def test_ExpBasic_run(self):
flowIn = mc.FlowState("water", "HEOS", None, 10., CP.PT_INPUTS, 3.e6,
mc.degC2K(500))
exp = mc.ExpBasic(6, 0.8, flowIn)
exp.run()
self.assertAlmostEqual(exp.flowOut.T, 563.74, 2)
self.assertAlmostEqual(exp.P_out / 1000, 4121.11, 2)
def test_ExpBasic_size_pRatio(self):
flowIn = mc.FlowState("water", -1, mc.PT_INPUTS, 2.e6, mc.degC2K(350))
flowOut = mc.FlowState("water", -1, mc.PQ_INPUTS, 50000., 1)
exp = mc.ExpBasic(-1, 0.686, flowIn, flowOut)
exp.update({'m': 1.})
exp.size() # defaults to sizeAttr=pRatio,sizeBounds=[1,50]
self.assertAlmostEqual(exp.pRatio, 40.0, 5)
def test_ExpBasic_size_pRatio(self):
flowIn = mc.FlowState("water", "HEOS", None, None, CP.PT_INPUTS, 2.e6,
mc.degC2K(350))
flowOut = mc.FlowState("water", "HEOS", None, None, CP.PQ_INPUTS,
50000., 1)
exp = mc.ExpBasic(None, 0.686, flowIn, flowOut, m=1.0)
exp.size() # defaults to sizeAttr=pRatio,sizeBracket=[1,50]
self.assertAlmostEqual(exp.pRatio, 40.0, 5)
def test_ExpBasic_size_effIsentropic(self):
flowIn = mc.FlowState("water", "HEOS", None, None, CP.PT_INPUTS, 2.e6,
mc.degC2K(350))
flowOut = mc.FlowState("water", "HEOS", None, None, CP.PQ_INPUTS,
50000., 1)
exp = mc.ExpBasic(40, 1.0, flowIn, flowOut, m=1.0)
exp.size("effIsentropic", [0.5, 0.8])
self.assertAlmostEqual(exp.effIsentropic, 0.686, 3)
def test_ExpBasic_size_efficiencyIsentropic(self):
flowIn = mc.FlowState("water", -1, mc.PT_INPUTS, 2.e6, mc.degC2K(350))
flowOut = mc.FlowState("water", -1, mc.PQ_INPUTS, 50000., 1)
exp = mc.ExpBasic(40, 1.0, flowIn, flowOut)
exp.update({
'm': 1.,
'sizeAttr': "efficiencyIsentropic",
'sizeBounds': [0.5, 0.8]
})
exp.size()
self.assertAlmostEqual(exp.efficiencyIsentropic, 0.686, 3)
class TestRankineBasic(unittest.TestCase):
wf = mc.FlowState("R123")
pEvap = 10.e5
superheat = 30.
TCond = 300.
subcool = 0
comp = mc.CompBasic(nan, 0.7, sizeAttr="pRatio")
sourceIn = mc.FlowState("Air", 0.09, mc.PT_INPUTS, 1.116e5, 1170.)
evap = mc.library.alfaLaval_AC30EQ()
evap.update({'sizeAttr': "NPlate", 'plate.T': 573.15})
exp = mc.ExpBasic(nan, 0.7, sizeAttr="pRatio")
sinkIn = mc.FlowState("Air", 0.20, mc.PT_INPUTS, 0.88260e5, 281.65)
sinkAmbient = sinkIn.copy()
sourceAmbient = sinkIn.copy()
cond = mc.ClrBasic(mc.CONSTANT_P, nan, 1, sizeAttr="QCool")
config = mc.Config()
config.update({
'dpEvap': False,
'dpCond': False,
'dpAcc': False,
'dpPort': False,
'dpHead': False
})
config.set_method("savostinTikhonov_sp", "GeomHxPlateChevron",
mc.TRANSFER_ALL, mc.UNITPHASE_ALL, mc.SECONDARY_FLUID)
cycle = mc.RankineBasic(wf, evap, exp, cond, comp, pEvap, superheat, nan,
subcool, config)
cycle.setAll_config(config)
cycle.update({
'TCond': TCond,
'sourceIn': sourceIn,
#'sinkIn': sinkIn,
'sourceAmbient': sourceAmbient,
#'sinkAmbient': sinkAmbient
})
cycle.pptdEvap = 10.
