"Stress analysis of the ceramic hip joint endoprosthesis with real shape deflections"@en . "Plze\u0148" . . . . "588381" . "1"^^ . . "Z\u00E1pado\u010Desk\u00E1 univerzita v Plzni" . . . "1"^^ . "2004-11-16+01:00"^^ . "Computational modelling, hip joint endoprosthesis, micro-unevenness modelling, stress and failure probability analyses, Weibull weakest link theory."@en . . "RIV/00216305:26210/04:PU45022!RIV11-MSM-26210___" . . . . . "Stress analysis of the ceramic hip joint endoprosthesis with real shape deflections"@en . . . . . "26210" . "1"^^ . . . "[FDC17D850CBF]" . "Biomechanics of Man 2004" . "Stress analysis of the ceramic hip joint endoprosthesis with real shape deflections" . . "Fuis, Vladim\u00EDr" . "\u0160umava Mountain - Hotel Horizont" . "Stress analysis of the ceramic hip joint endoprosthesis with real shape deflections" . . "The paper deals with the problems of ceramic head of hip joint endoprosthesis destructions, and with assessing the impact of shape deflections of conical surfaces on the probability of this failure. Concerned are shape deflections from the ideal conical surfaces of the stem and the head of the endoprosthesis, which - when the head is put on the stem and the endoprosthesis loaded - form a contact configuration. The shape deflections may be modelled at the macro-level - this concerns model shape inaccuracies such as deflection from the nominal degree of taper, ovality, and their combination, or, possibly, at the micro-level - when the stochastic distribution of unevenness on the contact areas is respected. The problem of stress in ceramic heads was solved using the algorithm of the finite element method for spatial contact tasks, and the Weibull probability model was used for solving the problem of head cohesion failure probability. In the paper are presented and analysed the results of solution of the"@en . "RIV/00216305:26210/04:PU45022" . . . . "N, P(GP101/04/P037), V, Z(AV0Z2076919), Z(MSM 262100001), Z(MSM 262100024)" . . "The paper deals with the problems of ceramic head of hip joint endoprosthesis destructions, and with assessing the impact of shape deflections of conical surfaces on the probability of this failure. Concerned are shape deflections from the ideal conical surfaces of the stem and the head of the endoprosthesis, which - when the head is put on the stem and the endoprosthesis loaded - form a contact configuration. The shape deflections may be modelled at the macro-level - this concerns model shape inaccuracies such as deflection from the nominal degree of taper, ovality, and their combination, or, possibly, at the micro-level - when the stochastic distribution of unevenness on the contact areas is respected. The problem of stress in ceramic heads was solved using the algorithm of the finite element method for spatial contact tasks, and the Weibull probability model was used for solving the problem of head cohesion failure probability. In the paper are presented and analysed the results of solution of the" . "80-7043-315-9" . .