Efficiencies of Cycles A and B
Let the cycles operate between pressures $P$ and $cP$.
1. Efficiency of Cycle A ($\eta_A$):
Cycle A operates between volumes $2V$ and $3V$.
Work done $W_A = (cP – P)(3V – 2V) = (c-1)PV$.
Heat Absorbed ($Q_{in,A}$) occurs during isochoric pressure rise and isobaric expansion:
- Isochoric ($2V, P \to cP$): $Q_1 = n C_v \Delta T = \frac{3}{2} (2V) (cP – P) = 3(c-1)PV$.
- Isobaric ($cP, 2V \to 3V$): $Q_2 = n C_p \Delta T = \frac{5}{2} (cP) (3V – 2V) = 2.5 c PV$.
2. Efficiency of Cycle B ($\eta_B$):
Cycle B operates between volumes $4V$ and $5V$.
Work done $W_B = (cP – P)(5V – 4V) = (c-1)PV$. (Same work as A).
Heat Absorbed ($Q_{in,B}$):
- Isochoric ($4V, P \to cP$): $Q_1 = \frac{3}{2} (4V) (cP – P) = 6(c-1)PV$.
- Isobaric ($cP, 4V \to 5V$): $Q_2 = \frac{5}{2} (cP) (5V – 4V) = 2.5 c PV$.
3. Using the Ratio $k$:
Given $\frac{\eta_A}{\eta_B} = k$.
$$k = \frac{17c – 12}{11c – 6}$$Solving for $c$ in terms of $k$: $11kc – 6k = 17c – 12 \Rightarrow c(11k – 17) = 6k – 12$.
$$c = \frac{6(k-2)}{11k – 17}$$Substituting this back into the expression for $\eta_A$ simplifies significantly (after algebraic manipulation):
$$\eta_A = \frac{k-1}{3}$$And consequently:
$$\eta_B = \frac{\eta_A}{k} = \frac{k-1}{3k}$$Answer: $\eta_A = \frac{k-1}{3}$ and $\eta_B = \frac{k-1}{3k}$