5.1 A force of 16 N is applied to a 3 m long metal wire - NSC Technical Sciences - Question 5 - 2021 - Paper 1

Strain ($ext{ε}$) is defined as the ratio of the change in length ($ext{ΔL}$) to the original length (L).

Given:

• Change in length, $ext{ΔL} = 0.5 ext{ mm} = 0.0005 ext{ m}$
• Original length, L = 3 m

The formula for strain is:

ext{ε} = rac{ ext{ΔL}}{L} = rac{0.0005}{3} = 1.67 imes 10^{-4}

extbf{Final Result:} Strain in the wire is $1.67 	imes 10^{-4}$.

Young's modulus (K) is the ratio of stress to strain.

Using the results from 5.1.1 and 5.1.2:

K = rac{ ext{Stress}}{ ext{Strain}} = rac{3.26 imes 10^6}{1.67 imes 10^{-4}} = 1.95 imes 10^{10} ext{ Pa}

extbf{Final Result:} Young's modulus of the wire is $1.95 	imes 10^{10} 	ext{ Pa}$.

Pressure (P) at a specific point is defined as the thrust or force (F) acting on the unit area (A) around that point. Mathematically, it can be expressed as:

P = rac{F}{A}

This definition highlights that pressure is a measure of how concentrated a force is over a specific area.

Given:

• Force applied, F = 26 N
• Area of input piston, A = 7.855 × 10⁻⁶ m²

Using the formula for pressure:

P = rac{F}{A} = rac{26}{7.855 imes 10^{-6}} = 3.309 imes 10^{5} ext{ Pa}

extbf{Final Result:} Fluid pressure in the hydraulic system is $3.309 	imes 10^5 	ext{ Pa}$.

Using the relationship between forces and areas in a hydraulic system:

rac{F_1}{A_1} = rac{F_2}{A_2}

Where:

• $F_1$ is the force on the input piston,
• $A_1$ is the area of the input piston,
• $F_2$ is the force exerted by the output piston (1,278 N),
• $A_2$ is the area of the output piston.

Rearranging gives:

A_2 = A_1 rac{F_2}{F_1}

Substituting in the values:

F_2 = 1278 ext{ N}, F_1 = 26 ext{ N}$$ Now calculate: $$A_2 = 7.855 imes 10^{-6} imes rac{1278}{26} ext{ m}^2 = 3.861 imes 10^{-3} ext{ m}^2$$ extbf{Final Result:} Area of the output piston is $3.861 imes 10^{-3} ext{ m}^2$.