Agricultural Engineering Exam  >  Agricultural Engineering Notes  >  Strength of Material Notes - Agricultural Engg  >  Introduction to Profile & its types - Stability Analysis of Gravity Dams, Strength of Materials

Introduction to Profile & its types - Stability Analysis of Gravity Dams, Strength of Materials | Strength of Material Notes - Agricultural Engg - Agricultural Engineering PDF Download

 Elementary Profile

While determining the elementary profile of a gravity dam only pressure due to water is considered. Therefore the dam is subjected to horizontal water pressure at the upstream face and uplift pressure at the base. In such case a right angled triangular profile as shown in Figure 32.1, provides the maximum possible stabilizing force against overturning, without causing tension in the base. This profile is defined by two parameters viz, dam height (H) and base width (b). The procedure to determine the dam height and base width is given bellow.

Fig. 32.1.

32.1.1 Base width of elementary profile

First the required base width is determined based on two criteria; (i) no sliding  stress criteria and (ii) no tension criteria. The greater of the width given by the both criteria is taken as the width of the elementary profile.

(a) No sliding criteria

Horizontal force due to water pressure should be balanced by the frictional resistance. Therefore condition for no sliding is,

\[{F_H}=\mu \left( {W - U} \right)\]                              (32.1)

\[\Rightarrow {1 \over 2}{\gamma _w}{H^2}=\mu \left( {{1 \over 2}{\gamma _C}bH - {1 \over 2}{\gamma _w}bH} \right)\]                       (32.2)

\[\Rightarrow b=\frac{{{\gamma _w}H}}{{\mu\left({{\gamma _C}-{\gamma _w}}\right)}}=\frac{H}{{\mu\left({\frac{{{\gamma _C}}}{{{\gamma _w}}}-1}\right)}}\Rightarrow b=\frac{H}{{\mu \left({{S_c}-1}\right)}}\]....(32.3)

\[{S_c}={{{\gamma _c}}{\left/{{{\gamma _c}} {{\gamma _w}}}} {{\gamma _w}}}\]  specific gravity of dam material ]

If uplift is neglected, \[b={H{\left/ {{H {\mu {S_c}}}}}{\mu {S_c}}}\]

In this case the normal stress developed at the base of the gravity dam varies as linearly with maximum tensile stress at the heel and maximum compressive stress at the toe as shown in Figure 32.3.

Fig. 32.2.

\[{p_{ntoe}}\]  and  \[{p_{nheel}}\] are given by,
\[{p_{ntoe}}={{{R_y}} \over b}\left( {1 + {{6e} \over b}} \right)\]            (32.4)

\[{p_{nheel}}={{{R_y}} \over b}\left( {1 - {{6e} \over b}} \right)\]           (32.5)

where, \[e={b \over 2} - {{{M_{toe}}} \over {{R_y}}}\]                               (32.6)

Now,

\[{R_y}=W - U = {1 \over 2}{\gamma _w}bH\left( {{S_c} - 1} \right)\]                            (32.7)

\[{M_{toe}}=W{{2b} \over 3} - {F_H}{H \over 3} - U{{2b} \over 3}={{{b^2}} \over 3}{\gamma _w}H\left( {{S_c} - 1} \right) - {{{H^3}} \over 6}{\gamma _w}\]                       (32.8)

From Equations (3) and (6) – (8), we have,

\[{p_{ntoe}}={\gamma _w}H{\mu ^2}{\left( {{S_c} - 1} \right)^2}\]                                (32.9)

\[{p_{ntoe}}={\gamma _w}H\left( {{S_c} - 1} \right)\left[ {1 - {\mu ^2}\left( {{S_c} - 1} \right)} \right]\]                        (32.10)

