Recent Question/Assignment
Thin-walled T-section Tapered Cantilever Beam
The Problem
A thin-walled T-section cantilevered beam is fixed at one end and is subjected to a vertically downward point load of 368N at the free end.
The section is of uniform thickness of 2mm.
The Young's modulus value is 200kN/mm2and Poisson’s ratio is 0.25
368N
2mm
100mm
100mm
2mm
t=2mm
N.B. the dimensions represent only the free end and gets bigger towards the fixed end. The web in middle of the beam 500mm from the free end is 150mm instead of 100mm
Finite Element Model
1 Work in units of N (force) and mm (length) and MPa (=N/mm2modulus/stress).
2 Use Plate/Shell QUAD8 element.
3 Take the global axes origin to be at the bottom left corner the fixed end- (X,Y, Z).
4 Generate the nodes and element manually for three elements model. UseTools Subdivide for generation of more elements.
Use QUAD8 elements as required
4@25
A
4@ 250mm
200mm
Q S
R
X
Z
B
P
4@ 25mm
Finite Element Output
1 Vertical deflection (DY) along the line AB.
2 Bending stress (SZZ), in Global axes, along the line AB.
3 Bending stress (SZZ), in Global axes, along the line PQ.
4 Vertical shear stress (SYZ), in Global axes, along the line PQ.
Theory
1 Use the double integration method to find the vertical deflection along the top surface (line AB).
2 Use the bending theory to find the bending stress along the top surface (line AB).
3 Use the bending theory to find the bending stress along the web (line PQ).
4 Use the bending theory to find the vertical shear stress distribution along the web (line PQ).
Results–DY-Vertical deflection (mm) along AB
Distance from fixed end (mm) Theory FE
0
150
300
450
600
750
900
1050
1200
Results–SZZ (Global axes)-Bending stress (N/mm2) along AB
Distance from fixed end (mm) Theory FE
0
150
300
450
600
750
900
1050
1200
Results–SZZ (Global axes) –Bending stress (N/mm2) along PQ
Distance from bottom(mm) Theory FE
0(P)
12.5
25
37.5
50
62.5
75
87.5
100(Q)
Results–SYZ (Global axes)-Shear stress(N/mm2) along PQ
Distance from bottom(mm) Theory FE
0(P)
12.5
25
37.5
50
62.5
75
87.5
100(Q)
Plot Graph
1 Plot on the same graph the span wise finite element vertical deflectionvalues (along AB) superimposed on the theoretical values.
2 Plot on the same graph the span wise the finite element bending stress values (along AB) superimposed on the theoretical values.
3 Plot on the same graph the finite element bending stress values (along PQ) superimposed on the theoretical values.
4 Plot on the same graph the finite element vertical shear stress values (along PQ) superimposed on the theoretical values.
The experimental values I are shown below but does not have to be same as theory and
strand7.
Load (N) Deflection (mm) Stress@ Flange 1 Stress@Flange 2 Stress @Web
0 0 0 0 0
18 0.14 0.9 0.4 0.2
28 0.22 1 0.6 0.2
38 0.3 1.4 0.6 0.1
48 0.38 1.5 1 -0.2
58 0.47 1.7 1.2 -0.3
68 0.55 1.8 1.3 -0.5
88 0.73 2.2 1.7 -0.8
108 0.89 2.5 1.9 -0.8
128 1.06 2.8 2.2 -1.1
148 1.24 3 2.7 -1.3
168 1.42 3.4 3 -1.6
188 1.64 3.7 3.2 -1.8
208 1.84 3.9 3.6 -2
228 2.07 4.3 4 -2.2
248 2.32 4.6 4.4 -2.6
268 2.65 4.9 4.7 -2.8
288 3.05 5.2 5.2 -3
308 3.39 5.3 5.5 -3.2
328 3.8 5.6 5.9 -3.4
348 4.19 6 6.3 -3.6
368 4.58 6.4 6.7 -4
The Problem
A thin-walled T-section cantilevered beam is fixed at one end and is subjected to a vertically downward point load of 368N at the free end.
The section is of uniform thickness of 2mm.
