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Q1000858 Arquitetura
A janela sempre teve um grande papel no processo de composição arquitetônica, seja ela distribuída em uma série de aberturas, criando ritmo na fachada, seja em uma cortina de vidro cujas áreas envidraçadas se tornam a parede propriamente dita. Todavia, o excesso de radiação (direta e difusa) dessas soluções, dependendo da localização do edifício, podem trazer problemas quanto ao desempenho térmico e ao consumo energético. Uma das estratégias de bloqueio da radiação difusa é a redução das áreas envidraçadas, minimizando a visão do céu. Por essa razão, entende-se que a proporção entre as superfícies transparentes e opacas da fachada é de grande importância para o desempenho térmico do edifício. Sendo assim, essa proporção é dada pelo índice:
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Q1000857 Arquitetura
De acordo a NBR 9050 - Acessibilidade a edificações, mobiliário, espaços e equipamentos urbano - a sinalização direcional pode ser na forma:
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Q1000856 Arquitetura
A NBR 9050 - Acessibilidade a edificações, mobiliário, espaços e equipamentos urbano - estabelece critérios e parâmetros técnicos a serem observados quanto:
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Q1000855 Arquitetura
O coeficiente Global de Transmissão Térmica - K ou Transmitância Térmica engloba as trocas térmicas superficiais e as trocas térmicas através dos materiais. Esse coeficiente quantifica a capacidade do material de ser atravessado por um fluxo de calor induzido por uma diferença de temperatura entre dois ambientes que o elemento constituído por tal material separa. Sendo assim, o "K“ tem como unidade:
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Q1000854 Arquitetura
As trocas de calor que envolvem variação de temperatura são denominadas trocas secas. Os mecanismos de trocas secas são:
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Q1000853 Arquitetura
Na utilização da carta solar, o “observador”, seja ele uma pessoa, um ponto na fachada de um edifício ou uma janela, está:
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Q1000852 Arquitetura
As cartas solares são instrumentos para resolução de problemas de geometria da insolação a partir de plantas, cortes e coordenadas horizontais da posição do Sol acima da linha do horizonte. No hemisfério sul, a Carta solar aplicada sobre a planta, é orientada:
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Q1000851 Arquitetura
A Etiqueta PBE Edifica faz parte do Programa Brasileiro de Etiquetagem (PBE) e foi desenvolvida em parceria entre o Inmetro e a Eletrobras/PROCEL Edifica. Apesar de uso voluntário nas edificações, a Instrução Normativa N° 2, de 4 de junho de 2014, torna obrigatória a etiquetagem de edificações públicas federais. A referida Instrução Normativa dispõe sobre regras e uso da Etiqueta Nacional de Conservação de energia (ENCE) nos projetos e construções de edificações públicas federais, com área superior a 500m2, novas ou que recebam qualquer reforma que altere:
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Q1000850 Arquitetura
As políticas voluntárias de certificação ambiental existentes no mundo objetivam elevar o desempenho ambiental dos edifícios e, como consequência, fornecer-lhe um selo que agregue valor e ateste sua participação no processo. A partir da década de 1990, começou a surgir uma série de certificações ambientais que, ao redor do mundo, refletia a cultura de seu pais e as especificidades climáticas e construtivas peculiares a esses países. Entre as principais certificações temos: SustainableBuildingAssessment (SBAT); Leadership in Environmental Design (LEED); BuildingResearch Establishment Environmental AssessmentMethod (BREEAM); GermanSustainableBuildingCouncil (DGNB) e Alta Qualidade Ambiental (AQUA), que surgiram respectivamente nos seguintes países:
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Q1000849 Arquitetura
A produção de um concreto fácil de ser trabalhado e durável, a um custo econômico, requer cuidado no cálculo e manipulação da mistura. Praticamente todos os concretos devem satisfazer a uma especificação referente à compressão após 28 dias. Sendo assim, a principal influência sobre a resistência de um concreto é exercida pela relação entre:
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Q1000848 Arquitetura
Os átrios são espaços adjacentes às partes interiores de uma edificação, que combinam sistemas laterais e zenitais para captação da luz natural. Quanto à avaliação do desempenho de átrios na captação e distribuição da luz é correto afirmar que é complexa uma vez que envolve:
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Q1000847 Arquitetura
São nove as principais grandezas relativas à iluminação natural e artificial, e a maioria delas refere-se mais à iluminação artificial que à natural. Dentre as opções abaixo assinale a opção que apresenta apenas grandezas referentes à iluminação artificial.
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Q1000846 Arquitetura
Atualmente a ergonomia apresenta dois enfoques bem característicos segundo o tipo de abordagem do homem no trabalho: o enfoque americano e o enfoque europeu. Segundo essas abordagens é correto afirmar que:
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Q1000845 Arquitetura
O conforto pode ser definido como uma qualidade do espaço que envolve a percepção e a interpretação de estímulos de diversas ordens, provenientes de fatores como as formas, as dimensões, a iluminação, as cores, a qualidade do ar, os ruídos e as temperaturas, e os estímulos que os usuários recebem dependem, também, da tarefa realizada. Um dos aspectos mais essenciais no processo da avaliação do conforto ambiental e a percepção espacial é a compreensão de como os indivíduos percebem, assimilam e agem a partir de informações que captam no ambiente à sua volta. É a partir dessa compreensão que as tarefas exercidas em determinado ambiente podem ser melhoradas principalmente em relação ao conforto e à segurança do usuário. Sob este ponto de vista, insere-se a ergonomia, que avalia características antropométricas, influência do ambiente físico, características psicofisiológicas e características dos ritmos circadianos, dos indivíduos em determinado ambiente. Sendo assim, esses ritmos circadianos referem-se às atividades que regulam:
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Q978270 Inglês

