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1 reinforced concrete buildings
Строительные конструкции: дома из конструкций крупнопанельного домостроенияУниверсальный англо-русский словарь > reinforced concrete buildings
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2 дома из конструкций крупнопанельного домостроения
Building structures: reinforced concrete buildings, prefabricated large-panel housingУниверсальный русско-английский словарь > дома из конструкций крупнопанельного домостроения
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3 hormigón
m.concrete.* * *1 concrete\hormigón armado reinforced concrete* * *noun m.* * *SM concrete* * *masculino concrete* * *= concrete.Ex. An enquirer wishes to retrieve documents on the 'finishing of concrete floors for industrial buildings'.----* bloque de hormigón = breeze block, cinder block, concrete block.* hormigón armado = reinforced concrete.* muro de hormigón = concrete wall.* viga de hormigón = concrete beam.* * *masculino concrete* * *= concrete.Ex: An enquirer wishes to retrieve documents on the 'finishing of concrete floors for industrial buildings'.
* bloque de hormigón = breeze block, cinder block, concrete block.* hormigón armado = reinforced concrete.* muro de hormigón = concrete wall.* viga de hormigón = concrete beam.* * *concreteCompuestos:reinforced concreteprestressed concrete* * *
hormigón sustantivo masculino
concrete
hormigón sustantivo masculino concrete, cement
hormigón armado, reinforced concrete
' hormigón' also found in these entries:
Spanish:
armada
- armado
- concreta
- concreto
- bloque
- mole
English:
concrete
- reinforced concrete
- set
- slab
* * *hormigón nmconcretehormigón armado reinforced concrete* * *m concrete* * ** * *hormigón n concrete -
4 hueco de servicio
(n.) = service coreEx. The title 'Torsion in the reinforced concrete in service cores in tall buildings' contains four separate elementary or unit concepts: torsion, reinforced concrete, service cores, tall buildings.* * *(n.) = service coreEx: The title 'Torsion in the reinforced concrete in service cores in tall buildings' contains four separate elementary or unit concepts: torsion, reinforced concrete, service cores, tall buildings.
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5 torsión
f.torsion, twist.* * *1 (torcedura) twist, twisting2 TÉCNICA torsion* * *noun f.twisting, torsion* * *SF1) (=torcedura) twist, twisting2) (Mec) torsion, torque* * *femenino torsion* * *= torsion, buckle, buckling effect.Ex. The title 'Torsion in the reinforced concrete in service cores in tall buildings' contains four separate elementary or unit concepts: torsion, reinforced concrete, service cores, tall buildings.Ex. The thermal deflection increased little or kept invariable with the continuous increase in temperature after the thermal buckle had occurred.Ex. For example, a model of an aircraft wing can be 'opened-up' on the screen to examine the buckling effects of the simulated loading on the wing's internal structure.----* par de torsión = torque.* * *femenino torsion* * *= torsion, buckle, buckling effect.Ex: The title 'Torsion in the reinforced concrete in service cores in tall buildings' contains four separate elementary or unit concepts: torsion, reinforced concrete, service cores, tall buildings.
Ex: The thermal deflection increased little or kept invariable with the continuous increase in temperature after the thermal buckle had occurred.Ex: For example, a model of an aircraft wing can be 'opened-up' on the screen to examine the buckling effects of the simulated loading on the wing's internal structure.* par de torsión = torque.* * *torsioncon una leve torsión del tronco with a slight twist of the upper body* * *
torsión sustantivo femenino
torsion
torsión sustantivo femenino
1 (torcimiento) twisting
2 Téc torsion
resistencia a la torsión, torsion resistance
* * *torsión nf1. [del cuerpo, brazo] twist, twisting2. Tec torsion* * *f twisting; TÉC torsion* * *♦ torsional adj -
6 Perret, Auguste
[br]b. 12 February 1874 Ixelles, near Brussels, Belgiumd. 26 February 1954 Le Havre (?), France[br]French architect who pioneered and established building design in reinforced concrete in a style suited to the modern movement.[br]Auguste Perret belonged to the family contracting firm of A. \& G.Perret, which early specialized in the use of reinforced concrete. His eight-storey building at 25 bis Rue Franklin in Paris, built in 1902–3, was the first example of frame construction in this material and established its viability for structural design. Both ground plan and façade are uncompromisingly modern, the simplicity of the latter being relieved by unobtrusive faience decoration. The two upper floors, which are set back, and the open terrace roof garden set a pattern for future schemes. All of Perret's buildings had reinforced-concrete structures and this was clearly delineated on the façade designs. The concept was uncommon in Europe at the time, when eclecticism still largely ruled, but was derived from the late nineteenth-century skyscraper façades built by Louis Sullivan in America. In 1905–6 came Perret's Garage Ponthieu in Paris; a striking example of exposed concrete, it had a central façade window glazed in modern design in rich colours. By the 1920s ferroconcrete was in more common use, but Perret still led the field in France with his imaginative, bold use of the material. His most original structure is the Church of Notre Dame at Le Raincy on the outskirts of Paris (1922–3). The imposing exterior with its tall tower in diminishing stages is finely designed, but the interior has magnificence. It is a wide, light church, the segmented vaulted roof supported on slender columns. The whole structure is in concrete apart from the glass window panels, which extend the full height of the walls all around the church. They provide a symphony of colour culminating in deep blue behind the altar. Because of the slenderness of the columns and the richness of the glass, this church possesses a spiritual atmosphere and unimpeded sight and sound of and from the altar for everyone. It became the prototype for churches all over Europe for decades, from Moser in prewar Switzerland to Spence's postwar Coventry Cathedral.In a long working life Perret designed buildings for a wide range of purposes, adhering to his preference for ferroconcrete and adapting its use according to each building's needs. In the 1940s he was responsible for the railway station at Amiens, the Atomic Centre at Saclay and, one of his last important works, the redevelopment after wartime damage of the town centre of Le Havre. For the latter, he laid out large open squares enclosed by prefabricated units, which display a certain monotony, despite the imposing town hall and Church of St Joseph in the Place de L'Hôtel de Ville.[br]Principal Honours and DistinctionsPresident des Réunions Internationales des Architectes. American Society of the French Legion of Honour Gold Medal 1950. Elected after the Second World War to the Institut de France. First President of the International Union of Architects on its creation in 1948. RIBA Royal Gold Medal 1948.Further ReadingP.Blater, 1939, "Work of the architect A.Perret", Architektura SSSR (Moscow) 7:57 (illustrated article).1848 "Auguste Perret: a pioneer in reinforced concrete", Civil Engineers' Review, pp.296–300.Peter Collins, 1959, Concrete: The Vision of a New Architecture: A Study of Auguste Perret and his Precursors, Faber \& Faber.Marcel Zahar, 1959, D'Une Doctrine d'Architecture: Auguste Perret, Paris: Vincent Fréal.DY -
7 Nervi, Pier Luigi
[br]b. 21 June 1891 Sondrio, Italyd. 9 January 1979 (?), Italy[br]Italian engineer who played a vital role in the use and adaptation of reinforced concrete as a structural material from the 1930s to the 1970s.[br]Nervi early established a reputation in the use of reinforced concrete with his stadium in Florence (1930–2). This elegant concrete structure combines graceful curves with functional solidity and is capable of seating some 35,000 spectators. The stadium was followed by the aircraft hangars built for the Italian Air Force at Orvieto and Ortebello, in which he spanned the vast roofs of the hangars with thin-shelled vaults supported by precast concrete beams and steel-reinforced ribs. The structural strength and subtle curves of these ribbed roofs set the pattern for Nervi's techniques, which he subsequently varied and elaborated on to solve problems that arose in further commissions.Immediately after the Second World War Italy was short of supplies of steel for structural purposes so, in contrast to the USA, Britain and Germany, did not for some years construct any quantity of steel-framed rectangular buildinngs used for offices, housing or industrial use. It was Nervi who led the way to a ferroconcrete approach, using a new type of structure based on these materials in the form of a fine steel mesh sprayed with cement mortar and used to roof all kinds of structures. It was a method that resulted in expressionist curves instead of rectangular blocks, and the first of his great exhibition halls at Turin (1949), with a vault span of 240 ft (73 m), was an early example of this technique. Nervi continued to create original and beautiful ferroconcrete structures of infinite variety: for example, the hall at the Lido di Roma, Ostia; the terme at Chianciano; and the three buildings that he designed for the Rome Olympics in 1960. The Palazzetto dello Sport is probably the most famous of these, for which he co-operated with the architect Annibale Vitellozzi to construct a small sports palace seating 5,000 spectators under a concrete "big top" of 194 ft (59 m) diameter, its enclosing walls supported by thirtysix guy ropes of concrete; inside, the elegant roof displays a floral quality. In 1960 Nervi returned to Turin to build his imaginative Palace of Labour for the centenary celebrations of Garibaldi and Victor Emmanuel in the city. This vast hall, like the Crystal Palace in England a century earlier (see Paxton), had to be built quickly and be suitable for later adaptation. It was therefore constructed partly in steel, and the metal supporting columns rose to palm-leaf capitals reminiscent of those in ancient Nile palaces.Nervi's aim was always to create functional buildings that simultaneously act by their aesthetic qualities as an effective educational influence. Functionalism for Nervi never became "brutalism". In consequence, his work is admired by the lay public as well as by architects. He collaborated with many of the outstanding architects of the day: with Gio Ponti on the Pirelli Building in Milan (1955–9); with Zehrfuss and Breuer on the Y-plan UNESCO Building in Paris (1953–7); and with Marcello Piacentini on the 16,000-seat Palazzo dello Sport in Rome. Nervi found time to write a number of books on building construction and design, lectured in the Universities of Rio de Janiero and Buenos Aires, and was for many years Professor of Technology and Technique of Construction in the Faculty of Architecture at the University of Rome. He continued to design new structures until well into the 1970s.[br]Principal Honours and DistinctionsRIBA Royal Gold Medal 1960. Royal Institute of Structural Engineers Gold Medal 1968. Honorary Degree Edinburgh University, Warsaw University, Munich University, London University, Harvard University. Member International Institute of Arts and Letters, Zurich; American Academy of Arts and Sciences; Royal Academy of Fine Arts, Stockholm.Bibliography1956, Structures, New York: Dodge.1945, Scienza o Arte del Costruire?, Rome: Bussola.Further ReadingP.Desideri et al., 1979, Pier Luigi Nervi, Bologna: Zanichelli.A.L.Huxtable, 1960, Masters of World Architecture; Pier Luigi Nervi, New York: Braziller.DY -
