intermediate liquid limit soil - ορισμός. Τι είναι το intermediate liquid limit soil
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Τι (ποιος) είναι intermediate liquid limit soil - ορισμός

GEOTECHNICAL CHARACTERISTICS OF A SOIL RELATED TO ITS WATER CONTENT
Plasticity index; Liquid limit; Plastic limit; Liquid Limit; Plastic limit (soils); Casagrande Device; Activity (soil mechanics); Plastic Limit; Shrinkage limit; Atterberg Limits
  • Casagrande cup in action

Soil Stradivarius         
STRADIVARIUS VIOLIN
Soil Strad; Soil stradivarius
The Soil Stradivarius (pronounced ) of 1714 is an antique violin made by Italian luthier Antonio Stradivari of Cremona (1644–1737). A product of Stradivari’s golden period, it is considered one of his finest.
liquid         
  • [[Surface wave]]s in water
  • A [[lava lamp]] contains two immiscible liquids (a molten wax and a watery solution) which add movement due to convection. In addition to the top surface, surfaces also form between the liquids, requiring a tension breaker to recombine the wax droplets at the bottom.
  • Cavitation in water from a boat propeller
  • Thermal image of a sink full of hot water with cold water being added, showing how the hot and the cold water flow into each other.
  • Lennard-Jones model fluid]].
  • deposition]] can occur.
  • Structure of a classical monatomic liquid. Atoms have many nearest neighbors in contact, yet no long-range order is present.
  • A simulation of [[viscosity]]. The fluid on the left has a lower viscosity and Newtonian behavior while the liquid on the right has higher viscosity and non-Newtonian behavior.
NEARLY INCOMPRESSIBLE FLUID THAT CONFORMS TO THE SHAPE OF ITS CONTAINER BUT RETAINS A NEARLY CONSTANT VOLUME INDEPENDENT OF PRESSURE
Liquid State; Liquid state; Liquid phase; Liquids; Liquid level
n.
1) (a) clear; cloudy liquid
2) (a) dishwashing liquid
liquid         
  • [[Surface wave]]s in water
  • A [[lava lamp]] contains two immiscible liquids (a molten wax and a watery solution) which add movement due to convection. In addition to the top surface, surfaces also form between the liquids, requiring a tension breaker to recombine the wax droplets at the bottom.
  • Cavitation in water from a boat propeller
  • Thermal image of a sink full of hot water with cold water being added, showing how the hot and the cold water flow into each other.
  • Lennard-Jones model fluid]].
  • deposition]] can occur.
  • Structure of a classical monatomic liquid. Atoms have many nearest neighbors in contact, yet no long-range order is present.
  • A simulation of [[viscosity]]. The fluid on the left has a lower viscosity and Newtonian behavior while the liquid on the right has higher viscosity and non-Newtonian behavior.
NEARLY INCOMPRESSIBLE FLUID THAT CONFORMS TO THE SHAPE OF ITS CONTAINER BUT RETAINS A NEARLY CONSTANT VOLUME INDEPENDENT OF PRESSURE
Liquid State; Liquid state; Liquid phase; Liquids; Liquid level
I. a.
1.
Fluid.
2.
Mellifluous, dulcet, soft, clear, flowing, melting.
II. n.
Fluid, liquor, liquid substance.

Βικιπαίδεια

Atterberg limits

The Atterberg limits are a basic measure of the critical water contents of a fine-grained soil: its shrinkage limit, plastic limit, and liquid limit.

Depending on its water content, soil may appear in one of four states: solid, semi-solid, plastic and liquid. In each state, the consistency and behavior of soil are different, and consequently so are its engineering properties. Thus, the boundary between each state can be defined based on a change in the soil's behavior. The Atterberg limits can be used to distinguish between silt and clay and to distinguish between different types of silts and clays. The water content at which soil changes from one state to the other is known as consistency limits, or Atterberg's limit.

These limits were created by Albert Atterberg, a Swedish chemist and agronomist, in 1911. They were later refined by Arthur Casagrande, an Austrian-born American geotechnical engineer and a close collaborator of Karl Terzaghi (both pioneers of soil mechanics).

Distinctions in soils are used in assessing soil which is to have a structure built on them. Soils when wet retain water, and some expand in volume (smectite clay). The amount of expansion is related to the ability of the soil to take in water and its structural make-up (the type of minerals present: clay, silt, or sand). These tests are mainly used on clayey or silty soils since these are the soils which expand and shrink when the moisture content varies. Clays and silts interact with water and thus change sizes and have varying shear strengths. Thus these tests are used widely in the preliminary stages of designing any structure to ensure that the soil will have the correct amount of shear strength and not too much change in volume as it expands and shrinks with different moisture contents.