Post on 01-Jan-2017
Bending Beam Louisiana State University
Joshua Board
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Table of Contents:
Table of Figures: ........................................................................................................................................... 4
Purpose .......................................................................................................................................................... 5
Introduction ................................................................................................................................................... 5
Apparatus and Test Procedures ................................................................................................................... 11
Summary of Data ........................................................................................................................................ 14
Discussion of Results .................................................................................................................................. 17
Conclusion .................................................................................................................................................. 20
References ................................................................................................................................................... 21
Sample Calculations .................................................................................................................................... 22
4
Table of Figures:
Figure 1 - Bending on a Cross Section ........................................................................................................... 5
Figure 2 - Bending Action caused by Transverse Loads ................................................................................ 6
Figure 3 - SM104 Beam Apparatus ............................................................................................................. 11
Figure 4 - Loading Arrangement for Test 1 and Test 2 ............................................................................... 12
Figure 5 - Loading Arrangement for Test 3 ................................................................................................. 13
Figure 6 - Deflection vs. Load Theory .......................................................................................................... 18
Figure 7 - Deflection vs. Load Experimental ............................................................................................... 18
Figure 8 - Deflection vs. Load Steel Theory ................................................................................................. 19
Figure 9 - Deflection vs. Load Steel Experimental ...................................................................................... 19
Table 1 - Test 1 Data ................................................................................................................................... 14
Table 2 - Test 2 Steel 6mm .......................................................................................................................... 15
Table 3 - Test 2 Steel 3mm .......................................................................................................................... 15
Table 4 - Test 2 Brass 6mm ......................................................................................................................... 15
Table 5 - Test 2 Aluminium 6mm ................................................................................................................ 16
Table 6 - Stiffness ........................................................................................................................................ 16
Table 7 - Test 3 Data ................................................................................................................................... 17
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Purpose
The purpose of this laboratory is to become familiar with the SM104 Beam Apparatus by
first verifying its sensitivity and accuracy. The second part of the lab will focus on using the
SM104 Beam Apparatus to determine the deflection of point-loaded simply-supported beams
made of steel, brass or aluminum. Using the deflection measurements, an examination of the
relationship between deflection and material properties will be shown along with a comparison
of the materials based on their strengths and deflections, both theoretical and experimental. The
last objective of this laboratory is to verify the theory of pure bending using the SM104 Beam
Apparatus.
Introduction
Engineers use beams to support loads over a span length. These beams are structural
members that are only loaded non-axially causing them to be subjected to bending. “A piece is
said to be in bending if the forces act on a piece of material in such a way that they tend to
induce compressive stresses over one part of a cross section of the piece and tensile stresses over
the remaining part” (Ref. 1). This definition of bending is illustrated below in Figure 1.
Figure 1 - Bending on a Cross Section
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It can be seen from Figure 1 that the compressive force, C, and the tensile force, T, acting on the
member are equal in magnitude because of equilibrium. Therefore, the compressive force and the
tensile force form a force couple whose moment is equal to either the tensile force multiplied by
the moment arm or the compressive force multiplied by the moment arm. The moment arm is
denoted, e, in Figure 1.
Figure 2 - Bending Action caused by Transverse Loads
Figure 2, shown above, is an illustration of bending action in a beam acted upon by
transverse loads. Bending may be accompanied by direct stress, transverse shear or torsional
shear, however for convenience; bending stresses may be considered separately (Ref. 1). In
order to separate the stresses it is assumed that the loads are applied in the following manner:
loads act in a plane of symmetry, no twisting occurs, deflections are parallel to the plane of the
loads, and no longitudinal forces are induced by the loads or by the supports (Ref. 1).
A beam or part of a beam that is only acted on by the bending stresses is said to be in a
condition of “pure bending.” However for many circumstances bending is accompany by
transverse shear. The term “flexure” is used to refer to bending tests of beams subjected to
transverse loading (Ref. 1). A visual illustration of the transverse shear and bending moment can
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be seen in the shear and bending moment diagrams of the beam. It is important to note that in a
symmetrical 2-point loading scenario, the center portion of the beam will be in a condition of
pure bending as such the bending stresses may be considered separately.
“Deflection” of a beam is the displacement of a point on the neutral surface of a beam
from its original position under the action of applied loads (Ref. 1). Before the proportional limit
of the material, the deflection, Δ, can be calculated using the moment of inertia, modulus of
elasticity along with other section properties that will depend on the given situation imposed on
the beam. The position of the load, the type of load applied on the beam, and the length of beam
are examples of section properties that depend on the situation. The deflection equations for two
common cases are listed below in equations (1) and (2).
Case 1: Center deflection of a simple beam with freely supported ends and concentrated
load, P, at the mid-span (Ref. 1).
