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Use of Newmark’s Influence Chart - Stress in Soil due to applied load, Soil Mechanics | Soil Mechanics Notes- Agricultural Engineering PDF Download

Use of Newmark’s Influence Chart

Newmark (1942) developed influence chart to determine the vertical stress due to loaded of area of any shape, irregular geometry at any point below the loaded area. A uniformly loaded circular area of radius r1 is divided into 20 divisions (say the first circle in Figure 8.1). Now if q is the intensity of loading then each small unit of the first circle will produce a vertical stress equal to \[{{{\sigma _z}}\over {20}}\]  at any depth of z below the center of the loaded area (as first circle is divided into 20 small divisions). Now from Eq. 7.5 of lesson 7 one can write that at any depth z vertical stress due to each small unit of the circle as:

\[\frac{{{\sigma _Z}}}{{20}}=\frac{q}{{20}}\left[{1-{{\left( {\frac{1}{{1+{{\left( {\frac{{{r_1}}}{z}}\right)}^2}}}}\right)}^{\frac{3}{2}}}}\right]\]       (8.1)

Let the right hand side of the Eq. 8.1 is equal to an arbitrary fixed value which is called influence value (say 0.005q). Thus,

\[\frac{q}{{20}}\left[{1-{{\left({\frac{1}{{1+{{\left({\frac{{{r_1}}}{z}}\right)}^2}}}}\right)}^{\frac{3}{2}}}}\right]=0.005q\]           (8.2)

The influence value of the chart is equal to 0.005 and each small unit is producing a vertical stress equal to 0.005q. After solving Eq. 8.2, one can get \[{{{r_1}} \over z}=0.27\] .  Thus, the radius of the first circle is 0.27z. In the influence chart (Figure 8.1), AB line representing the value of z (in the figure it is 2.5 cm). Thus, according to the chart shown in the Figure 8.1, any depth is represented by 2.5cm and based on that the scale has to be decided. According to that scale the loaded area has to be drawn for stress calculation. In the Figure 1, the radius of the first circle is 0.27 x 2.5 = 0.675 cm. Similarly, the second concentric circle of radius r2 is also divided in to 20 divisions. Including first and second circles, there are 40 divisions and again each unit is producing a vertical stress equal to 0.005q at a depth of z below the centre of the loaded area. Therefore, the each small unit in the second circle has two units and each unit will produce a vertical stress equal to 0.005q a depth of z below the centre of the loaded area. Thus, each small unit in the second circle will produce 2 x 0.005q amount of vertical stress a depth of z below the centre of the loaded area. Vertical stress due to each unit of the second circle is:

\[\frac{q}{{20}}\left[{1-{{\left({\frac{1}{{1+{{\left({\frac{{{r_2}}}{z}}\right)}^2}}}}\right)}^{\frac{3}{2}}}}\right]=2\times 0.005q\]             (8.3)

Again After solving Eq. 8.3, one can get \[{{{r_2}} \over z}=0.40\] . Thus, the radius of the second circle is 0.40z. The general expression of the vertical stress produce by each unit of the each circle at a depth of z below the centre of the loaded area can be written as:

\[\frac{q}{{20}}\left[{1-{{\left({\frac{1}{{1+{{\left({\frac{{{r_i}}}{z}}\right)}^2}}}}\right)}^{\frac{3}{2}}}}\right] = i\times 0.005q\]                (8.4)

where i = 1, 2, ……..9. After solving Eq. 8.4, the radius of the third to ninth circle can be determined as: 0.52z, 0.64z, 0.77z, 0.92z, 1.11z, 1.39z, 1.91z, respectively. The radius of the tenth circle is infinity and cannot be drawn. 