                                                 Texto 4


      FRANK WHITTLE AND THE INVENTION OF THE JET ENGINE:

                            SIX PLACES TO TRACE HIS GENIUS


      It was, in many ways, a very British sort of achievement. When the turbine began to spin on the “WU” – the prototype jet engine developed by the Coventry-born engineer Frank Whittle – it was a moment which changed the world. Had you been passing through the byways of Rugby, in Warwickshire, more than 80 years ago, you might even have heard it. A thrum of mechanics in sync, building and building, growing in intensity to become a roar; a giddy howl which would permanently alter the way we journey around our planet.

      And yet it might so easily not have happened. Whittle’s triumph – on April 12, 1937 – was garnered in the face of official indifference and scientific doubt, and was only pulled off by a merest financial hair’s breadth, with the Second World War crowding in on all sides.

                                             ( . . . )

       Here was a visionary who began fomenting his design for a jet engine as early as 1927, and patented it in 1930, yet had to swim against the current after seeing his idea pooh-poohed by the UK's Air Ministry – which, upon seeing the blueprint in 1929, deemed it “impracticable.”

      Undeterred, Whittle took his own path. In January 1936, he founded a private company, Power Jets Ltd, with aeronautical engineer Rolf Dudley Williams and retired RAF officer James Collingwood Tinling. With £2,000 of funding from O.T. Falk & Partners – an investment bank which was known for taking risks – the trio began converting what had been decried as fantasy into reality. That first blur of blades as the WU (Whittle Unit) screamed into life was followed by a series of leaps forward.

      The Air Ministry placed its first order for Whittle’s brainwave in January 1940. The first jet-powered British plane took off from RAF Cranwell, Lincolnshire, on May 15, 1941. The rest is so much history.

      None of this occurred in isolation. The story of the jet engine can never be told without mentions of Maxime Guillaume, who secured a French patent for a jet engine with a gas turbine in 1921 (no prototype was ever produced as it was beyond the scope of existing technology), and of Hans Von Ohain, who beat Whittle to the punch by building the first fully operational jet engine in 1939 as Germany chased advantages in the global conflict.

