Last edited by Shaktitilar
Wednesday, August 5, 2020 | History

2 edition of On the significance of Poisson"s ratio for floating ice found in the catalog.

On the significance of Poisson"s ratio for floating ice

Kolumban Hutter

On the significance of Poisson"s ratio for floating ice

by Kolumban Hutter

  • 385 Want to read
  • 16 Currently reading

Published by Eidgenössische Technische Hochschule in Zürich .
Written in English

    Subjects:
  • Sea ice

  • Edition Notes

    StatementKolumban Hutter.
    SeriesMitteilungen - Versuchsanstalt für Wasserbau, Hydrologie und Glaziologie -- Nr. 11
    Classifications
    LC ClassificationsGB2405 H83
    The Physical Object
    Paginationiii, 78 p. :
    Number of Pages78
    ID Numbers
    Open LibraryOL20098785M

    Nevel, D.E.: Creep theory for a floating ice sheet. Special Report 76–4. Cold Regions Research and Engineering Laboratory, Hanover, New Hampshire () 1– Bulk modulus, numerical constant that describes the elastic properties of a solid or fluid when it is under pressure on all surfaces. The applied pressure reduces the volume of a material, which returns to its original volume when the pressure is removed. Sometimes referred to as the incompressibility, the bulk modulus is a measure of the ability of a substance to withstand changes in volume.

    For polycrystalline ice, at a temperature of −10 • C Young's modulus of ice is reported in the range of ∼ GPa and Poisson's ratio is ∼ [Petrovic, ]. At a temperature.   Poisson's ratio definition: a measure of the elastic properties of a material expressed as the ratio of the | Meaning, pronunciation, translations and examples.

    now if you calculate the poisson's ratio: v= - Ex/Ez-> Ex = (35/11 -5)/5= -4/11 and Ez= ()/7= 4/7. v= 4/ 4/7 = 7/11 = > How I understood it: There is no volume change, so when you elongate one direction the other two will compensate this by compressing. And this poisson ratio of 1/2 is in the extreme case that one direction. The exponentiated numberofdrugs coefficient is the multiplicative term to use to calculate the estimated healthvalue when numberofdrugs increases by 1 unit. In the case of categorical (factor) variables, the exponentiated coefficient is the multiplicative term relative to the base (first factor) level for that variable (since R uses treatment contrasts by default).


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On the significance of Poisson"s ratio for floating ice by Kolumban Hutter Download PDF EPUB FB2

Floating sea ice plates and the significance of the dependence of the Poisson ratio on brine content By K. HUTTER Laboratory of Hydraulics, Hydrology, and Glaciology, Federal Institute of Technology, Zurich (Communicated by K.

Stewartson, ER.S. - Received 30 August ) This article investigates the influence of the temperature profile in ice. Floating sea ice plates and the significance of the dependence of the foundation to static line loads and with the propagation of plane waves in a system consisting of a liquid layer and floating ice plate.

it should thus be extremely difficult to experimentally detect the dependence of the Poisson ratio on brine content for sea ice. Poisson's ratio is a measure of the Poisson effect, that describes the expansion or contraction of a material in directions perpendicular to the direction of value of Poisson's ratio is the negative of the ratio of transverse strain to axial small values of these changes, is the amount of transversal expansion divided by the amount of axial compression.

Definition of Poisson's ratio Poisson's ratio is the ratio of transverse contraction strain to longitudinal extension strain in the direction of stretching force. Tensile deformation is considered positive and compressive deformation is considered negative. The definition of Poisson's ratio contains a minus sign so that normal materials have a positive ratio.

With Poisson's ratio for aluminum - the contraction can be calculated as. dr = - ( m) (5 m) / (10 m) = m = mm. Poisson's Ratios for Common Materials. For most common materials the Poisson's ratio is in the range 0 - Typical Poisson's Ratios for some common materials are indicated below.

In mechanics, Poisson’s ratio is the negative of the ratio of transverse strain to lateral or axial strain. It is named after Siméon Poisson and denoted by the Greek letter ‘nu’, It is the ratio of the amount of transversal expansion to the amount of axial compression for small values of these changes.

