def testIsentropic(self):
inlet = State("Water", Q=1, P=10 * 10 ** 6)
outlet = State("Water", P=10 * 10 ** 3)
inlet.define()
turb = Turbine(inlet, outlet)
turb.isentropic(0.9)
self.assertEquals(True, outlet.defined)
self.assertEquals(abs(outlet.properties["h"] * 10 ** (-3) - 1870) < 10, True)
def testExergyBalance(self):
inlet = State("Water", Q=1, P=10 * 10 ** 6)
outlet = State("Water", P=10 * 10 ** 3)
inlet.define()
turb = Turbine(inlet, outlet)
turb.isentropic(0.9)
turb.exergyBalance(300, 100 * 10 ** 3)
import IPython
IPython.embed()
class ReheatedRankine(object):
"""
This is a very specific use of the base state and component functions
that I need for a project in my Thermo class. Once I am done with the project
I plan on introducing a much more generica way of developing a cycle
"""
def __init__(self, p_1, t_1, p_2, p_cond, eta_t, eta_p,t_3, t0, p0, TL, TH):
self._one = State('Water', P=p_1, T=t_1)
self._one.define()
self._two = State('Water', P=p_2)
self.turb_one = Turbine(self._one, self._two)
self.turb_one.isentropic(eta_t)
self.turb_one.exergyBalance(t0, p0)
self._three = State('Water', P=p_2, T=t_3)
self._three.define()
self.reheater = Reheater(self._two, self._three)
self._four = State('Water', P=p_cond)
self.turb_two = Turbine(self._three, self._four)
self.turb_two.isentropic(eta_t)
self.turb_two.exergyBalance(t0, p0)
self._five = State('Water')
self.condensor = Condensor(p_cond, self._four, self._five)
self._six = State('Water', P=p_1)
self.pump = Pump(self._five, self._six)
self.pump.isentropic(eta_p)
self.pump.exergyBalance(t0, p0)
self.superHeater = Reheater(self._six, self._one)
self.eta = (sum([self.turb_two.w, self.turb_one.w, self.pump.w])/
sum([self.reheater.q, self.superHeater.q]))
self.E = self.eta*(1/(1-float(TL)/float(TH)))
def __init__(self, t0, p0, p_1, t_1, p_2, eta_t, eta_p, p_cond, TL, TH):
self.one = State('Water', P=p_1, T=t_1)
self.one.define()
self.two = State('Water', P=p_2)
self.turb_one = Turbine(self.one, self.two)
self.turb_one.isentropic(eta_t)
self.turb_one.exergyBalance(t0, p0)
self.three = State('Water', P=p_cond)
self.turb_two = Turbine(self.two, self.three)
self.turb_two.isentropic(eta_t)
self.four = State('Water', P=p_cond, Q=0)
self.four.define()
self.five = State('Water', P=p_1)
self.pump_one = Pump(self.four, self.five)
self.pump_one.isentropic(eta_p)
self.six = State('Water', P=p_1, T=350)
self.six.define()
self.seven = State('Water', P=p_2, Q=0)
self.seven.define()
self.eight = State('Water', P=p_cond, h=self.seven.properties['h'])
self.eight.define()
y = ((self.six.properties['h']-self.five.properties['h'])
/(self.two.properties['h']-self.seven.properties['h']))
self.y = y
self.turb_two.exergyBalanceY(t0, p0, y)
self.pump_one.exergyBalance(t0, p0)
self.superHeater = Reheater(self.six, self.one)
self.eta = (sum([self.turb_one.w, self.turb_two.w, self.pump_one.w])/
sum([self.superHeater.q]))
self.E = self.eta*(1/(1-float(TL)/float(TH)))
self.cfwh = CFeedWater([self.two, self.five], [y, 1], [self.seven, self.six],
[y, (1-y)], t0, p0)
def __init__(self, t0, p0, p_1, t_1, p_2, eta_t, eta_p, p_cond, TL, TH):
self.one = State('Water', P=p_1, T=t_1)
self.one.define()
self.two = State('Water', P=p_2)
self.turb_one = Turbine(self.one, self.two)
self.turb_one.isentropic(eta_t)
self.turb_one.exergyBalance(p0, t0)
self.three = State('Water', P=p_cond)
self.turb_two = Turbine(self.two, self.three)
self.turb_two.isentropic(eta_t)
