Safety Factor Of Structure Research Articles

Comparative study procedure for the safety evaluation of high arch dams

A set of factors for the safety evaluation of the dam heel crack and ultimate bearing capacity of high arch dams is presented: the curtain safety factor k 1, the structural mutation safety factor k 2, and the ultimate safety factor k 3. The factor k 1 reflects the curtain safety at the dam heel, k 2 describes the structural mutation stage for the adjustment of the multiple arch–cantilever system, and k 3 reflects the ultimate bearing capacity of the entire dam structure. A comparative study on the performance and ultimate bearing capacity of dams is performed to give a more reasonable evaluation criterion of safety factors.

원전 엘보우의 성능기반 안전여유도 분석

The piping systems in nuclear power plant are composed of various typed pipes such as straight, elbow pipe, branch and reducer etc. The elbow is connected from straight pipe to another pipes in order to establish the complicated piping system. Elbow is one of very important components considering management of wall thinning degradation. It is however applied by various loads such as system pressure, earthquake, postulated break loading and many transient loads, which provoke simply the internal pressure, bending and torsional stress. In this study, firstly pipes in the secondary system of the nuclear power plant are classified as pipe size and type for selecting the investigating range. Next, a large number of finite element analysis considering the all typed dimensions of commercial pipe has been performed to find out the behavior of TES(twice elastic slop) plastic load of elbows, which is based on evaluation of the structural safety factor. Finally performance based structural safety factor was investigated comparing with maximum allowable load by construction code.

Weshalb ist die Lunge trocken?

The extremely thin blood-gas barrier, the high blood perfusion rate and the deformability of the lung required for ventilation call for safety measures in order to keep the peripheral airspaces dry. The protective factors are provided in part by the particular structural organization of the lung, in part by physiological safeguards. Amongst the structural safety factors the extremely low permeability of the alveolar epithelial cell layer, the effective drainage system of interstitial spaces, and the loose connective tissue layers which surround vessels and bronchi, and which can act as transient fluid reservoirs, should be mentioned. The physiologic safety factors include the low hemodynamic pressures in the pulmonary vessels, the high colloid-osmotic pressure of blood, the decrease in perimicrovascular colloid-osmotic pressure on increased transcapillary fluid filtration, the interstitial pressure gradient between peripheral and central parts of the lung, and the minimal mechanical forces acting on the fine lung parenchyma owing to the low surface tensions provided by alveolar surfactant. Whether the active pumping mechanism improving reabsorption of edema fluid is also operative under normal conditions has not yet been clarified.

Mechanics based statistical prediction of structure size and geometry effects on safety factors for composites and other quasibrittle materials

The objective of this paper1 is a rational determination of safety factors of quasibrittle structures, taking into account their size and shape. To this end, it is necessary to establish the probability density distribution function (pdf) of the structural strength. For perfectly ductile and perfectly brittle materials, the proper pdf's of the nominal strength of structure are known to be Gaussian and Weibullian, respectively, and are invariable with structure size and geometry. However, for quasibrittle materials, many of which came recently to the forefront of attention, the pdf has recently been shown to depend on structure size and geometry, varying gradually from Gaussian pdf with a remote Weibull tail at small sizes to a fully Weibull pdf at large sizes. This recent result is reviewed, and then mathematically extended in two ways: 1) to a mathematical description of structural lifetime as a function of applied (time-invariable) nominal stress, and 2) to a mathematical description of the statistical parameters of the pdf of structural strength as a function of structure size and shape. Experimental verification and calibration is relegated to a subsequent journal article.

A Study on Structural Safety Evaluation of Jet Vane under Severe Thermal and Mechanical Loadings

When jet vane is exposed to exhaust gas and deflected at a typical angle, side force is produced and the missile is controlled. The vane is subjected to severe thermal and mechanical loadings by combustion gas. In this study, the high temperature tension tests of refractory metals, 3-D nonlinear numerical simulations and motor firing tests were performed to evaluate structural safety factor of the jet vane. The structural safety factor of jet vane was evaluated by comparing the numerical results with cold and hot structural tests of jet vane system. It has been found that a shaft supports most of thermal and mechanical loadings on the system and is structurally safe below 1400°C. From the comparison of firing tests and numerical results, the evaluation criterion of structural safety using the load and shaft deformation is more useful than using the equivalent stress.