                                               ( . . . )
  

RAF = Royal Air Force

LEADBEATER, C. Adaptado de Frank Whittle and the invention of the jet engine: Six places to trace his genius. In: The Telegraph. Disponível em: <https://www.telegraph.co.uk/travel/destinations/europe/unitedkingdom/england/articles/frank-whittle-and-the-birth-of-the-jet-engine/>. Acesso em: 08/06/2018


Choose the correct option.
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Q978269 Inglês

                                                 Texto 4


      FRANK WHITTLE AND THE INVENTION OF THE JET ENGINE:

                            SIX PLACES TO TRACE HIS GENIUS


      It was, in many ways, a very British sort of achievement. When the turbine began to spin on the “WU” – the prototype jet engine developed by the Coventry-born engineer Frank Whittle – it was a moment which changed the world. Had you been passing through the byways of Rugby, in Warwickshire, more than 80 years ago, you might even have heard it. A thrum of mechanics in sync, building and building, growing in intensity to become a roar; a giddy howl which would permanently alter the way we journey around our planet.

      And yet it might so easily not have happened. Whittle’s triumph – on April 12, 1937 – was garnered in the face of official indifference and scientific doubt, and was only pulled off by a merest financial hair’s breadth, with the Second World War crowding in on all sides.

                                             ( . . . )

       Here was a visionary who began fomenting his design for a jet engine as early as 1927, and patented it in 1930, yet had to swim against the current after seeing his idea pooh-poohed by the UK's Air Ministry – which, upon seeing the blueprint in 1929, deemed it “impracticable.”

      Undeterred, Whittle took his own path. In January 1936, he founded a private company, Power Jets Ltd, with aeronautical engineer Rolf Dudley Williams and retired RAF officer James Collingwood Tinling. With £2,000 of funding from O.T. Falk & Partners – an investment bank which was known for taking risks – the trio began converting what had been decried as fantasy into reality. That first blur of blades as the WU (Whittle Unit) screamed into life was followed by a series of leaps forward.

      The Air Ministry placed its first order for Whittle’s brainwave in January 1940. The first jet-powered British plane took off from RAF Cranwell, Lincolnshire, on May 15, 1941. The rest is so much history.

      None of this occurred in isolation. The story of the jet engine can never be told without mentions of Maxime Guillaume, who secured a French patent for a jet engine with a gas turbine in 1921 (no prototype was ever produced as it was beyond the scope of existing technology), and of Hans Von Ohain, who beat Whittle to the punch by building the first fully operational jet engine in 1939 as Germany chased advantages in the global conflict.

                                               ( . . . )
  

RAF = Royal Air Force

LEADBEATER, C. Adaptado de Frank Whittle and the invention of the jet engine: Six places to trace his genius. In: The Telegraph. Disponível em: <https://www.telegraph.co.uk/travel/destinations/europe/unitedkingdom/england/articles/frank-whittle-and-the-birth-of-the-jet-engine/>. Acesso em: 08/06/2018


Choose the correct option.


The sentence: “That first blur of blades as the WU (Whittle Unit) screamed into life was followed by a series of leaps forward” means that

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Q978268 Inglês

                                                 Texto 4


      FRANK WHITTLE AND THE INVENTION OF THE JET ENGINE:

                            SIX PLACES TO TRACE HIS GENIUS


      It was, in many ways, a very British sort of achievement. When the turbine began to spin on the “WU” – the prototype jet engine developed by the Coventry-born engineer Frank Whittle – it was a moment which changed the world. Had you been passing through the byways of Rugby, in Warwickshire, more than 80 years ago, you might even have heard it. A thrum of mechanics in sync, building and building, growing in intensity to become a roar; a giddy howl which would permanently alter the way we journey around our planet.

      And yet it might so easily not have happened. Whittle’s triumph – on April 12, 1937 – was garnered in the face of official indifference and scientific doubt, and was only pulled off by a merest financial hair’s breadth, with the Second World War crowding in on all sides.

                                             ( . . . )

       Here was a visionary who began fomenting his design for a jet engine as early as 1927, and patented it in 1930, yet had to swim against the current after seeing his idea pooh-poohed by the UK's Air Ministry – which, upon seeing the blueprint in 1929, deemed it “impracticable.”