self.four = State('Water', P=p_cond)
self.condensor = Condensor(p_cond, self.three, self.four)
self.five = State('Water', P=p_2)
self.pump_one = Pump(self.four, self.five)
self.pump_one.isentropic(eta_p)
self.six = State('Water', P=p_2, Q=0)
if self.six.define():
y = ((self.six.properties['h']-self.five.properties['h'])
/(self.two.properties['h']-self.five.properties['h']))
else:
print 'Failed to define state 6'
self.y = y
self.seven = State('Water', P=p_1)
self.pump_two = Pump(self.six, self.seven)
self.pump_two.isentropic(eta_p)
self.pump_two.exergyBalance(t0, p0)
self.turb_two.exergyBalanceY(t0, p0, y)
self.pump_one.exergyBalanceY(t0, p0, y)
self.superHeater = Reheater(self.seven, self.one)
self.eta = (sum([self.turb_one.w, self.turb_two.w, self.pump_one.w, self.pump_two.w])/
sum([self.superHeater.q]))
self.E = self.eta*(1/(1-float(TL)/float(TH)))
self.ofwh = OFeedWater([self.two, self.five], [y, (1-y)], self.six, [1], t0, p0)
def __init__(self, p_1, t_1, p_2, p_cond, eta_t, eta_p,t_3, t0, p0, TL, TH):
self._one = State('Water', P=p_1, T=t_1)
self._one.define()
self._two = State('Water', P=p_2)
self.turb_one = Turbine(self._one, self._two)
self.turb_one.isentropic(eta_t)
self.turb_one.exergyBalance(t0, p0)
self._three = State('Water', P=p_2, T=t_3)
self._three.define()
self.reheater = Reheater(self._two, self._three)
self._four = State('Water', P=p_cond)
self.turb_two = Turbine(self._three, self._four)
self.turb_two.isentropic(eta_t)
self.turb_two.exergyBalance(t0, p0)
self._five = State('Water')
self.condensor = Condensor(p_cond, self._four, self._five)
self._six = State('Water', P=p_1)
self.pump = Pump(self._five, self._six)
self.pump.isentropic(eta_p)
self.pump.exergyBalance(t0, p0)
self.superHeater = Reheater(self._six, self._one)
self.eta = (sum([self.turb_two.w, self.turb_one.w, self.pump.w])/
sum([self.reheater.q, self.superHeater.q]))
self.E = self.eta*(1/(1-float(TL)/float(TH)))
class CFWH(object):
"""
This is a very specific use of the base state and component functions
that I need for a project in my Thermo class. Once I am done with the project
I plan on introducing a much more generica way of developing a cycle
"""
def __init__(self, t0, p0, p_1, t_1, p_2, eta_t, eta_p, p_cond, TL, TH):
self.one = State('Water', P=p_1, T=t_1)
self.one.define()
self.two = State('Water', P=p_2)
self.turb_one = Turbine(self.one, self.two)
self.turb_one.isentropic(eta_t)
self.turb_one.exergyBalance(t0, p0)
self.three = State('Water', P=p_cond)
self.turb_two = Turbine(self.two, self.three)
self.turb_two.isentropic(eta_t)
self.four = State('Water', P=p_cond, Q=0)
self.four.define()
self.five = State('Water', P=p_1)
self.pump_one = Pump(self.four, self.five)
self.pump_one.isentropic(eta_p)
self.six = State('Water', P=p_1, T=350)
self.six.define()
self.seven = State('Water', P=p_2, Q=0)
self.seven.define()
self.eight = State('Water', P=p_cond, h=self.seven.properties['h'])
self.eight.define()
y = ((self.six.properties['h']-self.five.properties['h'])
/(self.two.properties['h']-self.seven.properties['h']))
self.y = y
self.turb_two.exergyBalanceY(t0, p0, y)
self.pump_one.exergyBalance(t0, p0)
self.superHeater = Reheater(self.six, self.one)
self.eta = (sum([self.turb_one.w, self.turb_two.w, self.pump_one.w])/
sum([self.superHeater.q]))
self.E = self.eta*(1/(1-float(TL)/float(TH)))
self.cfwh = CFeedWater([self.two, self.five], [y, 1], [self.seven, self.six],
[y, (1-y)], t0, p0)
