def f_etas(etas, stator, rotor, one, two, thr, gamma, cp, R, GR, psi, DeltaH_prod, bounds_angles, RHT, mdot): stator.eta = etas[0] rotor.eta = etas[1] # 1. # mach 3 converge until calculated value meets the initial guess # inside of this function, alpha2 and beta 3 are also set so that the DeltaH is met one, two, thr, stator, rotor = converge_mach3(one, two, thr, stator, rotor, gamma, cp, R, GR, psi, DeltaH_prod, bounds_angles) # 1.2 # calculate loss coefficients stator = f.losses(two.vel.V, two.vel.Vs, one.P0, two.P0, two.P, stator) rotor = f.losses(thr.vel.W, thr.vel.Ws, two.P0r, thr.P0r, thr.P, rotor) # 1.4 # compute total condtions thr.T0, thr.P0 = f.total_conditions(thr.T, thr.vel.V, thr.P, cp, gamma) # 2. # establish geometry after assuming RHT solve_geometry(RHT, one, two, thr, mdot, R, gamma, cp) # efficiency calculations stator.eta = (one.T0 - thr.T0) / (one.T0 - (thr.Ts + thr.vel.V**2 / 2 / cp)) rotor.eta = (one.T0 - thr.T0) / (one.T0 - thr.Ts) diff1 = abs(stator.eta - etas[0]) diff2 = abs(rotor.eta - etas[1]) return np.array([diff1, diff2])
def f_etas(etas, stator, rotor, one, two, thr, gamma, cp, R, GR, psi, DeltaH_prod, bounds_angles, RHT, mdot): stator.eta = etas[0] rotor.eta = etas[1] # 1. # mach 3 converge until calculated value meets the initial guess # inside of this function, alpha2 and beta 3 are also set so that the DeltaH is met one, two, thr, stator, rotor = converge_mach3(one, two, thr, stator, rotor, gamma, cp, R, GR, psi, DeltaH_prod, bounds_angles) # 1.2 # calculate loss coefficients stator = f.losses(two.vel.V, two.vel.Vs, one.P0, two.P0, two.P, stator) rotor = f.losses(thr.vel.W, thr.vel.Ws, two.P0r, thr.P0r, thr.P, rotor) # 1.4 # compute total condtions thr.T0, thr.P0 = f.total_conditions(thr.T, thr.vel.V, thr.P, cp, gamma) # 2. # establish geometry after assuming RHT solve_geometry(RHT, one, two, thr, mdot, R, gamma, cp) # efficiency calculations stator.eta = (one.T0 - thr.T0) / (one.T0 - (thr.Ts + thr.vel.V**2 / 2 / cp)) rotor.eta = (one.T0 - thr.T0) / (one.T0 - thr.Ts) # calculate reynolds numbers f.reynolds(two, thr) f.trailing_throat(two, thr) # use kacker-okapuu to calculate losses in stator and rotor stator.omegaKC = kackerokapuu('stator', two.geo.s, abs(one.alpha), abs(two.beta), two.geo.c, two.geo.bx, two.geo.h, one.vel.M, two.vel.M, one.P, two.P, gamma, RHT, two.Re, two.geo.to) rotor.omegaKC = kackerokapuu('rotor', thr.geo.s, abs(two.alpha), abs(thr.beta), thr.geo.c, thr.geo.bx, thr.geo.h, two.vel.M, thr.vel.M, two.P, thr.P, gamma, RHT, thr.Re, thr.geo.to) diff1 = abs(stator.omega - stator.omegaKC) diff2 = abs(rotor.omega - rotor.omegaKC) print(diff1, diff2) return np.array([diff1, diff2])