      Undeterred, Whittle took his own path. In January 1936, he founded a private company, Power Jets Ltd, with aeronautical engineer Rolf Dudley Williams and retired RAF officer James Collingwood Tinling. With £2,000 of funding from O.T. Falk & Partners – an investment bank which was known for taking risks – the trio began converting what had been decried as fantasy into reality. That first blur of blades as the WU (Whittle Unit) screamed into life was followed by a series of leaps forward.

      The Air Ministry placed its first order for Whittle’s brainwave in January 1940. The first jet-powered British plane took off from RAF Cranwell, Lincolnshire, on May 15, 1941. The rest is so much history.

      None of this occurred in isolation. The story of the jet engine can never be told without mentions of Maxime Guillaume, who secured a French patent for a jet engine with a gas turbine in 1921 (no prototype was ever produced as it was beyond the scope of existing technology), and of Hans Von Ohain, who beat Whittle to the punch by building the first fully operational jet engine in 1939 as Germany chased advantages in the global conflict.

                                               ( . . . )
  

RAF = Royal Air Force

LEADBEATER, C. Adaptado de Frank Whittle and the invention of the jet engine: Six places to trace his genius. In: The Telegraph. Disponível em: <https://www.telegraph.co.uk/travel/destinations/europe/unitedkingdom/england/articles/frank-whittle-and-the-birth-of-the-jet-engine/>. Acesso em: 08/06/2018


Choose the correct option.
Alternativas
Q978267 Inglês

                                                 Texto 4


      FRANK WHITTLE AND THE INVENTION OF THE JET ENGINE:

                            SIX PLACES TO TRACE HIS GENIUS


      It was, in many ways, a very British sort of achievement. When the turbine began to spin on the “WU” – the prototype jet engine developed by the Coventry-born engineer Frank Whittle – it was a moment which changed the world. Had you been passing through the byways of Rugby, in Warwickshire, more than 80 years ago, you might even have heard it. A thrum of mechanics in sync, building and building, growing in intensity to become a roar; a giddy howl which would permanently alter the way we journey around our planet.

      And yet it might so easily not have happened. Whittle’s triumph – on April 12, 1937 – was garnered in the face of official indifference and scientific doubt, and was only pulled off by a merest financial hair’s breadth, with the Second World War crowding in on all sides.

                                             ( . . . )

       Here was a visionary who began fomenting his design for a jet engine as early as 1927, and patented it in 1930, yet had to swim against the current after seeing his idea pooh-poohed by the UK's Air Ministry – which, upon seeing the blueprint in 1929, deemed it “impracticable.”

      Undeterred, Whittle took his own path. In January 1936, he founded a private company, Power Jets Ltd, with aeronautical engineer Rolf Dudley Williams and retired RAF officer James Collingwood Tinling. With £2,000 of funding from O.T. Falk & Partners – an investment bank which was known for taking risks – the trio began converting what had been decried as fantasy into reality. That first blur of blades as the WU (Whittle Unit) screamed into life was followed by a series of leaps forward.

      The Air Ministry placed its first order for Whittle’s brainwave in January 1940. The first jet-powered British plane took off from RAF Cranwell, Lincolnshire, on May 15, 1941. The rest is so much history.

      None of this occurred in isolation. The story of the jet engine can never be told without mentions of Maxime Guillaume, who secured a French patent for a jet engine with a gas turbine in 1921 (no prototype was ever produced as it was beyond the scope of existing technology), and of Hans Von Ohain, who beat Whittle to the punch by building the first fully operational jet engine in 1939 as Germany chased advantages in the global conflict.

                                               ( . . . )
  

RAF = Royal Air Force

LEADBEATER, C. Adaptado de Frank Whittle and the invention of the jet engine: Six places to trace his genius. In: The Telegraph. Disponível em: <https://www.telegraph.co.uk/travel/destinations/europe/unitedkingdom/england/articles/frank-whittle-and-the-birth-of-the-jet-engine/>. Acesso em: 08/06/2018


Choose the correct option.
Alternativas
Q978266 Inglês

                                                 Texto 4


      FRANK WHITTLE AND THE INVENTION OF THE JET ENGINE:

                            SIX PLACES TO TRACE HIS GENIUS


      It was, in many ways, a very British sort of achievement. When the turbine began to spin on the “WU” – the prototype jet engine developed by the Coventry-born engineer Frank Whittle – it was a moment which changed the world. Had you been passing through the byways of Rugby, in Warwickshire, more than 80 years ago, you might even have heard it. A thrum of mechanics in sync, building and building, growing in intensity to become a roar; a giddy howl which would permanently alter the way we journey around our planet.