Corresponding principal stress at toe,

\[{\sigma _1}={p_{ntoe}}{\sec ^2}\varphi\]                                       (32.11)

\[\Rightarrow {\sigma _1}={\gamma _w}H{\mu ^2}{\left( {{S_c} - 1} \right)^2}\left[ {{{\left( {b/H} \right)}^2} + 1} \right]\]   [ \[\tan \varphi=b/H\] ]            (32.12)

\[\Rightarrow {\sigma _1}={\gamma _w}H\left[ {{\mu ^2}{{\left( {{S_c} - 1} \right)}^2} + 1} \right]\]  [ \[b={H \over {\mu \left( {{S_c} - 1} \right)}}\]  ]   (32.13)

Similarly, shear stress is,

\[\tau={\gamma _w}H{\mu ^2}{\left({{S_c}-1} \right)^2}\tan \varphi\Rightarrow\tau={\gamma _w}H\mu \left( {{S_c}-1} \right)\]          (32.14)

Following the similar approach stresses at the heel can be computed.


No tension criteria

Tension generally occurs at the heel. Condition for no tension is,

Moment of FH about heel = moment of Ry about heel.

\[\Rightarrow {F_H}{H \over 3}=\left( {W - U} \right){b \over 3}\]                 (32.15)

\[\Rightarrow {1 \over 6}{\gamma _w}{H^3}=\left( {{1 \over 2}{\gamma _C}bH - {1 \over 2}{\gamma _w}bH} \right){b \over 3}\]                 (32.16)

\[\Rightarrow {H^2}=\left( {{S_C} - 1} \right){b^2}\]                  (32.17)

\[\Rightarrow b={H{\left/ {\sqrt {\left( {{S_C} - 1} \right)} }}\]                       (32.18)

If uplift is neglected, \[b = {H{\left/ {\sqrt {{S_c}} }}\].


In this case the normal stress developed at the base of the gravity dam varies linearly with zero value at the heel and maximum at the toe as shown in Figure 32.3.

 Fig. 32.3.


\[{1 \over 2}b{p_{ntoe}}=W - U \Rightarrow {1 \over 2}b{p_{ntoe}}={1 \over 2}{\gamma _C}bH - {1 \over 2}{\gamma _w}bH\]        (32.19)

\[\Rightarrow {p_{ntoe}}={\gamma _w}H\left( {{{{\gamma _C}} \over {{\gamma _w}}} - 1} \right) \Rightarrow {p_{ntoe}}={\gamma _w}H\left( {{S_c} - 1} \right)\]            (32.20)

Corresponding principal stress at toe,

\[{\sigma _1}={p_{ntoe}}{\sec ^2}\varphi\]                  (32.21)

\[\Rightarrow {\sigma _1}={\gamma _w}H\left( {{S_c} - 1} \right)\left[ {{{\left( {b/H} \right)}^2} + 1} \right]\]   [ \[\tan \varphi=b/H\] ]       (32.22)

\[\Rightarrow {\sigma _1}={\gamma _w}H\left( {{S_c} - 1} \right)\left[ {{1 \over {{S_C} - 1}} + 1} \right]\]                  (32.23)

\[\Rightarrow {\sigma _1}={\gamma _w}H{S_c}\]                   (32.24)

Similarly, shear stress is,

\[\tau={p_{ntoe}}\tan\varphi\Rightarrow\tau={\gamma _w}H\left( {{S_c} - 1} \right){b \over H} \Rightarrow \tau={\gamma _w}H{{\left( {{S_c} - 1} \right)} \over {\sqrt {\left( {{S_c} - 1} \right)} }}\]               (32.25)

\[\Rightarrow \tau={\gamma _w}H\sqrt {\left( {{S_c} - 1} \right)}\]             (32.26)

32.1.2 Limiting height of a gravity dam

The limiting height of a gravity dam is determined based on no tension criteria. The maximum value of principal stress should not exceed the permissible value.

