Specific weight

Not to be confused with specific gravity.

The specific weight (also known as the unit weight) is the weight per unit volume of a material. The symbol of specific weight is γ (the Greek letter Gamma).

A commonly used value is the specific weight of water on Earth at 5°C which is 9.807 kN/m3 or 62.43 lbf/ft3. [1]

The terms specific gravity, and less often specific weight, are also used for relative density.

General formula

\gamma = \rho \, g

where

\gamma is the specific weight of the material (weight per unit volume, typically N/m3 units)
\rho is the density of the material (mass per unit volume, typically kg/m3)
g is acceleration due to gravity (rate of change of velocity, given in m/s2, and on Earth usually given as 9.81 m/s2)

Changes of specific weight

Unlike density, specific weight is not absolute. It depends upon the value of the gravitational acceleration, which varies with location. A significant influence upon the value of specific gravity is the temperature of the material. Pressure may also affect values, depending upon the bulk modulus of the material, but generally, at moderate pressures, has a less significant effect than the other factors. [2]

Uses

Fluid mechanics

In fluid mechanics, specific weight represents the force exerted by gravity on a unit volume of a fluid. For this reason, units are expressed as force per unit volume (e.g., N/m3 or lb/ft3). Specific weight can be used as a characteristic property of a fluid. [2]

Soil mechanics

Specific weight is often used as a property of soil to solve earthwork problems.

In soil mechanics, specific weight may refer to:

\gamma = \frac{(1+w)G_s\gamma_w}{1+e}

where

\gamma is the moist unit weight of the material
\gamma_w is the unit weight of water
w is the moisture content of the material
Gs is the specific gravity of the solid
e is the void ratio

The formula for dry unit weight is:

\gamma_d = \frac{G_s\gamma_w}{1+e} = \frac{\gamma}{1+w}

where

\gamma is the moist unit weight of the material
\gamma_d is the dry unit weight of the material
\gamma_w is the unit weight of water
w is the moisture content of the material
Gs is the specific gravity of the solid
e is the void ratio

The formula for saturated unit weight is:

\gamma_s = \frac{(G_s+e)\gamma_w}{1+e}

where

\gamma_s is the saturated unit weight of the material
\gamma_w is the unit weight of water
w is the moisture content of the material
Gs is the specific gravity of the solid
e is the void ratio[3]

The formula for submerged unit weight is:

\gamma^{'} = \gamma_s - \gamma_w

where

\gamma^{'} is the submerged unit weight of the material
\gamma_s is the saturated unit weight of the material
\gamma_w is the unit weight of water

Mechanical engineering

Specific weight can be used in mechanical engineering to determine the weight of a structure designed to carry certain loads while remaining intact and remaining within limits regarding deformation.

Specific weight of water

Temperature(°C) Specific weight (kN/m3)
0 9.805
5 9.807
10 9.804
15 9.798
20 9.789
25 9.777
30 9.765
40 9.731
50 9.690
60 9.642
70 9.589
80 9.530
90 9.467
100 9.399
Specific weight of water at standard sea-level atmospheric pressure (Metric units) [2]
Temperature(°F) Specific weight (lb/ft3)
32 62.42
40 62.43
50 62.41
60 62.37
70 62.30
80 62.22
90 62.11
100 62.00
110 61.86
120 61.71
130 61.55
140 61.38
150 61.20
160 61.00
170 60.80
180 60.58
190 60.36
200 60.12
212 59.83
Specific weight of water at standard sea-level atmospheric pressure (English units) [2]

Specific weight of air

Temperature(°C) Specific weight (N/m3)
−40 14.86
−20 13.86
0 12.68
10 12.24
20 11.82
30 11.43
40 11.06
60 10.4
80 9.81
100 9.28
200 7.33
Specific weight of air at standard sea-level atmospheric pressure (Metric units) [2]
Temperature(°F) Specific Weight (lb/ft3)
−40
−20 0.0903
0 0.08637
10 0.08453
20 0.08277
30 0.08108
40 0.07945
50 0.0779
60 0.0764
70 0.07495
80 0.07357
90 0.07223
100 0.07094
120 0.06849
140 0.0662
160 0.06407
180 0.06206
200 0.06018
250 0.05594
Specific weight of air at standard sea-level atmospheric pressure (English units) [2]

See also

References

  1. National Council of Examiners for Engineering and Surveying (2005). Fundamentals of Engineering Supplied-Reference Handbook (7th ed.). Clemson: National Council of Examiners for Engineering and Surveying. ISBN 1-932613-00-5
  2. 1 2 3 4 5 6 Finnemore, J. E. (2002). Fluid Mechanics with Engineering Applications. New York: McGraw-Hill. ISBN 0-07-243202-0.
  3. Das, Braja M. (2007). Principles of Geotechnical Engineering. Canada: Chris Carson. ISBN 0-495-07316-4.
  4. The Transtec Group, Inc. (2012). Basic Definitions and Terminology of Soils. http://www.intelligentcompaction.com/downloads/IC_RelatedDocs/SoilCmpct_Basic%20definitions%20of%20Soils.pdf (Page viewed December 7, 2012

External links

This article is issued from Wikipedia - version of the Tuesday, February 02, 2016. The text is available under the Creative Commons Attribution/Share Alike but additional terms may apply for the media files.