Respuesta :
Answer:
part a : The dry unit weight is 0.0616 [tex]lb/in^3[/tex]
part b : The void ratio is 0.77
part c : Degree of Saturation is 0.43
part d : Additional water (in lb) needed to achieve 100% saturation in the soil sample is 0.72 lb
Explanation:
Part a
Dry Unit Weight
The dry unit weight is given as
[tex]\gamma_{d}=\frac{\gamma}{1+\frac{w}{100}}[/tex]
Here
- [tex]\gamma_d[/tex] is the dry unit weight which is to be calculated
- γ is the bulk unit weight given as
[tex]\gamma =weight/Volume \\\gamma= 4 lb / \pi r^2 h\\\gamma= 4 lb / \pi (4/2)^2 \times 4.58\\\gamma= 4 lb / 57.55\\\gamma= 0.069 lb/in^3[/tex]
- w is the moisture content in percentage, given as 12%
Substituting values
[tex]\gamma_{d}=\frac{\gamma}{1+\frac{w}{100}}\\\gamma_{d}=\frac{0.069}{1+\frac{12}{100}} \\\gamma_{d}=\frac{0.069}{1.12}\\\gamma_{d}=0.0616 lb/in^3[/tex]
The dry unit weight is 0.0616 [tex]lb/in^3[/tex]
Part b
Void Ratio
The void ratio is given as
[tex]e=\frac{G_s \gamma_w}{\gamma_d} -1[/tex]
Here
- e is the void ratio which is to be calculated
- [tex]\gamma_d[/tex] is the dry unit weight which is calculated in part a
- [tex]\gamma_w[/tex] is the water unit weight which is 62.4 [tex]lb/ft^3[/tex] or 0.04 [tex]lb/in^3[/tex]
- G is the specific gravity which is given as 2.72
Substituting values
[tex]e=\frac{G_s \gamma_w}{\gamma_d} -1\\e=\frac{2.72 \times 0.04}{0.0616} -1\\e=1.766 -1\\e=0.766[/tex]
The void ratio is 0.77
Part c
Degree of Saturation
Degree of Saturation is given as
[tex]S=\frac{G w}{e}[/tex]
Here
- e is the void ratio which is calculated in part b
- G is the specific gravity which is given as 2.72
- w is the moisture content in percentage, given as 12% or 0.12 in fraction
Substituting values
[tex]S=\frac{G w}{e}\\S=\frac{2.72 \times .12}{0.766}\\S=0.4261[/tex]
Degree of Saturation is 0.43
Part d
Additional Water needed
For this firstly the zero air unit weight with 100% Saturation is calculated and the value is further manipulated accordingly. Zero air unit weight is given as
[tex]\gamma_{zav}=\frac{\gamma_w}{w+\frac{1}{G}}[/tex]
Here
- [tex]\gamma_{zav}[/tex] is the zero air unit weight which is to be calculated
- [tex]\gamma_w[/tex] is the water unit weight which is 62.4 [tex]lb/ft^3[/tex] or 0.04 [tex]lb/in^3[/tex]
- G is the specific gravity which is given as 2.72
- w is the moisture content in percentage, given as 12% or 0.12 in fraction
[tex]\gamma_{zav}=\frac{\gamma_w}{w+\frac{1}{G}}\\\gamma_{zav}=\frac{0.04}{0.12+\frac{1}{2.72}}\\\gamma_{zav}=\frac{0.04}{0.4876}\\\gamma_{zav}=0.08202 lb/in^3\\[/tex]
Now as the volume is known, the the overall weight is given as
[tex]weight=\gamma_{zav} \times V\\weight=0.08202 \times 57.55\\weight=4.72 lb[/tex]
As weight of initial bulk is already given as 4 lb so additional water required is 0.72 lb.