Equation (1)
where:
Δ = deflection, (mm)
P = load, (N)
L = length of beam, (mm)
E = modulus of elasticity (N/m2)
I = moment of inertia of section about the neutral axis, (mm4)
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Case 2: Center deflection of a simple beam with concentrated loads, each equal to P, at
third points of span (Ref. 1).
Equation (2)
where:
Δ = deflection, (mm)
P = load, (N)
L = length of beam, (mm)
E = modulus of elasticity (N/m2)
I = moment of inertia of section about the neutral axis, (mm4)
Deflection is a measure of overall stiffness of a given beam and can be seen to be a
function of the stiffness of the material and proportions of the piece (Ref. 1). Deflection
measurements give the engineer a way to calculate the modulus of elasticity for a material in
flexure. The stiffness of a given material is calculated using the following equation:
Equation (3)
where:
P = load, (N)
Δ = deflection, (mm)
Stiffness (N/m)
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A beam may fail in any of the following ways: A beam may fail by yielding of extreme
fibers, in long span beams compression fivers act like those of a column and fail by buckling, in
webbed members excessive shear stress may occur and stress concentrations may build up in
parts of beam adjacent to bearing blocks (Ref. 1). The scope and applicability of the bending
tests are defined as:
1) Used as a direct means of evaluation behavior under bending loads, particularly for
determining limits of structural stability of beams of various shapes and sizes.
2) Made to determine strength and stiffness in bending.
3) Occasionally made to get stress distribution in a flexural member.
4) May be used to determine resilience and toughness of materials in bending.
5) Uses simple and inexpensive apparatus.
6) Used as control test for brittle materials and not suitable for determining ultimate strength
of ductile materials. (Ref. 1)
Deflection for experiment 1 is calculated with the following:
Equation (4)
where:
R1 = reaction at support 1, (N)
R2 = reaction at support 2, (N)
W1 = load at point 1, (N)
W2 = load at point 2, (N)
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Percent error for experiment 1 is calculated with the following:
Equation (5)
where:
Δ = deflection, (mm)
W1 = load at point 1, (N)
W2 = load at point 2, (N)
For experiment 3, y is calculated as follows:
Equation (6)
where:
h1 = reading from gauge 1, (mm)
h3 = reading from gauge 3, (mm)
For experiment 3, h is calculated as follows:
Equation (7)
where:
h2 = reading from gauge 2, (mm)
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Apparatus and Test Procedures
In this laboratory, an SM104 Beam Apparatus was utilized and is shown below in Figure
(3). This apparatus has load cells with a capacity of 0 – 46 N.
Figure 3 - SM104 Beam Apparatus
Procedure for Test 1:
1) Calibrate the dial gauges.
2) Find the mid span of the beam.
3) Set up load cells as shown in Figure 4.
4) Place a beam on apparatus with 1/4 span overhang.
5) Position the two hangers equidistant from the mid-point.
6) Position the dial gauge at the mid-point.
7) Apply the load to the hangers.
8) Record the data.
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Figure 4 - Loading Arrangement for Test 1 and Test 2
Procedure for Test 2:
1) Calibrate the dial gauges.
2) Find the mid span of the beam.
3) Set up load cells as shown in Figure 4.
4) Place a beam on apparatus with 1/4 span overhang.
5) Place the hanger at the mid-span.
6) Position the dial gauge over the mid-span.
7) Apply the load to the hanger.
8) Record beam deflection.
9) Increase the load and record the dial reading, repeat for 5 different load patterns.
10) Decrease the load and record the dial reading, repeat for 5 different load patterns.
11) Repeat for each beam.
Procedure for Test 3:
1) Calibrate the dial gauges.
2) Find the mid span of the beam.
3) Set up load cells as shown in Figure 4.
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4) Place a beam on apparatus with 1/4 span overhang.
5) Place one hanger near the left end of the beam and place a second hanger near the right
end of the beam as shown in Figure 5.
6) Position a dial gauge at mid-span and two other dial gauges equidistant on either side as
shown in Figure 5.
7) Zero the gauges.
8) Apply the load to the two hangers.
9) Increase the load and repeat step 8 for at least five different loads.
10) Record the data.
Figure 5 - Loading Arrangement for Test 3
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Summary of Data
The results from Test 1, the verification of the sensitivity and accuracy of the apparatus,
are shown below in Table 1. This table shows the reactions at the supports based on the applied
load. Deflection was calculated using Equation (4) and the percent error was determined with
Equation (5). The average error for Test 1 is also shown in Table 1 and it was determined that the
average error for this Test is 2.5%, therefore the SM104 Beam Apparatus is accurate within
2.5%.
