscou-se chegar a um modelo de processo viável para se obter rebites de Aço inoxidável. Apesar da fabricação do rebite de Alumínio ser menos crítica, no que diz respeito a força necessária para conformação, a qualidade do produto é inferior, quando se compara com o Aço inoxidável. Este confere maior resistência mecânica e resistência à corrosão. Para modelamento do processo desenvolvido com o Alumínio AA5052 e com as ligas de Aço inoxidável utilizadas utilizou-se o software de simulação por elementos finitos SIMUFACT 11.0. Os resultados das simulações com o aço inoxidável com temperaturas a morno demonstraram grande dependência da temperatura para obtenção de tensões e forças suportadas pelo ferramental. Alguns resultados alcançados com o aço inoxidável aquecido, quando se variaram as temperaturas de 25ºC até 500ºC, geraram o grau de tensões e esforços no ferramental menor ou igual à condição onde o Alumínio é conformado a frio. Também, critérios como resistência à corrosão foram determinantes para a aprovação das ligas de aço inoxidável 302 e 430 estudadas. Esse resultado confirmou o que é indicado na bibliografia, onde são recomendadas ligas austeníticas e ferríticas, ao invés de martensíticas, para a fabricação de produtos de aço inoxidável que exigem alta resistência à corrosão, como é o caso dos rebites. / This study analyzed the differences between the rivet manufacturing process made by Aluminum of alloy AA5052 and Stainless Steel of alloys AISI 420, AISI 430 and AISI 302, wich are widely used in the cutlery industry. Taking into account the particularities of both materials, it was analyzed forming forces, stresses, strains and temperatures in order to find a viable process to manufacture stainless steel rivets. Even the manufacturing of Aluminum rivets is less critical, regarding the forming forces, the quality of the product is inferior than the stainless steel, wich provides more mechanical and corrosion resistance. The study of the process of forming Aluminum AA5052 and Stainless Steel rivets was developed using the finite elements software SIMUFACT 11.0. The simulation results of the Stainless Steel with warm temperatures showed big influence of the temperature to obtain lower stresses and forces, wich are supported by the tools. Some results with heated Stainless steel, considering temperatures from 25ºC to 500ºC, resulted in lower stress and tool forces than in the Aluminum with cold temperatures. Also, criteria like corrosion resistance was very important to the approval of the Stainless Steel AISI 302 and AISI 430. Those results confirm the information available in the bibliography, where it is preferential austenitic and ferritic alloys of stainless steel instead of martensitic alloys, when used to manufacture stainless steel rivets, wich require high corrosion resistance. Rebite (Engenharia) Aço inoxidável Extrusão Prensagem Backward extrusion Finite Elements Method Stainless steel Rivets Pressing
3	Desenvolvimento de processo de extrusão e prensagem de rebites de aço inox Vagliatti, Rafael Brufatto January 2017 (has links) Este trabalho analisou as diferenças entre o processo de conformação de rebites de Alumínio da liga AA 5052 e de aço inoxidável das ligas ABNT 420, ABNT 430 e ABNT 302, os quais são utilizados em grande escala na indústria cuteleira. Levando em conta as particularidades de cada material em estudo, foram analisadas as forças de conformação, tensões, deformações e temperaturas. A partir delas buscou-se chegar a um modelo de processo viável para se obter rebites de Aço inoxidável. Apesar da fabricação do rebite de Alumínio ser menos crítica, no que diz respeito a força necessária para conformação, a qualidade do produto é inferior, quando se compara com o Aço inoxidável. Este confere maior resistência mecânica e resistência à corrosão. Para modelamento do processo desenvolvido com o Alumínio AA5052 e com as ligas de Aço inoxidável utilizadas utilizou-se o software de simulação por elementos finitos SIMUFACT 11.0. Os resultados das simulações com o aço inoxidável com temperaturas a morno demonstraram grande dependência da temperatura para obtenção de tensões e forças suportadas pelo ferramental. Alguns resultados alcançados com o aço inoxidável aquecido, quando se variaram as temperaturas de 25ºC até 500ºC, geraram o grau de tensões e esforços no ferramental menor ou igual à condição onde o Alumínio é conformado a frio. Também, critérios como resistência à corrosão foram determinantes para a aprovação das ligas de aço inoxidável 302 e 430 estudadas. Esse resultado confirmou o que é indicado na bibliografia, onde são recomendadas ligas austeníticas e ferríticas, ao invés de martensíticas, para a fabricação de produtos de aço inoxidável que exigem alta resistência à corrosão, como é o caso dos rebites. / This study analyzed the differences between the rivet manufacturing process made by Aluminum of alloy AA5052 and Stainless Steel of alloys AISI 420, AISI 430 and AISI 302, wich are widely used in the cutlery industry. Taking into account the particularities of both materials, it was analyzed forming forces, stresses, strains and temperatures in order to find a viable process to manufacture stainless steel rivets. Even the manufacturing of Aluminum rivets is less critical, regarding the forming forces, the quality of the product is inferior than the stainless steel, wich provides more mechanical and corrosion resistance. The study