8 Wright, Frank Lloyd
SUBJECT AREA: Architecture and building[br]b. 8 June 1869 Richland Center, Wisconsin, USAd. 9 April 1959 Phoenix, Arizona, USA[br]American architect who, in an unparalleled career spanning almost seventy years, became the most important figure on the modern architectural scene both in his own country and far further afield.[br]Wright began his career in 1887 working in the Chicago offices of Adler \& Sullivan. He conceived a great admiration for Sullivan, who was then concentrating upon large commercial projects in modern mode, producing functional yet decorative buildings which took all possible advantage of new structural methods. Wright was responsible for many of the domestic commissions.In 1893 Wright left the firm in order to set up practice on his own, thus initiating a career which was to develop into three distinct phases. In the first of these, up until the First World War, he was chiefly designing houses in a concept in which he envisaged "the house as a shelter". These buildings displayed his deeply held opinion that detached houses in country areas should be designed as an integral part of the landscape, a view later to be evidenced strongly in the work of modern Finnish architects. Wright's designs were called "prairie houses" because so many of them were built in the MidWest of America, which Wright described as a "prairie". These were low and spreading, with gently sloping rooflines, very plain and clean lined, built of traditional materials in warm rural colours, blending softly into their settings. Typical was W.W.Willit's house of 1902 in Highland Park, Illinois.In the second phase of his career Wright began to build more extensively in modern materials, utilizing advanced means of construction. A notable example was his remarkable Imperial Hotel in Tokyo, carefully designed and built in 1916–22 (now demolished), with special foundations and structure to withstand (successfully) strong earthquake tremors. He also became interested in the possibilities of reinforced concrete; in 1906 he built his church at Oak Park, Illinois, entirely of this material. In the 1920s, in California, he abandoned his use of traditional materials for house building in favour of precast concrete blocks, which were intended to provide an "organic" continuity between structure and decorative surfacing. In his continued exploration of the possibilities of concrete as a building material, he created the dramatic concept of'Falling Water', a house built in 1935–7 at Bear Run in Pennsylvania in which he projected massive reinforced-concrete terraces cantilevered from a cliff over a waterfall in the woodlands. In the later 1930s an extraordinary run of original concepts came from Wright, then nearing 70 years of age, ranging from his own winter residence and studio, Taliesin West in Arizona, to the administration block for Johnson Wax (1936–9) in Racine, Wisconsin, where the main interior ceiling was supported by Minoan-style, inversely tapered concrete columns rising to spreading circular capitals which contained lighting tubes of Pyrex glass.Frank Lloyd Wright continued to work until four days before his death at the age of 91. One of his most important and certainly controversial commissions was the Solomon R.Guggenheim Museum in New York. This had been proposed in 1943 but was not finally built until 1956–9; in this striking design the museum's exhibition areas are ranged along a gradually mounting spiral ramp lit effectively from above. Controversy stemmed from the unusual and original design of exterior banding and interior descending spiral for wall-display of paintings: some critics strongly approved, while others, equally strongly, did not.[br]Principal Honours and DistinctionsRIBA Royal Gold Medal 1941.Bibliography1945, An Autobiography, Faber \& Faber.Further ReadingE.Kaufmann (ed.), 1957, Frank Lloyd Wright: an American Architect, New York: Horizon Press.H.Russell Hitchcock, 1973, In the Nature of Materials, New York: Da Capo.T.A.Heinz, 1982, Frank Lloyd Wright, New York: St Martin's.DY -
9 joint