The Young's modulus value is 200kN/mm2and Poisson’s ratio is 0.25
368N
2mm
100mm
100mm
2mm
t=2mm
N.B. the dimensions represent only the free end and gets bigger towards the fixed end. The web in middle of the beam 500mm from the free end is 150mm instead of 100mm
Finite Element Model
1 Work in units of N (force) and mm (length) and MPa (=N/mm2modulus/stress).
2 Use Plate/Shell QUAD8 element.
3 Take the global axes origin to be at the bottom left corner the fixed end- (X,Y, Z).
4 Generate the nodes and element manually for three elements model. UseTools Subdivide for generation of more elements.
Use QUAD8 elements as required
4@25
A
4@ 250mm
200mm
Q S
R
X
Z
B
P
4@ 25mm
Finite Element Output
1 Vertical deflection (DY) along the line AB.
2 Bending stress (SZZ), in Global axes, along the line AB.
3 Bending stress (SZZ), in Global axes, along the line PQ.
4 Vertical shear stress (SYZ), in Global axes, along the line PQ.
Theory
1 Use the double integration method to find the vertical deflection along the top surface (line AB).
2 Use the bending theory to find the bending stress along the top surface (line AB).
3 Use the bending theory to find the bending stress along the web (line PQ).
4 Use the bending theory to find the vertical shear stress distribution along the web (line PQ).
Results–DY-Vertical deflection (mm) along AB
Distance from fixed end (mm) Theory FE
0
150
300
450
600
750
900
1050
1200
Results–SZZ (Global axes)-Bending stress (N/mm2) along AB
Distance from fixed end (mm) Theory FE
0
150
300
450
600
750
900
1050
1200
Results–SZZ (Global axes) –Bending stress (N/mm2) along PQ
Distance from bottom(mm) Theory FE
0(P)
12.5
25
37.5
50
62.5
75
87.5
100(Q)
Results–SYZ (Global axes)-Shear stress(N/mm2) along PQ
Distance from bottom(mm) Theory FE
0(P)
12.5
25
37.5
50
62.5
75
87.5
100(Q)
Plot Graph
1 Plot on the same graph the span wise finite element vertical deflectionvalues (along AB) superimposed on the theoretical values.
2 Plot on the same graph the span wise the finite element bending stress values (along AB) superimposed on the theoretical values.
3 Plot on the same graph the finite element bending stress values (along PQ) superimposed on the theoretical values.
4 Plot on the same graph the finite element vertical shear stress values (along PQ) superimposed on the theoretical values.
The experimental values I are shown below but does not have to be same as theory and
strand7.
Load (N) Deflection (mm) Stress@ Flange 1 Stress@Flange 2 Stress @Web
0 0 0 0 0
18 0.14 0.9 0.4 0.2
28 0.22 1 0.6 0.2
38 0.3 1.4 0.6 0.1
48 0.38 1.5 1 -0.2
58 0.47 1.7 1.2 -0.3
68 0.55 1.8 1.3 -0.5
88 0.73 2.2 1.7 -0.8
108 0.89 2.5 1.9 -0.8
128 1.06 2.8 2.2 -1.1
148 1.24 3 2.7 -1.3
168 1.42 3.4 3 -1.6
188 1.64 3.7 3.2 -1.8
208 1.84 3.9 3.6 -2
228 2.07 4.3 4 -2.2
248 2.32 4.6 4.4 -2.6
268 2.65 4.9 4.7 -2.8
288 3.05 5.2 5.2 -3
308 3.39 5.3 5.5 -3.2
328 3.8 5.6 5.9 -3.4
348 4.19 6 6.3 -3.6
368 4.58 6.4 6.7 -4
Looking for answers ?
Recent Questions
I have an another assignment to do.48353 – Concrete Design, Autumn 2024Design Group ProjectDESIGN BRIEFFigure 1 represents the floor plan of ...................... building to be constructed in the CBD of ……………..! The building is to be...Title: Tutorial WorkbookStudent: XXXXX XXXXXXXXXXStudent Number: XXXXXXXXEmail Address: XXX.XXXXXXXX@postgrad.curtin.edu.auSchool/Program: Health Promotion/Public HealthUnit: Health Promotion Strategies...Factors that impact registered nurses ability to influence national government health policy?Write a 3000 words assessment factors that impact registered nurses' ability to influence national government...TCHR5010:Competency and capability of PreschoolersAssessment Two: Portfolio(Deferred Placement)Information BookletAssessment name: Portfolio of planning cycleDue Date: Monday 10th June (WEEK 7) 11:59pmWeighting:...BackgroundGiven recent attacks on the Healthcare sector, and some noted data breaches, FauxCura Health have engaged Quantum.LogiGuardian (Q.LG), a cyber security consultancy and analytics firm.FauxCura...Assessment 2Authentic Assessment StatementThe purpose of this assessment is to extend the capacity to report on Aboriginal culture using academic frameworks and examples of personal and professional interest....Show All Questions