of the process of forming Aluminum AA5052 and Stainless Steel rivets was developed using the finite elements software SIMUFACT 11.0. The simulation results of the Stainless Steel with warm temperatures showed big influence of the temperature to obtain lower stresses and forces, wich are supported by the tools. Some results with heated Stainless steel, considering temperatures from 25ºC to 500ºC, resulted in lower stress and tool forces than in the Aluminum with cold temperatures. Also, criteria like corrosion resistance was very important to the approval of the Stainless Steel AISI 302 and AISI 430. Those results confirm the information available in the bibliography, where it is preferential austenitic and ferritic alloys of stainless steel instead of martensitic alloys, when used to manufacture stainless steel rivets, wich require high corrosion resistance. Rebite (Engenharia) Aço inoxidável Extrusão Prensagem Backward extrusion Finite Elements Method Stainless steel Rivets Pressing
4	Výroba drážkového náboje / Production of splined sleeve Vališ, Ondřej January 2020 (has links) The master’s thesis submits a technological project of production of splined sleeve used in automotive as a component of propeller shaft. The part is made of steel ČSN 11 523 by bulk forming technology in an annual production series of 20 000 pieces. Production process was designed in four operations, after the second operation there was recrystallization annealing included for regeneration of plasticity before following extrusion. There were made technological calculations for these production operations. Operations were projected to be done by common one-operation press machines available in local manufacturing facility. For all the operations were designed functional tools and tools setups. In conclusion, there was performed technical-economic evaluation. As emerged from this evaluation the final amount of total production costs for one piece is 131,- Kč. When 9 393 pieces are produced, the production series reaches to the break-even point and then the profit starts to be generated.
5	Návrh výroby pouzdra tlakového filtru / Production of pressure filter casing Janoušek, Jiří January 2021 (has links) The project presents a proposal for the technology of production of the pressure filter casing used in hydraulic systems, which is made of non-alloy carbon steel 12 020. With the help of a literature study of cold extrusion and calculations, the production of the component was designed, which will take place in two operations. Before each operation, the surface treatment is performed by phosphating and soaping and inter-operational annealing must take place. Tool sets were designed for both operations and a press was selected from the company's machine park with a nominal force of 25,000 kN. Finally, a technical and economic evaluation was proved, which shows that the price of production of one piece is CZK 187. The turning point was set at 3 497 pieces per year.
6	Výroba pístu diskové brzdy objemovým tvářením / Bulk forming technology of piston of disk brake Toman, Svatopluk January 2008 (has links) The project of Master’s thesis elaborated within engineering studies of branch 23-03-T002 proposes a technology of production of disk brake piston made of low-carbon steel EN C10E. Supposed production amount is 300 000 pieces per year. With knowledge of literary study on the theme of cold steel bulk forming, three variants of production technique were proposed. The chosen one, for which the technological and energy computations were accomplished, consists of two basic forming operations. For manufacture realization was selected three-stage automatic forming machine TPD 630 (manufacturer Šmeral Brno) with nominal forming output of 6 300 kN. As a material of extruding punch, tool-steel EN X100CrMoV5-1was chosen. For extruding dies was selected high speed steel HS 6-5-2 and its shrink ring is made of high quality steel 60WCrV8. Optimalization of tool properties was performed with specialized PC software.
7	Výroba pouzdra pružiny objemovým tvářením / Production of spring buch by cold forming Kosek, Lukáš January 2013 (has links) The master’s thesis presents a concept for spring bush manufacturing made of 11 320-5R steel by cold forming. Five steps process of manufacturing is based on the literary studies and technical calculations. The multistage cold forming machine HATEBUR AKP 5-5 was chosen for selected option of forming technology. As raw material was used cylinder shape with diameter of 26 mm and length of 29 mm. The economic results fix the price of one component of 16 CZK for annual dose 250 000 pieces.
8	微細複合組織金属の変形機構および塑性加工性に関する研究 / ビサイフクゴウソシキキンゾクノヘンケイキコウオヨビソセイカコウセイニカンスルケンキュウ名取恵子, Keiko Natori 22 March 2014 (has links) ヘテロ構造組織を有する鉄・非鉄金属の組織形態に注目して,微視的構造やその挙動が巨視的現象(変形特性,成形性)として発現するメカニズムを解明することを目的とした.鉄系金属ではDual Phase型高張力鋼のスプリングバック現象のひずみ速度依存性,非鉄系金属では半凝固鋳造法と強ひずみ加工を組み合わせた亜共晶アルミニウム合金の衝撃後方押出し成形性に注目した.これらの検討によりいずれの試料においても,結晶粒界よりもスケールの大きいヘテロ構造に由来した変形機構が支配的であることが明らかになった. / 博士(工学) / Doctor of Philosophy in Engineering / 同志社大学 / Doshisha University 二相鋼高張力鋼バウシンガー効果ハット曲げスプリングバックひずみ速度依存性アルミニウム合金共晶半凝固鋳造強ひずみ加工 ECAP加工衝撃後方押出し Dual Phase steel high strength steel Bauschinger effect hat-bending forming springback strain rate dependence Aluminum alloy eutectic semi-solid cast Severe Plastic Deformation equal-channel angular pressing impact backward extrusion

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