1) соединение; сочленение; шарнир2) узел фермы; геометрический узел4) геол. трещина5) замок ( для канатов)6) совместный ( о предприятии)7) соединять ( при помощи вставных частей); наращивать•- abutment joint - abutting joint - adhesive joint - airtight joint - alternate joints - angle joint - angle half-lap joint - arc-welded joint - articulated joint - asymmetric joint - back joint - ball joint - ball-and-socket joint - bayonet joint - bead joint - beam butt joint - beam-to-beam joint - beam-to-beam moment joint - beam-to-column joint - bed joint - bell-and-plain end joint - bell-and-spigot joint - bell butt joint - bellows joint - bevelled joint - bleeding joint - blind joint - bolt joint - bolted joint - bolt-adhesive joint - bracket joint - branch joint - branch tee-saddle joint - brazed joint - brazed-welded joint - breaking joints - brick joint - brickwork joints - bricks joints - bridge joint - bridle joint - broken joints - building wall joints - butt joint - butt-and-collar joint - buttered joint - cable joint - carpenter's joint - cash joint - castellated joint - cast-welded rail joint - caulked joint - caulking joint - cemented joint - centre joint - chamfered joint - chamfered-edge lap joint - circular joint - clamping plate joint - clamping ring joint - clasp joint - cleat joint - clip joint - closed-tee joint - cluster joint - coach joint - cogged joint - collar joint - compensation joint - composite joint - compound for joint sealing - compression joint - concave joint - concealed joint - concrete mix joint - conduit joint - constricted-end joint - construction joint - contact joint - contraction joint - control joint - convex joint - coped joint - corner joint - cornerlock joint - cotter pin joint - coursing joint - couvre joint - cross joint - cross-halved joint - cruciform joint - curb joint - cut joint - dado joint - dead joint - demountable joint - detachable joint - dilatation joint - direct-edge splined joint - disk joint - divided tenon joint - double joint - double-bevel butt joint - double-butt joint - double-lap riveted joint - double-shear joint - dovetail joint - dovetail halving joint - dovetail scarf joint - dowelled joint - draw-band joint - dry joint - dummy joint - eccentric joint - edge joint - edge butt joint - elastic joint - elbow joint - end joint - erection joint - expanded joint - expansion joint - exposed joint - eye joint - face joint - faced joint - false joint - faucet joint - faulty joint - field joint - fillet joint - fillistered joint - finger joint - firm-and-impervious joint - fish-mouth joint - fixed joint - flange joint - flange-to-web joint - flashed joint - flat joint - flexible joint - flush joint - flush-cut joint - flush cylindrical joint - flush taper joint - folded-over joint - forge-welded joint - fork joint - friction joint - full open-corner joint - full-strength joint - gasketless joint - gastight joint - gas-welded joint - girth joint - glue joint - groove joint - grooved and tongued joint - ground joint - grouted joint - half joint - half-lap joint - half-mitre joint - halved joint - header joint - heading joint of flooring boards - hem joint - hinge joint - hinged joint - hollow joint - hook joint - housed joint - impervious joint - inclined joint - inclined tee joint - indented joint - involute splined joint - J-groove joint - joggle joint - joint double-strap lap joint - keyed joint - king-post joint - lap joint - lapped corner joint - lead joint - leakage of joint - leaky joint - ledge joint - lift joint - linear slotted lap joint - lipped joint - lock joint - longitudinal joint - loop joint - loose joint - loose tongue joint - married joints - match joint - milter joint - mortar mix joint - mortise joint - mortise and tenon joint - mortise dowel joint - movable joint - movement of joint - multiple joint - multiple bar joint - nipple joint - oblique joint - open joint - open-butt joint - open-drained joint - opening of joint - open mortise and tenon joint - open tee joint - overlap joint - packed joint - permeable joints - pillow joint - pilot joint - pin joint - pin-connected joint - pipe joint - plain lap joint - poured joint - pressure-welded joint - profiled joint - push joint - racked joint - related joint - rigid joint - ring joint - rivet joint - riveted lap joint with butt strap - rocker joint - rope joint - rotating joint - rubbed joint - rust joint - saddle joint - scarf joint - screw joint - sealing of joints - seamless joint - secret joint - semiflexible joint - shilap joint - shove joint - skew joint - skew scarf joint - sliding joint - slip joint - socket-and-spigot joint - soldered joint - spherical joint - splined joint - split joint - square joint - S-slip joint - step joint - strapped joint - strength joint - strike joint - structural joints - swivel joint - swivel rod joint - tale-to-tale joint - taper joint - tapered-end joint - telescope joint - tenon joint - tension joint - thermit joint - threaded gas pipe joint - tianged-edge joint - tight joint - toe joint - tongue-and-groove joint - tooth cogging joint - transverse joint - treated joint - U-groove joint - unchamfered joint - universal joint - voussoir joint - V-shaped joint - wall-footing joint - water-sealed joint - watertight joint - weathered joint - wedge joint - welded joint - welding joint - woodworking jointto joint with skew, scarf and key — соединять зигзагом
* * *1. соединение, шов; узел, стык2. разрыв, трещина ( горных пород)joint between precast members — соединение элементов сборных (железо)бетонныхжелезобетонных¦бетонных конструкций
joint fixed [locked] against rotation — узел, закреплённый против поворота; узел с наложенными связями против поворота
joint restrained by elastic members — упруго-податливое соединение, упруго-податливый узел
joint transmitting compression — соединение, передающее усилие сжатия
- abutting jointjoint transmitting shears — соединение, обеспечивающее передачу поперечных сил [сдвигающих усилий]
- adhesive-bonded joint
- adhesive joint
- angle joint
- angle half-lap joint
- articulated joint
- aseismic joint
- ball joint
- beam butt joint
- beam-column joint
- bed joint
