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11	Osmanlı camilerinde kemer strüktür-bicim ilis̲kisi üzerine bir deneme, 1300-1730 / Batur, Afife, January 1974 (has links) Thesis (Ph. D.)--Istanbul Teknik Üniversitesi, 1973. / Text in Turkish; summary in French. Vita. Includes bibliographical references (p. 179-212) and index. Arches. Architecture, Islamic Mosques
12	BUCKLING BEHAVIOR OF SYMMETRIC ARCHES Qaqish, Samih Shaker, 1950- January 1977 (has links) No description available. Arches. Buckling (Mechanics)
13	Large deflection theory for arches Callan, Michael Dolan, 1940- January 1963 (has links) No description available. Arches. Deformations (Mechanics)
14	Plastic analysis of circular two-hinged steel arches Namdar, Khosrow, 1941- January 1966 (has links) No description available. Arches. Plastic analysis (Engineering)
15	Large deflections of beams and arches Newbill, Thomas Carroll 05 1900 (has links) No description available. Arches Girders Strains and stresses
16	Construction technique and strength of connected regolith bag structures Singh, Mandeep, January 2007 (has links) (PDF) Thesis (M.S.)--Auburn University, 2007. / Abstract. Vita. Includes bibliographic references (ℓ. 101-103) Lunar bases Arches Sandbags.
17	Lateral stability of bridge arches braced with transverse bars Östlund, Lars. January 1954 (has links) Avhandling--Tekniska högskolan, Stockholm. / Extra t.p., with thesis statement, inserted. Includes bibliographical references (p. [124]). Arches. Arch bridges.
18	Buried FPR-Concrete Arches Tomblin, Josh January 2006 (has links) (PDF) No description available. Arches. Fiber-reinforced plastics
19	Analysis of flexible hingeless arch by an influence line method. Lee, Richard Way Mah January 1958 (has links) An influence line method for the analysis of flexible hingeless arch by the deflection theory is presented in this thesis. To facilitate the work, tables of dimensionless magni fication factors are provided. Prom these tables, influence lines taking into account the flexibility of the arch may be readily drawn and used very much in the ordinary way. The flexibility of the arch was conveniently measured by a dimensionless ratio, [ equation omitted ], and called the stiffness factor of the arch. The tables are for parabolic hingeless arches having rise ratios of 1/8,1/6,1/4,1/3, with constant EI or a prescribed variable EI. Values are given for β = 3 and 5 with some for β = 7. Also the tables contain magnification factors for maximum moments at eleven points in the arch, when the arch is loaded with a uniform load. Although the given tables are good only for parabolic hingeless arches with constant EI or a prescribed variation in EI, the tables may be reasonably extended to other hingeless arches whose shapes are not too different from a parabola and to a wide variety of variation in moment of inertia, provided these variations are not unrealistic. The possibility of using superposition in the deflection theory is based on the fact that calculations showed the horizontal thrust acting on the arch was approximately the same either by the deflection theory or the elastic theory. Because of this, the horizontal thrust becomes independent of deflection and the differential equation for bending of an arch is linear. Thus superposition may be used. The differential equation was hot convenient for calculation. Instead, the solutions in the tables were calculated by a numerical procedure of successive approximations, using the conjugate beam concept. This procedure was conveniently programmed for an electronic computer, the ALWAC III E, at the University of British Columbia. In the first cycle of approximation, the programme assumed the horizontal and vertical deflections were zero. This represented the elastic theory analysis. In subsequent cycles, the deflected shape of the arch from previous analysis was assumed. Successive approximation as such led to a solution based on the deflection theory. Three numerical examples shown in this thesis indicated that the error introduced by the linearized deflection theory was small, and the influence line method may be used for analysis of flexible arches. / Applied Science, Faculty of / Civil Engineering, Department of / Graduate Arches Strains and stresses
20	Magnification factors for hingeless arches. Pelton, Thomas Edward January 1958 (has links) This thesis presents a simple method for the determination of bending moments in flexible symmetrical hingeless arches. The deflection theory bending moments are obtained by multiplying elastic theory bending moments by predetermined magnification factors. The problem was to provide magnification factors for all cases of loading on a wide range of flexible symmetrical hingeless arches. By studying the differential equation a modified method of superposition was developed. Therefore, it was only necessary to determine magnification factors for a concentrated load at a number of positions along the arch axis. A convenient set of coordinates for the magnification factor was determined by dimensional analysis. Finally, an electronic computer was used to calculate the required magnification factors by a numerical method. Tables of magnification factors are presented for symmetrical parabolic hingeless arches. Magnification factors are given for rise to span ratios of 1/8, 1/6, 1/4, and 1/3 ; for constant and variable moment of inertia; and for values of [formula omitted]from 0 to 7, where H = the total horizontal thrust, L = the span, EIa = the average flexural rigidity. / Applied Science, Faculty of / Civil Engineering, Department of / Graduate Arches Strains and stresses

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