Table 1 - Test 1 Data
R1 (N) W1 (N) W2 (N) R2 (N) R1 + R2 (N) Δ (N) %
4.0 5.0 0.0 1.2 5.2 0.2 4.0
7.0 10.0 0.0 3.3 10.3 0.3 3.0
10.5 15.0 0.0 5.0 15.5 0.5 3.3
14.0 20.0 0.0 6.0 20.0 0.0 0.0
21.0 30.0 0.0 8.0 29.0 -1.0 -3.3
1.5 0.0 5.0 3.8 5.3 0.3 6.0
3.1 0.0 10.0 6.9 10.0 0.0 0.0
5.1 0.0 15.0 10.5 15.6 0.6 4.0
6.2 0.0 20.0 14.7 20.9 0.9 4.5
11.0 0.0 30.0 20.2 31.2 1.2 4.0
5.5 5.0 5.0 5.1 10.6 0.6 6.0
9.8 10.0 10.0 10.2 20.0 0.0 0.0
15.0 15.0 15.0 15.2 30.2 0.2 0.7
21.7 20.0 20.0 19.7 41.4 1.4 3.5
30.5 30.0 30.0 30.8 61.3 1.3 2.2
Average Error 2.5
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The results for Test 2, deflection of a simply supported beam with load, beam thickness and
material, are shown below based on material type in Tables 2 – 5. Each table shows the load
applied, the material properties and both the theoretical and experimental deflections determined
by Test 2. Looking at the tables it is clear that the material with the smallest cross section, 3mm
Steel, experienced the largest deflection which was expected because that specimen has the
smallest moment of inertia.
Table 2 - Test 2 Steel 6mm
Load (N) deflection theory (mm) deflection theory (m) E (N/mm2) Load (N) deflection exp (mm) deflection exp (m)
0 0 0 210000 0 0
5 3.56849 0.00357 Inertia (mm4) 5 5 0.005
10 7.13698 0.00714 342 10 8 0.008
15 10.70547 0.01071 Length (mm) 15 10 0.01
20 14.27397 0.01427 1350 20 15 0.015
25 17.84246 0.01784 25 20 0.02
30 21.41095 0.02141 30 25 0.025
Steel (6mm)
Table 3 - Test 2 Steel 3mm
Load (N) deflection theory (mm) deflection theory (m) E (N/mm2) Load (N) deflection exp (mm) deflection exp (m)
0 0 0 210000 0 0 0
5 28.54793 0.02855 Inertia (mm4) 5 30 0.03
10 57.09586 0.05710 42.75 10 70 0.07
15 85.64380 0.08564 Length (mm) 15 100 0.1
20 114.19173 0.11419 1350 20 130 0.13
25 142.73966 0.14274 25 170 0.17
30 171.28759 0.17129 30 200 0.2
Steel (3mm)
Table 4 - Test 2 Brass 6mm
Load (N) deflection theory (mm) deflection theory (m) E (N/mm2) Load (N) deflection exp (mm) deflection exp (m)
0 0 0 105000 0 0 0
5 7.13698 0.00714 Inertia (mm4) 5 8 0.008
10 14.27397 0.01427 342 10 15 0.015
15 21.41095 0.02141 Length (mm) 15 23 0.023
20 28.54793 0.02855 1350 20 31 0.031
25 35.68492 0.03568 25 38 0.038
30 42.82190 0.04282 30 44 0.044
Brass (6mm)
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Table 5 - Test 2 Aluminium 6mm
Load (N) deflection theory (mm) deflection theory (m) E (N/mm2) Load (N) deflection exp (mm) deflection exp (m)
0 0 0 76000 0 0 0
2 3.94412 0.00394 Inertia (mm4) 2 3 0.003
4 7.88824 0.00789 342 4 7 0.007
6 11.83237 0.01183 Length (mm) 6 11 0.011
8 15.77649 0.01578 1350 8 16 0.016
10 19.72061 0.01972 10 21 0.021
Aluminium (6mm)
Using the applied load and having already solved for the deflection of each material under that
load, the stiffness of the material can be determined using Equation (3). Shown below is Table 6
which had the calculated stiffness for each material.
Table 6 - Stiffness
Material Thickness (mm) Stiffness (N/m) (theory) Stiffness (N/m) (exp)
Steel 6 0.0007 0.0008
Steel 3 0.0057 0.0067
Brass 6 0.0014 0.0015
Aluminium 6 0.002 0.0023
The results from Test 3 are shown in Table 7 below. The table contains the applied load, the
distances to the load, a and b, the dial gauge readings and the modulus of elasticity based on the
data. The average E value is 108544.22 N/mm2 and after accounting for the error found in Test 1
our value is 105830.61 N/mm2.