- bell-and-spigot joint
- birdsmouth joint
- bolted joint
- box dovetail joint
- breaking joints
- break joints
- brick joints
- bridle joint
- butt joint
- buttered joint
- cable joint
- capillary joint
- caulked joint
- cleat joint
- closely-spaced joints
- coax scarf joint
- cog scarf joint
- cold joint
- combed joint
- compression joint
- concave joint
- construction joint
- contraction joint
- convex joint
- corner joint
- cornerlock joint
- coursing joint
- crimped joint
- crimp upstand joint
- cross joint
- cross-lap joint
- curb joint
- cut joint
- dilatation joint
- dismountable joint
- double-shear joint
- double-S slip joint
- dovetail halving joint
- doweled contraction joint
- draw band joint
- duct flange joint
- dummy joint
- edge joint
- end joint
- end lap joint
- erection joint
- expansion joint
- face joint
- fail-safe joint
- false joint
- feather joint
- field joint
- finger joint
- fixed joint
- flanged joint
- flared joint
- flat joint
- flexible joint
- flexible ball joint
- floor joint
- floor-to-wall joint
- flush joint
- friction-type joint
- gland joint
- glued joint
- groove joint
- ground joint
- grouted joint
- half-lap joint
- halved joint
- heading joint
- head joint
- head contact joint
- head free joint
- Hercules pile joint
- hick joint
- high joint due to frost action
- hinged joint
- hinge joint
- incompressible joint
- insulated flanged pipe joint
- insulated rail joint
- isolation joint
- joggle joint
- keyed joint
- keys scarf joint
- knuckle joint
- laminated joint
- lapped joint
- lap joint
- lead joint
- lengthening joint
- lift joint
- lock joint
- longitudinal joint
- loose flange joint
- manipulative joint
- miter joint
- mortise-and-tenon joint
- mortise joint
- movement joint
- nonmanipulative joint
- oblique joint
- oblique butt joint
- open joint
- overstrained joint
- packed joint
- pin joint
- pipe expansion joint
- plain-S slip joint
- ploughed-and-tongued joint
- pocket lock joint
- pointed joint
- pressure-tight joint
- push fit joint
- rail joint
- raked joint
- rebated joint
- reinforced bar slip joint
- reinforced standing seam joint
- released joint
- resilient joint
- rigid joint
- ring seal joint
- rough-cut joint
- rustication joint
- rustic joint
- saddle joint
- sawed joint
- scarf joint
- screwed joint
- screw joint
- sealed joint
- semiflexible joint
- settlement joint
- shear joint
- shoved joint
- shrinkage joint
- shrinkage compensating concrete floor joint
- shrunk rubber ring joint
- single dovetail joint
- sleeve joint
- sliding joint
- slip joint
- solvent welded joint
- socket joint
- socket-and-spigot joint
- spalled joint
- spigot-and-socket joint
- S slip joint
- stagger joints
- steel crossing construction joint
- struck joint
- T and G joint
- tank base joint
- telescope joint
- threaded joint
- tight joint
- toggle joint
- tongue and groove joint
- tool joint
- tooled joint
- transverse joint
- treated joint
- undoweled joint
- unsealed joint
- V-shaped joint
- wall-footing joint
- warping joint
- watertight joint
- weathered joint
- welded joint
- wiped joint -
10 Breuer, Marcel Lajos
[br]b. 22 May 1902 Pécs, Hungaryd. 1 July 1981 New York (?), USA[br]Hungarian member of the European Bauhaus generation in the 1920s, who went on to become a leader in the modern school of architectural and furniture design in Europe and the United States.[br]Breuer began his student days following an art course in Vienna, but joined the Bauhaus at Weimar, where he later graduated, in 1920. When Gropius re-established the school in purpose-built structures at Dessau, Breuer became a member of the teaching staff in charge of the carpentry and furniture workshops. Much of his time there was spent in design and research into new materials being applied to furniture and interior decoration. The essence of his contribution was to relate the design of furniture to industrial production; in this field he developed the tubular-steel structure, especially in chair design, and experimented with aluminium as a furniture material as well as pieces of furniture made up from modular units. His furniture style was characterized by an elegance of line and a careful avoidance of superfluous detail. By 1926 he had furnished the Bauhaus with such furniture in chromium-plated steel, and two years later had developed a cantilevered chair.Breuer left the Bauhaus in 1928 and set up an architectural practice in Berlin. In the early 1930s he also spent some time in Switzerland. Notable from these years was his Harnischmacher Haus in Wiesbaden and his apartment buildings in the Dolderthal area of Zurich. His architectural work was at first influenced by constructivism, and then by that of Le Corbusier (see Charles-Edouard Jeanneret). In 1935 he moved to England, where in partnership with F.R.S. Yorke he built some houses and continued to practise furniture design. The Isokon Furniture Co. commissioned him to develop ideas that took advantage of the new bending and moulding processes in laminated wood, one result being his much-copied reclining chair.In 1937, like so many of the European architectural refugees from Nazism, he found himself under-occupied due to the reluctance of English clients to embrace the modern architectural movement. He went to the United States at Gropius's invitation to join him as a professor at Harvard. Breuer and Gropius were influential in training a new generation of American architects, and in particular they built a number of houses. This partnership ended in 1941 and Breuer set up practice in New York. His style of work from this time on was still modern, but became more varied. In housing, he adapted his style to American needs and used local materials in a functional manner. In the Whitney Museum (1966) he worked in a sculptural, granite-clad style. Often he utilized a bold reinforced-concrete form, as in his collaboration with Pier Luigi Nervi and Bernard Zehrfuss in the Paris UNESCO Building (1953–8) and the US Embassy in the Hague (1954–8). He displayed his masterly handling of poured concrete used in a strikingly expressionistic, sculptural manner in his St John's Abbey (1953–61) in Collegeville, Minnesota, and in 1973 his Church of St Francis de Sale in Michigan won him the top award of the American Institute of Architects.