Possibilistic approach for consideration of uncertainties to estimate structural capacity of ageing cast iron water mains

Drinking water distribution networks form essential components of all urban centres. Water mains buried in the soil-backfill are exposed to different deleterious reactions, with the result being that the design factor of safety may significantly degrade, leading to structural failure. In particular, metallic distribution and trunk mains are subject to corrosion. Proactive pipeline management, which entails timely maintenance, repair, and renovation, can increase the service life of pipes. Several nondestructive evaluation techniques have recently become available to measure the remaining wall thickness of metallic pipes. In this paper, a previously developed analytical model based on Winkler-type pipe–soil interaction (WPSI) is cast in a "possibilistic" framework to translate the remaining pipe wall thickness to current structural factor of safety. The WPSI model takes into consideration external (traffic, frost, etc.) and internal (operating and surge pressures) loads, temperature changes, and loss of bedding support and the reduction of pipe structural capacity in the presence of corrosion pits. Uncertainties associated with the input data–parameters are handled using fuzzy arithmetic operations and interpreted through possibility theory. A Monte Carlo type random sampling method is carried out for performing sensitivity analyses to identify the critical data-parameters that merit further investigation.Key words: water mains, pipe–soil interaction, uncertainty analysis, fuzzy arithmetic, possibility theory.

Optimum values of structural safety factors for a predefined reliability level with extension to multiple limit states

In the field of deterministic structural optimization, the designer reduces the structural cost without taking into account uncertainties concerning materials, geometry and loading. This way, the resulting optimum solution may represent a lower level of reliability and thus a higher risk of failure. It is the objective of reliability-based design optimization (RBDO) to design structures that should be both economic and reliable. The coupling between mechanical modeling, reliability analyses and optimization methods leads to very high computational costs and weak convergence stability. Since the traditional RBDO solution is achieved by alternating between reliability and optimization iterations, the structural designers performing deterministic optimization do not consider the RBDO model as a practical tool for the design of real structures. Fortunately, a hybrid method based on simultaneous solution of the reliability and the optimization problem, has successfully reduced the computational time problem. The hybrid method allows us to satisfy a required reliability level, but the vector of variables here contains both deterministic and random variables. The hybrid RBDO problem is thus more complex than that of deterministic design. The major difficulty lies in the evaluation of the structural reliability, which is carried out by a special optimization procedure. In this paper a new methodology is presented with the aim of finding a global solution to RBDO problems without additional computing cost for the reliability evaluation. The safety factor formulation for a single limit state case has been used to efficiently reduce the computational time . This technique is fundamentally based on a study of the sensitivity of the limit state function with respect to the design variables. In order to demonstrate analytically the efficiency of this methodology, the optimality condition is then used. The efficiency of this technique is also extended to multiple limit state cases. Two numerical examples are presented at the end of the paper to demonstrate the applicability of the new methodology.

Earthquake Risk Analysis On HistoricalBuildings In Istanbul

Historical structures in ~stanbul, should be valued and preserved, since they are the most important part of cultural heritage of mankind. The typical historical structures and Byzantine and Ottoman buildings are very rigid. Earthquakes pose an everlasting danger to these historical structures, for they have destroyed so many hstorical structures in the past. Therefore, these Byzantine and Ottoman structures must be intensively studied for load carrying vulnerability against earthquakes. The ratio of load effects on structure and the strength capacity can represent a quantitative safety factor of historical structures against earthquakes. Therefore, an analytical risk analysis of the structure is performed in this paper, for a systematical restoration in future. All these Byzantine and Ottoman Buildings are the summit of mankind. Therefore, the prevention systems for these monuments against the hazardous future earthquakes must be urgently designed.

Variation in safety factors of claws within and among six species of Cancer crabs (Decapoda: Brachyura)

To better understand how safety factors of biological structures evolve, we examined the frequency of claw failure, and the intra- and interspecific patterns of variation in maximum biting force and breaking strength in the claws of six species of Cancer (Linnaeus) crabs that live in sympatrv along the coast of the northeastern Pacific: C. antennarius, C. branneri, C. gracilis, C. maguter, C. oregonensis and C. productus. Although the breakage frequencies in natural populations were similar among species (6%), they were higher than predicted based on failure probabilities calculated from laboratory measurements of biting force and breaking strength for healthy pristine claws. The incidence of claw damage was correlated with the degree of wear, suggesting that claws later in the intermolt interval were more likely to fail. Within species, safety factors increased from 3.1 to 4.6 with increasing instar number due primarily to a decline in muscle stress (force per unit area of apodeme). Surprisingly, the lower maximum muscle stress generated by later instars appeared to be due to behavioral restraint, since it was not accompanied by relatively lower muscle mass. In addition, among individuals of the same claw size, lower breaking forces were correlated with lower maximum biting force, and both were correlated with lighter cuticle and closer muscle mass, suggesting a coupling that maintains a more stable safety factor over the moult cycle. In some species, size-adjusted maximum biting forces were higher for males than females, but this paralleled differences in breaking strength, so safety factors did not differ between the sexes. Among the six Cancer species, one exhibited an unusually high safety factor (C. oregonensis, 7.4) and another an unusually low one (C. maguter, 2.6). The remaining four species were similar to each other and exhibited an intermediate safety factor (3.6). From a phylogenetic perspective, the species with more extreme safety factors appeared to be derived from a common ancestor with an intermediate safety factor. From an ecological perspective, species more closely associated with rocky substrata, and presumably a higher incidence of hard-shelled prey, exhibited higher safety factors. But safety factors were also correlated with relative claw size, and sexual dimorphism in claw size. Although we cannot say whether habitat, diet or sexual selection are primarily responsible for the differences in safety factors observed among species, the cost of producing a relatively larger claw seems an unlikely explanation because safety-factors did not differ between males and females in any of the sexually dimorphic species.