Therefore,

\[{\sigma _1}\le{\sigma _a}\]          [ \[{\sigma _a}\]  is the allowable normal stress]

\[\Rightarrow {\gamma _w}{H_{\lim }}{S_c} \le {\sigma _a}\]

\[\Rightarrow {H_{\lim }} \le {{{\sigma _a}} \over {{\gamma _w}{S_c}}}\]                  (32.27)

Generally, uplift pressure is not considered while determining the limiting height of a gravity dam. Following the approach given in section 32.1.1, it can be shown that for no uplift pressure Equation (27) is reduced to,

\[{H_{\lim }} \le {{{\sigma _a}} \over {{\gamma _w}\left( {{S_c} + 1} \right)}}\]         (32.28)

 

The document Introduction to Profile & its types - Stability Analysis of Gravity Dams, Strength of Materials | Strength of Material Notes - Agricultural Engg - Agricultural Engineering is a part of the Agricultural Engineering Course Strength of Material Notes - Agricultural Engg.
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FAQs on Introduction to Profile & its types - Stability Analysis of Gravity Dams, Strength of Materials - Strength of Material Notes - Agricultural Engg - Agricultural Engineering

1. What is a profile in the context of stability analysis of gravity dams?
Ans. In the context of stability analysis of gravity dams, a profile refers to the vertical cross-section of the dam that shows its various components and dimensions. It provides a visual representation of the dam's shape, height, and thickness, along with the location of the reservoir and the foundation. The profile is crucial in determining the stability and structural integrity of the dam.
2. What are the types of profiles used in stability analysis of gravity dams?
Ans. There are two main types of profiles used in stability analysis of gravity dams: - Upstream Profile: This type of profile shows the dam's upstream face, which is the side facing the reservoir. It includes the crest, which is the topmost part of the dam, and the slope leading down to the foundation. The upstream profile is essential in analyzing the stability of the dam against the water pressure exerted by the reservoir. - Downstream Profile: The downstream profile displays the dam's downstream face, which is the side opposite to the reservoir. It includes the slope from the crest to the foundation, along with any protective measures such as a concrete lining or rockfill. The downstream profile is crucial in assessing the stability of the dam against external forces such as wave action or erosion.
3. How does the profile of a gravity dam affect its stability?
Ans. The profile of a gravity dam plays a significant role in determining its stability. The shape and dimensions of the dam influence its ability to resist the various forces acting upon it, such as water pressure, seismic forces, and uplift. A well-designed profile ensures that the dam can safely withstand these forces without failure. Specifically, the profile affects the stability of the dam by: - Providing adequate weight and resistance against overturning and sliding. - Distributing and dissipating water pressure uniformly across the dam. - Minimizing the potential for uplift and seepage through the foundation. - Allowing for the safe dissipation of seismic forces. - Incorporating protective features such as spillways or energy dissipation devices.
4. What are the key considerations in designing the profile of a gravity dam?
Ans. Designing the profile of a gravity dam involves several key considerations to ensure its stability and structural integrity. Some important factors to consider include: - Reservoir characteristics: The dimensions and behavior of the reservoir, including water level fluctuations and wave action, influence the profile's shape and dimensions. - Foundation conditions: The properties of the foundation material, such as its strength and permeability, dictate the profile's slope and the need for additional protective measures. - Material availability: The availability of construction materials, such as concrete or rockfill, affects the choice of profile shape and dimensions. - Seismicity: The level of seismic activity in the region determines the profile's ability to withstand earthquake forces. - Environmental impact: The profile design should consider any potential environmental impacts, such as the avoidance of protected habitats or preservation of scenic views.
5. How can the stability of a gravity dam be assessed using the profile?
Ans. The stability of a gravity dam can be assessed using the profile by considering various factors and performing calculations. Some common methods of assessing stability include: - Determining the factor of safety: This involves calculating the ratio of the resisting forces (such as weight and friction) to the driving forces (such as water pressure and seismic forces). A factor of safety greater than one indicates stability. - Analyzing critical sections: By analyzing critical sections along the dam's profile, engineers can identify potential failure modes and assess their stability individually. - Conducting stability analyses for different loading conditions: Engineers can simulate different loading conditions, such as maximum reservoir level or seismic events, to assess the stability of the dam under various scenarios. - Considering stability during construction: The profile should also account for stability during construction, ensuring that the dam remains stable during the construction process and before it reaches its final design configuration.
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