[br]Principal Honours and DistinctionsAmerican Institute of Architects Medal of Honour 1964, Gold Medal 1968. Jefferson Foundation Medal 1968.Bibliography1955, Sun and Shadow, the Philosophy of an Architect, New York: Dodd Read (autobiography).Further ReadingC.Jones (ed.), 1963, Marcel Breuer: Buildings and Projects 1921–1961, New York: Praeger.T.Papachristou (ed.), 1970, Marcel Breuer: New Buildings and Projects 1960–1970, New York: Praeger.DY -
11 Rondelet, Jean-Baptiste
[br]b. 1734 Lyons, France d. 1829[br]French architect particularly interested in the scientific and mathematical basis of architectural structure, and who at an early date introduced reinforced concrete into supporting piers in his buildings.[br]From 1795 Rondelet was Professor at the Ecole Centrale des Travaux Publics and while there was responsible for a major treatise on building construction: this was his Traité théorique et pratique de l'art de bâtir, published in four volumes in 1802–17. From 1806 he taught at the Ecole Spéciale d'Architecture, which was soon afterwards merged with the Ecole Polytechnique. It was when Rondelet took over the work of com-pleting the Panthéon in Paris, after the death of Jacques-Germain Soufflot, that he had the opportunity of putting some of his particular structural ideas into practice. In 1755 the King had appointed Soufflot architect of the great new church to be dedicated to the patron saint of the city, Sainte Geneviève. In this neo-classical structure based upon Greek cross plan, Soufflot intended four slender piers, each encased in three engaged columns, to support the pendentives for the dome to rise over the crossing. It was a fine and elegant building on a large scale, but by the early nineteenth century, when the church had become a pantheon, cracks were appearing in the masonry. When Rondelet succeeded as architect after Soufflot's death, he strengthened and enlarged the piers, employing a faced concrete structure reinforced with metal. He used a metalreinforced mortar with rubble aggregate.[br]BibliographyAn article by Rondelet appears in: 1989, Le Panthéon: Symbole des Révolutions, pp. 308–10 (book of the Exhibition at the Hôtel de Sully, Paris), ed. Picard, Caisse Nationale des Monuments Historiques et des Sites en France.Further ReadingM.N.Mathuset-Bandouin, 1980, "Biographie de Jean Rondelet", Soufflot et son temps, Caisse Nationale des Monuments Historiques et des Sites en France, 155ö7.DYBiographical history of technology > Rondelet, Jean-Baptiste
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12 equipment
оборудование; снаряжение; оснащениеequipment for the manufacture of asbestos cement — оборудование для производства асбестоцементных изделий
equipment for the manufacture of ceramic products — оборудование для производства керамических материалов
- air equipment - air-conditioning equipment - air-humidifying equipment - air-painting equipment - automatic sampling equipment - cargo handling equipment - carrying and lifting equipment - construction equipment - crane equipment - crushing equipment - crushing and concentration equipment - crushing and screening equipment - decontaminating equipment - defective equipment - detritus equipment - direct-chlorine-feed equipment - durable equipment - earthmoving equipment - efficient earthmoving equipment - emergency equipment - erection equipment - exhibition equipment - fire-fighting equipment - fixed equipment - garage-repair equipment - gathering frames equipment - grit-dredging equipment - groundwater level-lowering equipment - handling equipment - hauling equipment - high-fi equipment - hi-fi equipment - homemade fire-fighting equipment - idle equipment - industrial cleaning equipment - installed equipment - kiln car conveying equipment - laboratory equipment - lime-handling equipment - loading and unloading equipment for dryer cars - manufacturing equipment - material mining equipment - measuring and control equipment - mountable pile-driving equipment - non-assembled equipment - nonstandard equipment - operational equipment - outdated equipment - pile-driving equipment - piling equipment - professional drilling equipment - quarry equipment - repair equipment - residential equipment - ripper's equipment - road-building equipment - rope-suspended boom equipment - safety equipment - sampling equipment - snow-cleaning equipment - standby equipment - stressing equipment - supplementary equipment - telescopic equipment - testing equipment - underwater construction equipment - universal equipment - up-to-date construction equipment - used equipment - vandalproof equipment - vehicle greasing equipment - water-purification equipment - water quality monitoring equipment - water-treatment equipment - weighing equipment - weld deposition equipment - welding deposition equipment - welding equipmentequipment for the manufacture of prefabricated reinforced concrete — оборудование для производства сборного железобетона