      And yet it might so easily not have happened. Whittle’s triumph – on April 12, 1937 – was garnered in the face of official indifference and scientific doubt, and was only pulled off by a merest financial hair’s breadth, with the Second World War crowding in on all sides.

                                             ( . . . )

       Here was a visionary who began fomenting his design for a jet engine as early as 1927, and patented it in 1930, yet had to swim against the current after seeing his idea pooh-poohed by the UK's Air Ministry – which, upon seeing the blueprint in 1929, deemed it “impracticable.”

      Undeterred, Whittle took his own path. In January 1936, he founded a private company, Power Jets Ltd, with aeronautical engineer Rolf Dudley Williams and retired RAF officer James Collingwood Tinling. With £2,000 of funding from O.T. Falk & Partners – an investment bank which was known for taking risks – the trio began converting what had been decried as fantasy into reality. That first blur of blades as the WU (Whittle Unit) screamed into life was followed by a series of leaps forward.

      The Air Ministry placed its first order for Whittle’s brainwave in January 1940. The first jet-powered British plane took off from RAF Cranwell, Lincolnshire, on May 15, 1941. The rest is so much history.

      None of this occurred in isolation. The story of the jet engine can never be told without mentions of Maxime Guillaume, who secured a French patent for a jet engine with a gas turbine in 1921 (no prototype was ever produced as it was beyond the scope of existing technology), and of Hans Von Ohain, who beat Whittle to the punch by building the first fully operational jet engine in 1939 as Germany chased advantages in the global conflict.

                                               ( . . . )
  

RAF = Royal Air Force

LEADBEATER, C. Adaptado de Frank Whittle and the invention of the jet engine: Six places to trace his genius. In: The Telegraph. Disponível em: <https://www.telegraph.co.uk/travel/destinations/europe/unitedkingdom/england/articles/frank-whittle-and-the-birth-of-the-jet-engine/>. Acesso em: 08/06/2018


Choose the correct option.
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Q978265 Inglês

                                           Texto 3

THE DISCOVERY OF PENICILLIN—NEW INSIGHTS AFTER MORE THAN 75 YEARS OF CLINICAL USE


ABSTRACT   

        After just over 75 years of penicillin’s clinical use, the world can see that its impact was immediate and profound. In 1928, a chance event in Alexander Fleming’s London laboratory changed the course of medicine. However, the purification and first clinical use of penicillin would take more than a decade. Unprecedented United States/Great Britain cooperation to produce penicillin was incredibly successful by 1943. This success overshadowed efforts to produce penicillin during World War II in Europe, particularly in the Netherlands. Information about these efforts, available only in the last 10–15 years, provides new insights into the story of the first antibiotic. Researchers in the Netherlands produced penicillin using their own production methods and marketed it in 1946, which eventually increased the penicillin supply and decreased the price. The unusual serendipity involved in the discovery of penicillin demonstrates the difficulties in finding new antibiotics and should remind health professionals to expertly manage these extraordinary medicines.

                                                      ( . . . )

GAYNES, R. The Discovery of Penicillin—New Insights After More Than 75 Years of Clinical Use. In: Science, 2017. Disponível em: <http://wwwnc.cdc.gov/eid/article/23/5/16-1556_article>. Acesso em: 26/06/2018.

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The meaning of the word “serendipity” in the sentence: “The unusual serendipity involved in the discovery of penicillin demonstrates the difficulties in finding new antibiotics (...)” is:

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Respostas
201: D
202: A
203: C
204: C
205: A
206: E
207: B
208: A
209: B
210: D
211: C
212: E
213: A
214: D
215: E
216: E
217: C
218: D
219: A
220: B