Variation in safety factors of claws within and among six species of Cancer crabs (Decapoda: Brachyura)

To better understand how safety factors of biological structures evolve, we examined the frequency of claw failure, and the intra- and interspecific patterns of variation in maximum biting force and breaking strength in the claws of six species of Cancer (Linnaeus) crabs that live in sympatry along the coast of the northeastern Pacific C. antennarius, C. branneri, C. gracilis, C. magister, C. oregonensis and C. productus. Although the breakage frequencies in natural populations were similar among species (≈ 6%), they were higher than predicted based on failure probabilities calculated from laboratory measurements of biting force and breaking strength for healthy pristine claws. The incidence of claw damage was correlated with the degree of wear, suggesting that claws later in the intermolt interval were more likely to fail. Within species, safety factors increased from 3.1 to 4.6 with increasing instar number due primarily to a decline in muscle stress (force per unit area of apodeme). Surprisingly, the lower maximum muscle stress generated by later instars appeared to be due to behavioral restraint, since it was not accompanied by relatively lower muscle mass. In addition, among individuals of the same claw size, lower breaking forces were correlated with lower maximum biting force, and both were correlated with lighter cuticle and closer muscle mass, suggesting a coupling that maintains a more stable safety factor over the moult cycle. In some species, size-adjusted maximum biting forces were higher for males than females, but this paralleled differences in breaking strength, so safety factors did not differ between the sexes. Among the six Cancer species, one exhibited an unusually high safety factor (C. oregonensis, 7.4) and another an unusually low one (C. magister, 2.6). The remaining four species were similar to each other and exhibited an intermediate safety factor (3.6). From a phylogenetic perspective, the species with more extreme safety factors appeared to be derived from a common ancestor with an intermediate safety factor. From an ecological perspective, species more closely associated with rocky substrata, and presumably a higher incidence of hard-shelled prey, exhibited higher safety factors. But safety factors were also correlated with relative claw size, and sexual dimorphism in claw size. Although we cannot say whether habitat, diet or sexual selection are primarily responsible for the differences in safety factors observed among species, the cost of producing a relatively larger claw seems an unlikely explanation because safety factors did not differ between males and females in any of the sexually dimorphic species.

Structural response to thin steel shell structures due to aircraft impact

The article presented is devoted to the problems of resistance of unprotected structures of process equipment such as large storage tanks, and tall and slender pressure tanks under impact loads. The subject of the study is a qualified estimation of the survivability of such cylindrical shell structures when hit by a flying object. The results may be used for the estimation of the safety factor of these structures in early project and construction stages, and will be of value when deciding whether the resistance and hence the safety of the structure is sufficient for a given type of processed or stored agents (which are mostly toxic chemicals, flammable and explosive liquids and gases, liquefied gases) or whether it is necessary to design a more resistant and, of course, more expensive structure.

On the numerical assessment of the safety factor of elastic-plastic structures under variable loading

A finite element method for the shakedown analysis of two-dimensional structures under combined mechanical and thermal loading is presented. Linear elastic-perfectly plastic as well as linear elastic-limited kinematical hardening material behaviour is taken into account. The discretized shakedown problem is solved numerically with the reduced basis technique. A new method for the generation of reduced base vectors is presented. Numerical examples illustrate the proposed method.