Problem 1

A raft foundation of dimension 11m x 6.2m is placed at a depth of 2m below the ground level. Determine the net stress due to the raft foundation (stress due to applied load only) at a depth of 7m below the ground level. Also determine the total stress due to raft (stress due to applied load) and stress due to soil (overburden pressure) at a depth of 7m below the ground level. The raft is subjected to total load of 10000 kN. The unit weight of the soil is 18 kN/m3. Neglect the pore water pressure (assumed soil is completely dry).
Use of Newmark’s Influence Chart - Stress in Soil due to applied load, Soil Mechanics | Soil Mechanics Notes- Agricultural Engineering

Fig. 8.1. Newmark’s influence chart to calculate vertical stress


Solution:

The total stress acting at the base of the raft =  \[{{100000} \over {11 \times 6.2}}=146.6\] kN/m2. The net stress at the base of raft = 146.6 – 18 x 2 = 110.6 kN/m2 (net stress means total stress minus the stress due to the soil above the base of the foundation as before the application of load soil was existing there. Thus, stress due to soil has to be deducted to calculate the net stress).


Now, depth of the point below the base of the raft is (z) = 7 – 2 = 5m.


Thus, according to the Newmark’s chart (Figure 1), 2.5 cm = 5m. Scale is 1: 200. Now, the raft (CDEF) is drawn with a scale of 1: 200 and placed on the Newmark’s chart (as shown in Figure 8.1) such that the centre of the raft is coincided with the centre of the Newmark’s chart. This is to be noted that, here the stress below the centre of the raft is determined. Thus, centre of the raft is coincided with the centre of the Newmark’s chart. If the vertical stress below the corner or any other point within the raft is to be determined than the corner or the point on interest has to be coincided with the centre of the Newmark’s chart. The total number of influence area covered by the raft = 116 (as shown in Figure 8.1). The net stress at a depth of 7 m below the ground level or 5 m below the base of the raft = 110.6 x 0.005 x 116 = 64.2 kN/m2. Thus, vertical stress due to applied load only is 64.2 kN/m2.


The vertical stress due to the overburden pressure at a depth of 7 m below the ground level = 18 x 7 = 126 kN/m2. Thus total vertical stress due to the applied load and overburden pressure at a depth of 7 m below the ground level = (64.2 + 126) = 190.2 kN/m2.

The document Use of Newmark’s Influence Chart - Stress in Soil due to applied load, Soil Mechanics | Soil Mechanics Notes- Agricultural Engineering is a part of the Agricultural Engineering Course Soil Mechanics Notes- Agricultural Engineering.
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FAQs on Use of Newmark’s Influence Chart - Stress in Soil due to applied load, Soil Mechanics - Soil Mechanics Notes- Agricultural Engineering

1. What is Newmark's Influence Chart?
Ans. Newmark's Influence Chart is a graphical method used in soil mechanics to determine the stress distribution in soil due to an applied load. It helps engineers analyze the settlement and stress changes in the soil as the load is transferred through it.
2. How does Newmark's Influence Chart work?
Ans. Newmark's Influence Chart works by using a set of curves that represent the influence of a loaded area on adjacent points in the soil. The chart allows engineers to determine the vertical stress at any point in the soil profile by simply reading the corresponding value from the chart.
3. What is the significance of stress in soil due to an applied load?
Ans. The stress in soil due to an applied load is significant as it directly affects the stability and performance of structures built on or with soil. It helps engineers understand how the soil will behave under different loading conditions, allowing them to design foundations and other structures accordingly.
4. Can Newmark's Influence Chart be used in agricultural engineering?
Ans. Yes, Newmark's Influence Chart can be used in agricultural engineering. It is particularly useful in analyzing the stress distribution in soil under agricultural machinery, such as tractors or harvesters. This information can help determine potential soil compaction and its impact on crop growth.
5. Are there any limitations to using Newmark's Influence Chart?
Ans. Yes, there are limitations to using Newmark's Influence Chart. It assumes linear elastic soil behavior, which may not always be accurate in real-world scenarios. Additionally, the chart does not account for factors such as soil heterogeneity, groundwater effects, or time-dependent soil behavior. Therefore, it should be used as a preliminary analysis tool and complemented with more advanced methods when necessary.
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