* * *оборудование- air equipmentequipment found to be damaged — оборудование с обнаруженными неисправностями ( после контрольного осмотра)
- air handling equipment
- application equipment
- automatic points equipment
- automatic spray equipment
- auxiliary building equipment
- carrying and lifting equipment
- compaction equipment
- compressed-air equipment
- concrete equipment
- concrete placing equipment
- construction equipment
- dust separation equipment
- earthmoving equipment
- EDM equipment
- electrical equipment of buildings
- electronic distance measuring equipment
- erecting equipment
- excavating equipment
- factory equipment
- fire control portable equipment
- fire-extinguishing equipment
- fire-protection equipment
- flame-cleaning equipment
- front-end equipment
- grouting equipment
- high-performance equipment
- high-pressure equipment
- hoisting equipment
- hydraulic equipment
- jacking equipment
- jacking equipment for lift slab
- joint sealing equipment
- laboratory equipment
- lifting equipment
- load-and-carry equipment
- load cell weighing equipment
- loading equipment
- materials-handling equipment
- measuring equipment
- mechanical handling equipment
- mobile equipment
- monitoring equipment
- motor-driven equipment
- office equipment
- own equipment
- oxygen flame-grooving equipment
- personal protective equipment
- pile driving equipment
- piling equipment
- play equipment
- pneumatic equipment
- portable equipment
- protective face equipment
- protective head equipment
- refrigeration equipment
- reverse circulating drilling equipment
- road repair equipment
- safety equipment
- scarifying equipment
- self-contained equipment
- service equipment
- shotcrete equipment
- signaling equipment
- site equipment
- snow clearing equipment
- specialized equipment
- spray equipment
- stationary equipment
- stressing equipment
- technical equipment
- tensioning equipment
- testing equipment
- track equipment
- vacuum lifting equipment
- vandal-proof equipment
- vehicle-mounted equipment
- water-borne equipment
- weight-moving equipment
- welding equipment -
13 Gropius, Walter Adolf
SUBJECT AREA: Architecture and building[br]b. 18 May 1883 Berlin, Germanyd. 5 July 1969 Boston, USA[br]German co-founder of the modern movement of architecture.[br]A year after he began practice as an architect, Gropius was responsible for the pace-setting Fagus shoe-last factory at Alfeld-an-der-Leine in Germany, one of the few of his buildings to survive the Second World War. Today the building does not appear unusual, but in 1911 it was a revolutionary prototype, heralding the glass curtain walled method of non-load-bearing cladding that later became ubiquitous. Made from glass, steel and reinforced concrete, this factory initiated a new concept, that of the International school of modern architecture.In 1919 Gropius was appointed to head the new School of Art and Design at Weimar, the Staatliches Bauhaus. The school had been formed by an amalgamation of the Grand Ducal schools of fine and applied arts founded in 1906. Here Gropius put into practice his strongly held views and he was so successful that this small college, which trained only a few hundred students in the limited years of its existence, became world famous, attracting artists, architects and students of quality from all over Europe.Gropius's idea was to set up an institution where students of all the arts and crafts could work together and learn from one another. He abhorred the artificial barriers that had come to exist between artists and craftsmen and saw them all as interdependent. He felt that manual dexterity was as essential as creative design. Every Bauhaus student, whatever the individual's field of work or talent, took the same original workshop training. When qualified they were able to understand and supervise all the aesthetic and constructional processes that made up the scope of their work.In 1924, because of political changes, the Weimar Bauhaus was closed, but Gropius was invited to go to Dessau to re-establish it in a new purpose-built school which he designed. This group of buildings became a prototype that designers of the new architectural form emulated. Gropius left the Bauhaus in 1928, only a few years before it was finally closed due to the growth of National Socialism. He moved to England in 1934, but because of a lack of architectural opportunities and encouragement he continued on his way to the USA, where he headed the Department of Architecture at Harvard University's Graduate School of Design from 1937 to 1952. After his retirement from there Gropius formed the Architect's Collaborative and, working with other architects such as Marcel Breuer and Pietro Belluschi, designed a number of buildings (for example, the US Embassy in Athens (1960) and the Pan Am Building in New York (1963)).[br]Bibliography1984, Scope of Total Architecture, Allen \& Unwin.Further ReadingN.Pevsner, 1936, Pioneers of the Modern Movement: From William Morris to Walter Gropius, Penguin.C.Jenck, 1973, Modern Movements in Architecture, Penguin.H.Probst and C.Shädlich, 1988, Walter Gropius, Berlin: Ernst \& Son.DY -
14 building
2) строительство, сооружение3) сборка; монтаж•-
abutting buildings
-
apartment building
-
bearing-wall building
-