Poisson’s ratio is an important engineering property for aerospace materials because of the need for close tolerances in aircraft structures and engines.

For example, a material having a high Poisson’s ratio (i.e. v → 1) used in an engine turbine blade contracts laterally by an excessive amount when under load, resulting in a large loss. The lattice parameters near the melting point are a = nm and c = nm.

The c/a ratio () is very close to the ideal ratio () and is independent of temperature. The ice Ih unit cell is relatively open (packing factor less than ), and this accounts for ordinary ice being less dense than water.

Poisson’s ratio is simply a ratio of the strain in the direction of stretching, against the perpendicular strain. Strain is defined as the deformation caused by stress. The ratio is named after Simeon Poisson, a French engineer, physicist and mathematician, who defined the Poisson effect in his book Traité de Mécanique – The.

poissons ratio of water Posted Feb 3,AM PST Acoustics & Vibrations, Materials VersionVersion a 7 Replies Dinesh Rotake. If you set up the classic Young's modulus experiment, where you stretch a wire made of some material, the Poisson’s ratio is a measure of the extent to which the wire reacts by getting thinner.

It doesn't “want” to get thinner, because stretching. Simplest definition By How much times did something contracted in perpendicular (y) -direction when you pulled it in one(x) -direction.

Assumptions taken: 2D element. The French mathematician Siméon-Denis Poisson developed his function in to describe the number of times a gambler would win a rarely won game of chance in a large number of tries. Letting p represent the probability of a win on any given try, the mean, or average, number of wins (λ) in n tries will be given by λ = the Swiss mathematician Jakob Bernoulli’s binomial.

1. Introduction. With climate changes and global warming, floating ice covers in the polar region are thinning and are more prone to break up. The possibility is now increasing that new sea routes through the Arctic Ocean would appear in the coming decades [1,2], adjacent to or through the extremely dynamic transitional zone with broken ice covers i.e.

the Marginal Ice Zone (MIZ) which is the. Poisson's ratio is a material constant that relates stress in one direction to elastic strain in another. Stress describes an external force applied to a material and strain measures the change in.

publication of Poisson’s Traité de Mécanique2 (Box 1), this is a good time to take stock of the utility of Poisson’s ratio.

Definition and physical significance Poisson3 defined the ratio ν between transverse strain (e t) and longitudinal strain (e l) in the elastic loading direction as ν = – e t /e l (Box 1). Float glass provides the material for all other forms of processed glass, such as laminated glass and toughened glass.

This article outlines its production and some of its applications. Young's modulus (E or Y) is a measure of a solid's stiffness or resistance to elastic deformation under load.

It relates stress (force per unit area) to strain (proportional deformation) along an axis or basic principle is that a material undergoes elastic deformation when it is compressed or extended, returning to its original shape when the load is removed.

It means that when a material is loaded within elastic limit than the ratio of lateral strain to the longitudinal strain gives us a constant called poisson’s ratio. It is denoted by the symbol μ. The value of poisson’s ratio varies from to For rubber its value varies from to Mathematically.

Plate anchor technology is an efficient solution for mooring offshore floating facilities for oil and gas or renewable energy projects. When used with a taut mooring, the anchor is typically subjec. Most books on regression analysis briefly discuss Poisson regression.

We are aware of only one book that is completely dedicated to the discussion of the topic. This is the book by Cameron and Trivedi ().

Most of the methods presented here were obtained from their book.Poisson's ratio is required in FEA. A great many materials have a Poisson's ratio of about+/- Common exceptions include rubbers, bio-tissues, ceramics, cast metals, and a few polymers.

Google will find it for almost any material. Stress and strain are not very sensitive to Poisson's ratio in the range of (around %. This article explores Poisson's ratio, starting with the controversy concerning its magnitude and uniqueness in the context of the molecular and continuum hypotheses competing in the development of elasticity theory in the nineteenth century, moving on to its place in the development of materials science and engineering in the twentieth century, and concluding with its recent re .