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Table 7 - Test 3 Data
Load (N) b (mm) a (mm) h1 (mm) h2 (mm) h3 (mm) y (mm) h2 - y E (N/mm2)
5 300 100 2.2 2.4 2.2 2.2 0.2 109649.12
10 300 100 3.2 3.6 3.3 3.25 0.35 125313.28
15 300 100 3.7 4.4 3.8 3.75 0.65 101214.57
20 300 100 7.5 8.3 7.4 7.45 0.85 103199.17
25 300 100 7.8 8.8 7.9 7.85 0.95 115420.13
5 300 150 1.7 2.2 1.8 1.75 0.45 109649.12
10 300 150 3.5 4.4 3.4 3.45 0.95 103878.12
15 300 150 4.6 6 4.6 4.6 1.4 105733.08
20 300 150 6 7.8 6.2 6.1 1.7 116099.07
25 300 150 6.8 9.2 6.8 6.8 2.4 102796.05
5 300 200 1.4 2.2 1.3 1.35 0.85 103199.17
10 300 200 2.8 4.5 2.9 2.85 1.65 106326.42
15 300 200 5 7.6 5.2 5.1 2.5 105263.16
20 300 200 4.7 8 4.8 4.75 3.25 107962.21
25 300 200 4.6 8.5 4.6 4.6 3.9 112460.64
Inertia (mm4) 108544.22
342 105830.61
Test 1
Test 2
Test 3
Average E value
Average E accounting for error
Discussion of Results
Test 1 showed that the SM104 Beam Apparatus was verified to have an average error of
2.5%. This is an acceptable error for this kind of test and we accounted for this error when we
found the average E value in Test 3. Shown below in Figure s 6 - 9 are the graphs that were
obtained from Test 2. Figure 6 shows deflection vs. load based on theoretical data and Figure 7
shows deflection vs. load for the experimental data gathered in the lab. From these charts it is
clear to see that as the modulus of elasticity decreased from material to material, the deflection
increased for the same applied load. This was true for both the theoretical and the experimental
data.
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Figure 6 - Deflection vs. Load Theory
Figure 7 - Deflection vs. Load Experimental
0
20
40
60
80
100
120
140
160
180
0 5 10 15 20 25 30 35
De
fle
ctio
n
Load (N)
Deflection vs. Load Theory
6 mm Steel
3 mm Steel
6 mm Brass
6 mm Aluminum
0
50
100
150
200
250
0 10 20 30 40
De
fle
ctio
n
Load (N)
Deflection vs. Load Experimental
6 mm Steel
3 mm Steel
6 mm Brass
6 mm Aluminium
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Figure 8 and Figure 9 both compare the two types of steels tested. From the figures, you can see
that as the moment of inertia decreases, the deflection of the material increases.
Figure 8 - Deflection vs. Load Steel Theory
Figure 9 - Deflection vs. Load Steel Experimental
0
20
40
60
80
100
120
140
160
180
0 5 10 15 20 25 30 35
De
fle
ctio
n
Load (N)
Deflection vs. Load Steel Theory
6 mm Steel
3 mm Steel
0
50
100
150
200
250
0 5 10 15 20 25 30 35
De
fle
ctio
n
Load (N)
Deflection vs. Load Steel Experimental
6 mm Steel
3 mm Steel
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Table 7 displayed previously shows the results from Test 3. From the measured radius of
curvature and the set up shown in Figure 5, the modulus of elasticity was determined. Even
though some of the numbers that were determined were off by some error, the overall average
value of E was determined to be 108,544.22 N/mm2. This number is very close to the expected
value of 105000 N/mm2 and after accounting for the 2.5% error our numbers are very close.
Conclusion
Using the SM104 Beam Apparatus, we were able to determine first that our numbers
were accurate. Secondly, we found from Test 2 that as the modulus of elasticity of each
specimen decreased, the deflection increased which is consistent with Equation (1). We also
determined that the stiffness of a material is a function of the load over the deflection, meaning
that if the load increases but the deflection does not, then the material is considered stiff. Test 3
proved that the theory of pure bending holds true when the material has not exceeded the
proportional limit because as shown in Table 7, the modulus of elasticity is constant over this
region.
Some human error could have occurred during the laboratory, however our results match
up to the reference values which leads me to believe that error could not have played a big factor
in this lab. Overall a greater understanding of deflection and how different materials react to the
same applied load was achieved.
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References
1. Jacobs, C., CE 3410 Notes – “Bending summary”, received in class on March 16, 2009.
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Sample Calculations
Steel 6mm
Test 1:
Deflection, Δ
Δ = (4.0 + 1.2) – (5 + 0) = 0.2
% error
= 4.0%
Test 2:
Deflection theory (mm)
= 3.57 mm
Stiffness (N/m)
= 0.008 N/m
Test 3:
E = = = 7.97 x 1011
N/m2