Is No-Tension Design of Concrete or Rock Structures Always Safe?—Fracture Analysis

Plain concrete structures such as dams or retaining walls, as well as rock structures such as tunnels, caverns, excavations, and rock slopes, have commonly been designed by elastic-perfectly plastic analysis in which the tensile yield strength of the material is taken as zero. The paper analyzes the safety of this no­ tension design in the light of the finiteness of the tensile strength of concrete or the tensile strength of rock between the joints. Through examples, it is demonstrated that: (1) the calculated length of cracks or cracking zones can correspond to an unstable state; (2) the uncracked ligament of the cross section, available for resisting horizontal shear loads, can be predicted much too large, compared to the fracture mechanics pre­ diction; (3) the calculated load-deflection diagram can lie lower than that obtained by fracture mechanics; (4) the no-tension load capacity for a combination of crack face pressure and loads remote from the crack front, calculated by elastic analysis on the basis of allowable compressive stress, can be higher than that obtained by fracture mechanics; and (5) an increase in the tensile strength of the material can cause the load capacity of the structure to decrease. Due to the size effect, these facts are true not only for zero fracture toughness (no-toughness design) but also for finite fracture toughness provided that the structure size is large enough. Several previous studies on the safety of no-tension design, including the finite-element analysis of a gravity dam, are also reviewed. It is concluded that if the no-tension limit design is used, the safety factors of concrete or rock structures cannot be guaranteed to have the specified values. Fracture mechanics is required for that.

A proposal for safety factor estimation in seismic PSA of structure by stochastic FEM technique

Abstract The study of safety factor estimation in seismic probabilistic safety assessment has been a focus of researchers' interest for some time. Most of the papers dealt with the safety factor estimation by means of experimental knowledge or numerical analysis such as the Monte Carlo technique. This paper presents a new method to gain parts of structural response factors analytically by utilizing the statistical theory of extremes and the stochastic FEM technique. First, the stochastic FEM is adopted to obtain the statistical response values considering the uncertainty of structural material, through the spectral analysis due to an earthquake as a stationary random process. As second step, combining the results by statistical theory of extremes for a structure having deterministic material properties with the previous results by spectral analysis considering material uncertainty, with the aid of the total representation theorem against uncertainty modeling, statistics related to maximum values of response could be calculated under the consideration of structural material uncertainty. Those results are shown in good agreement with Monte Carlo simulation. Finally, using the obtained results, it is shown how to get the structural safety factors related to structural material uncertainty analytically.

Selection for Increased Safety Factors of Biological Structures as Environmental Unpredictability Increases

Theory predicts that selection should increase the ratio of the performance of a biological structure or system to the requirements placed upon it (that is, its safety factor) as conditions become increasingly unpredictable. Although conventional safety factors are rarely measurable, an alternative, truncation safety factor (the ratio of mean strength to maximum possible load), can be measured quantitatively for certain load-bearing structures. For intertidal limpet shells subject to prying forces, truncation safety factor was found to increase with increased variability in shell strength, thus providing direct support for the theory.

Collapse of SDOF System to Harmonic Excitation

The investigation of the dynamic collapse behavior of structures during strong wind disturbances provides a rational foundation for estimating the safety factor of structures. In order to discuss the essential features of dynamic collapse behavior, the analyric and numerical studies are carried out on the dynamic behavior of single‐degree‐of‐freedom (SDOF) inelastic systems, also taking into consideration the effect of gravity under harmonic perturbation conditions with a mean static force. This model disturbance, which may be applied to wind disturbances, will be briefly called the harmonic excitation. The dynamic collapse condition of a system with respect to a harmonic excitation can be given by considering the elastic steady‐state response of the system. If an allowable displacement of a system is specified, the harmonic excitation which induces the system to collapse can be found. Inversely, if a harmonic excitation is specified, the tolerable displacement of the system can also be found.

Fusion reactor first-wall cooling for very high energy fluxes

A study has been made of the feasibility of a protective first-wall shield between the plasma and the containment vessel for early experimental controlled thermonuclear fusion machines. The proposed first-wall shield is a water-cooled array of thin-walled tubes designed to take very high local energy fluxes originating from the neutral beam injectors. Detailed computer calculations reveal that heat flux capabilities of 3300 W/cm 2 are possible with first-wall shield sections made up of tubes 1 m long of Ta-10W alloy (with tubes of 10 mm i.d. and tube wall thickness of 0.5 mm) with a structural safety factor of about four. Required pumping powers on the order of 1 MW/m 2 of first-wall area exposed to these high energy fluxes are predicted for flow in the non-boiling regime. If operation in the subcooled nucleate boiling regime can be achieved without oscillations or instabilities, the required pumping power is shown to decrease by about an order of magnitude.

Safety factor of certain optimum structures made of an ideal elastoplastic material

Safety factor of certain optimum structures made of an ideal elastoplastic material

Unified principle for determining the safety factor of structures against sliding

Unified principle for determining the safety factor of structures against sliding

2093 鉄骨構造の火災に対する安全率(構造)

2093 鉄骨構造の火災に対する安全率(構造)