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Parents Pricing Home NSC Technical Sciences Elasticity A load of 40 kN causes a compressive stress of 16 MPa in a square brass bar
A load of 40 kN causes a compressive stress of 16 MPa in a square brass bar - NSC Technical Sciences - Question 5 - 2022 - Paper 1 Question 5
View full question A load of 40 kN causes a compressive stress of 16 MPa in a square brass bar. Young's modulus for brass is 90 GPa. The original length of the bar is 300 mm.
5.1 Dete... show full transcript
View marking scheme Worked Solution & Example Answer:A load of 40 kN causes a compressive stress of 16 MPa in a square brass bar - NSC Technical Sciences - Question 5 - 2022 - Paper 1
5.1.1 The length, x, of one side of the square brass bar. Give your answer in millimetres. Only available for registered users.
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To find the length of one side, we start from the formula for stress:
σ = F A σ = \frac{F}{A} σ = A F Where:
σ = stress = 16 , \text{MPa} = 16 \times 10^6 , \text{Pa}
F = load = 40 , \text{kN} = 40 \times 10^3 , \text{N}
A = area = x^2 (where x is one side of the square bar)
Substituting the values, we have:
16 × 1 0 6 = 40 × 1 0 3 x 2 16 \times 10^6 = \frac{40 \times 10^3}{x^2} 16 × 1 0 6 = x 2 40 × 1 0 3 Rearranging gives:
x 2 = 40 × 1 0 3 16 × 1 0 6 = 0.0025 m 2 x^2 = \frac{40 \times 10^3}{16 \times 10^6} = 0.0025 \, \text{m}^2 x 2 = 16 × 1 0 6 40 × 1 0 3 = 0.0025 m 2 Thus, taking the square root:
x = 0.05 m = 50 mm x = 0.05 \, \text{m} = 50 \, \text{mm} x = 0.05 m = 50 mm
5.1.2 The strain caused by the load Only available for registered users.
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The strain (ε) can be calculated using:
ε = σ E ε = \frac{σ}{E} ε = E σ Where:
E = Young's modulus = 90 , \text{GPa} = 90 \times 10^9 , \text{Pa}
Substituting the known values:
ε = 16 × 1 0 6 90 × 1 0 9 = 1.78 × 1 0 − 4 ε = \frac{16 \times 10^6}{90 \times 10^9} = 1.78 \times 10^{-4} ε = 90 × 1 0 9 16 × 1 0 6 = 1.78 × 1 0 − 4
5.1.3 The change in length, in millimetres, caused by the load Only available for registered users.
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The change in length (ΔL) can be calculated with:
Δ L = L × ε ΔL = L \times ε Δ L = L × ε Where L is the original length of the bar:
L = 300 , \text{mm} = 0.3 , \text{m}
Thus, substituting values:
Δ L = 0.3 × 1.78 × 1 0 − 4 = 0.0000534 m = 0.0534 mm ΔL = 0.3 \times 1.78 \times 10^{-4} = 0.0000534 \, \text{m} = 0.0534 \, \text{mm} Δ L = 0.3 × 1.78 × 1 0 − 4 = 0.0000534 m = 0.0534 mm
5.2.1 The fluid pressure in the hydraulic system when in equilibrium Only available for registered users.
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In equilibrium, the pressure (P) can be calculated using:
P = F A P = \frac{F}{A} P = A F For Piston B:
F = 20 , \text{kN} = 20 \times 10^3 , \text{N}
The area (A) for Piston B (diameter = 200 mm):
A = π ( d 2 ) 2 = π ( 0.2 2 ) 2 = π 4 × ( 0.2 ) 2 = 3.142 × 1 0 − 2 m 2 A = \pi \left( \frac{d}{2} \right)^2 = \pi \left( \frac{0.2}{2} \right)^2 = \frac{\pi}{4} \times (0.2)^2 = 3.142 \times 10^{-2} \, \text{m}^2 A = π ( 2 d ) 2 = π ( 2 0.2 ) 2 = 4 π × ( 0.2 ) 2 = 3.142 × 1 0 − 2 m 2 Then:
P = 20 × 1 0 3 3.142 × 1 0 − 2 = 636.54 × 1 0 3 Pa P = \frac{20 \times 10^3}{3.142 \times 10^{-2}} = 636.54 \times 10^3 \, \text{Pa} P = 3.142 × 1 0 − 2 20 × 1 0 3 = 636.54 × 1 0 3 Pa
5.2.2 The force, F, that must be exerted onto Piston A Only available for registered users.
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To find the force F, we can use the pressure calculated earlier:
P = F A A P = \frac{F}{A_A} P = A A F Where A_A is the area for Piston A:
Diameter = 50 mm = 0.05 m:
A A = π ( 0.05 2 ) 2 = 3.142 × 1 0 − 3 m 2 A_A = \pi \left( \frac{0.05}{2} \right)^2 = 3.142 \times 10^{-3} \, \text{m}^2 A A = π ( 2 0.05 ) 2 = 3.142 × 1 0 − 3 m 2 Now substituting:
Using P = 636.54 \times 10^3 , \text{Pa}:
F = P × A A = 636.54 × 1 0 3 × 3.142 × 1 0 − 3 = 2000 N = 2 kN F = P \times A_A = 636.54 \times 10^3 \times 3.142 \times 10^{-3} = 2000 \, \text{N} = 2 \, \text{kN} F = P × A A = 636.54 × 1 0 3 × 3.142 × 1 0 − 3 = 2000 N = 2 kN Join the NSC students using SimpleStudy...97% of StudentsReport Improved Results
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