Respuesta :
(a) The cycle is not possible.
(b) The cycle operates irreversibly.
(c) The cycle operates irreversibly.
(d) The cycle is not possible.
Explanation:
Given -
Temperature of hot reservoir, Th = 1500K
Temperature of cold reservoir, Tc = 500K
(a)
Heat transfer at hot reservoir, Qh = 550 kW
Heat transfer at cold reservoir, Qc = 100 kW
Maximum net work -
Wcycle = Qh - Qc
Wcycle = 550 - 100 = 450kW
Maximum efficiency -
ηmax = 1 - Tc/Th
ηmax = 1 - 500/1500 =  0.667
ηmax = 66.7%
η(actual) = Wcycle/ Qh
η(actual) = 450 kW/ 550 = 0.8
η(actual) = 80%
Since the actual efficiency is higher than the maximum efficiency, the cycle is not possible.
(b)
Heat transfer at hot reservoir, Qh = 500 kW
Heat transfer at cold reservoir, Qc = 200 kW
Maximum net work -
Wcycle = Qh - Qc
Wcycle = 500 - 200 = 300kW
Maximum efficiency -
ηmax = 1 - Tc/Th
ηmax = 1 - 500/1500 =  0.667
ηmax = 66.7%
η(actual) = Wcycle/ Qh
η(actual) = 300 kW/ 500 = 0.6
η(actual) = 60%
Since the actual efficiency is lower than the maximum efficiency, the cycle operates irreversibly.
(c)
Heat transfer at hot reservoir, Qh = 300 kW
Heat transfer at cold reservoir, Qc = 150 kW
Maximum net work -
Wcycle = Qh - Qc
Wcycle = 300 - 150 = 150 kW
Maximum efficiency -
ηmax = 1 - Tc/Th
ηmax = 1 - 500/1500 =  0.667
ηmax = 66.7%
η(actual) = Wcycle/ Qh
η(actual) = 150 kW/ 300 = 0.5
η(actual) = 50%
Since the actual efficiency is lower than the maximum efficiency, the cycle operates irreversibly.
(d)
Heat transfer at hot reservoir, Qh = 500 kW
Heat transfer at cold reservoir, Qc = 100 kW
Maximum net work -
Wcycle = Qh - Qc
Wcycle = 500 - 100 = 400kW
Maximum efficiency -
ηmax = 1 - Tc/Th
ηmax = 1 - 500/1500 =  0.667
ηmax = 66.7%
η(actual) = Wcycle/ Qh
η(actual) = 400 kW/ 500 = 0.8
η(actual) = 80%
Since the actual efficiency is higher than the maximum efficiency, the cycle is not possible.