blast-resistant building
-
car-dumper building
-
chain building
-
civic building
-
concrete-steel building
-
containment building
-
core building
-
crusher building
-
custom car building
-
defrosting building
-
detached building
-
double-core skeleton-type building
-
drum building
-
earthquake-proof building
-
electrode building
-
factory building
-
farm building
-
feed processing building
-
frame building
-
framed building
-
goaf pack building
-
high-rise building
-
industrial building
-
industrialized building
-
ladle cleaning-and-lining building
-
large-panel building
-
line building
-
link building
-
low leakage containment building
-
machine building
-
machine tool building
-
main building
-
mated tire building
-
multistorey building
-
office building
-
one-storey building
-
ply tire building
-
prefabricated building
-
public building
-
reactor auxiliary building
-
reactor building
-
reinforced-concrete building
-
residential building
-
ribbon building
-
sectional building
-
service and office building
-
shaft building
-
shear wall building
-
shear wall-frame building
-
shoulder drum building
-
single-aisle building
-
single-core skeleton-type building
-
single-storey building
-
skeleton-type building
-
sporadic building
-
steam-generating building
-
stock building
-
storage building
-
terminal building
-
tower building
-
transfer building
-
turbine building
-
two-aisle building
-
vacuum building
-
walk-up building
-
water-conditioning building -
15 joint
- joint
- n1. соединение, шов; узел, стык
2. разрыв, трещина ( горных пород)
joint between precast members — соединение элементов сборных (железо)бетонныхжелезобетонных¦бетонных конструкций
joint fixed [locked] against rotation — узел, закреплённый против поворота; узел с наложенными связями против поворота
joint restrained by elastic members — упруго-податливое соединение, упруго-податливый узел
joint transmitting compression — соединение, передающее усилие сжатия
joint transmitting shears — соединение, обеспечивающее передачу поперечных сил [сдвигающих усилий]
- abutting joint
- adhesive-bonded joint
- adhesive joint
- angle joint
- angle half-lap joint
- articulated joint
- aseismic joint
- ball joint
- beam butt joint
- beam-column joint
- bed joint
- bell-and-spigot joint
- birdsmouth joint
- bolted joint
- box dovetail joint
- breaking joints
- break joints
- brick joints
- bridle joint
- butt joint
- buttered joint
- cable joint
- capillary joint
- caulked joint
- cleat joint
- closely-spaced joints
- coax scarf joint
- cog scarf joint
- cold joint
- combed joint
- compression joint
- concave joint
- construction joint
- contraction joint
- convex joint
- corner joint
- cornerlock joint
- coursing joint
- crimped joint
- crimp upstand joint
- cross joint
- cross-lap joint
- curb joint
- cut joint
- dilatation joint
- dismountable joint
- double-shear joint
- double-S slip joint
- dovetail halving joint
- doweled contraction joint
- draw band joint
- duct flange joint
- dummy joint
- edge joint
- end joint
- end lap joint
- erection joint
- expansion joint
- face joint
- fail-safe joint
- false joint
- feather joint
- field joint
- finger joint
- fixed joint
- flanged joint
- flared joint
- flat joint
- flexible joint
- flexible ball joint
- floor joint
- floor-to-wall joint
- flush joint
- friction-type joint
- gland joint
- glued joint
- groove joint
- ground joint
- grouted joint
- half-lap joint
- halved joint
- heading joint
- head joint
- head contact joint
- head free joint
- Hercules pile joint
- hick joint
- high joint due to frost action
- hinged joint
- hinge joint
- incompressible joint
- insulated flanged pipe joint
- insulated rail joint
- isolation joint
- joggle joint
- keyed joint
- keys scarf joint
- knuckle joint
- laminated joint
- lapped joint
- lap joint
- lead joint
- lengthening joint
- lift joint
- lock joint
- longitudinal joint
- loose flange joint
- manipulative joint
- miter joint
- mortise-and-tenon joint
- mortise joint
- movement joint
- nonmanipulative joint
- oblique joint
- oblique butt joint
- open joint
- overstrained joint
- packed joint
- pin joint
- pipe expansion joint
- plain-S slip joint
- ploughed-and-tongued joint
- pocket lock joint
- pointed joint
- pressure-tight joint
- push fit joint
- rail joint
- raked joint
- rebated joint
- reinforced bar slip joint
- reinforced standing seam joint
- released joint
- resilient joint
- rigid joint
- ring seal joint
- rough-cut joint
- rustication joint
- rustic joint
- saddle joint
- sawed joint
- scarf joint
- screwed joint
- screw joint
- sealed joint
- semiflexible joint
- settlement joint
- shear joint
- shoved joint
- shrinkage joint
- shrinkage compensating concrete floor joint
- shrunk rubber ring joint
- single dovetail joint
- sleeve joint
- sliding joint
- slip joint
- solvent welded joint
- socket joint
- socket-and-spigot joint
- spalled joint
- spigot-and-socket joint
- S slip joint
- stagger joints
- steel crossing construction joint
- struck joint
- T and G joint
- tank base joint
- telescope joint
- threaded joint
- tight joint
- toggle joint
- tongue and groove joint
- tool joint
- tooled joint
- transverse joint
- treated joint
- undoweled joint
- unsealed joint
- V-shaped joint
- wall-footing joint
- warping joint
- watertight joint
- weathered joint
- welded joint
- wiped joint
Англо-русский строительный словарь. — М.: Русский Язык. С.Н.Корчемкина, С.К.Кашкина, С.В.Курбатова. 1995.
См. также в других словарях:
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