def test_0_setup_cycle(self):
self.assertAlmostEqual(self.cycle.pCond, 97797.60828695059, 5)
self.assertIs(self.cycle.exp.config, self.config)
self.assertAlmostEqual(self.cycle.mWf, 0.34307814292524513, 10)
def test_1_size(self):
self.cycle.update({"config.dpEvap": False, "evap.L": 0.269})
self.cycle.size()
self.assertEqual(self.cycle.evap.NPlate, 23)
self.assertAlmostEqual(
abs(self.cycle.evap.L - 0.268278920236407), 0, 2)
self.assertAlmostEqual(self.cycle.comp.pRatio, 10.22519893, 4)
self.assertAlmostEqual(self.cycle.exp.pRatio, 10.22519893, 4)
self.assertAlmostEqual(self.cycle.evap.Q(), 83891.17350428084, 4)
def test_1_size_dpEvap_True(self):
self.cycle.update({"config.dpEvap": True, "evap.L": 0.269})
self.cycle.size()
self.assertAlmostEqual(
abs(self.cycle.evap.L - 0.268278920236407), 0, 2)
self.assertAlmostEqual(
(self.cycle.comp.pRatio - 10.22519893) / 10.22519893, 0, 4)
self.assertAlmostEqual(
self.cycle.exp.pRatio,
(self.cycle.pEvap - 39607.4552153897) / self.cycle.pCond, 4)
self.assertAlmostEqual(self.cycle.evap.Q(), 83891.17350428084, 4)
def test_1_run_from_comp(self):
self.cycle.update({
"config.dpEvap": False,
"evap.NPlate": 23,
"evap.L": 0.269,
"pRatioExp": 10.22519893,
"pRatioComp": 10.22519893,
"cond.QCool": 73582.4417680011
})
self.cycle.clearWf_flows()
rb0 = self.wf.copyUpdateState(mc.PT_INPUTS, self.pEvap,
self.cycle.TEvap + 20.).h()
rb1 = self.wf.copyUpdateState(mc.PT_INPUTS, self.pEvap,
self.cycle.TEvap + 32.).h()
self.evap.update({"runBounds": [rb0, rb1]})
self.cycle.set_state6(
self.wf.copyUpdateState(mc.QT_INPUTS, 0, self.TCond))
self.cycle.run()
self.assertAlmostEqual(
abs(self.cycle.state4.T() / 3.6047e+02) - 1, 0, 3)
self.assertAlmostEqual(
abs(self.cycle.state4.p() / self.cycle.pCond) - 1, 0, 5)
self.assertAlmostEqual(
abs(self.cycle.state3.T() / (self.cycle.TEvap + 30)) - 1, 0, 3)
'''
def test_1_run_from_comp_dpEvap_True(self):
self.cycle.update({
"config.dpEvap": True,
"evap.NPlate": 23,
"evap.L": 0.269,
"exp.pRatio": 9.820204742676,
"comp.pRatio": 10.22519893,
"cond.QCool": 73582.4417680011
})
self.cycle.clearWf_flows()
rb0 = self.wf.copyUpdateState(mc.PT_INPUTS, self.pEvap,
self.cycle.TEvap + 20.).h()
rb1 = self.wf.copyUpdateState(mc.PT_INPUTS, self.pEvap,
self.cycle.TEvap + 32.).h()
self.evap.update({"runBounds": [rb0, rb1]})
self.cycle.set_state6(self.wf.copyUpdateState(mc.QT_INPUTS, 0, self.TCond))
self.cycle.run()
self.assertAlmostEqual(
abs(self.cycle.state4.T() / 3.6047e+02) - 1, 0, 3)
self.assertAlmostEqual(
abs(self.cycle.state4.p() / self.cycle.pCond) - 1, 0, 5)
self.assertAlmostEqual(abs(self.cycle.state3.T() / (413.67)) - 1, 0, 2)
self.assertAlmostEqual(
abs(self.cycle.state3.p() / (9.6039e5)) - 1, 0, 1)
'''
def test_1_run_from_exp(self):
self.cycle.update({
"config.dpEvap": False,
"evap.NPlate": 23,
"evap.L": 0.269,
"pRatioExp": 10.22519893,
"pRatioComp": 10.22519893,
"cond.QCool": 73582.4417680011
})
self.cycle.clearWf_flows()
rb0 = self.wf.copyUpdateState(mc.PT_INPUTS, self.pEvap,
self.cycle.TEvap + 20.).h()
rb1 = self.wf.copyUpdateState(mc.PT_INPUTS, self.pEvap,
self.cycle.TEvap + 32.).h()
self.evap.update({"runBounds": [rb0, rb1]})
self.cycle.set_state3(
self.wf.copyUpdateState(mc.PT_INPUTS, self.cycle.pEvap,
self.cycle.TEvap + 30))
self.cycle.run()
self.assertAlmostEqual(
abs(self.cycle.state4.T() / 3.6047e+02) - 1, 0, 3)
self.assertAlmostEqual(
abs(self.cycle.state4.p() / self.cycle.pCond) - 1, 0, 5)
self.assertAlmostEqual(
abs(self.cycle.state3.T() / (self.cycle.TEvap + 30)) - 1, 0, 3)
def test_cycle_plot(self):
import os
self.cycle.sizeSetup(True, True)
self.cycle.plot(
title="test_cycle_plot",
show=False,
savefig=True,
savefig_name="test_cycle_plot",
savefig_format="png",
savefig_folder=".")
cwd = os.getcwd()
os.remove("./test_cycle_plot.png")
# ************************************************
print("Set MCycle defaults...")
mc.defaults.PLOT_DIR = ""
mc.defaults.PLOT_DPI = 200
mc.defaults.check()
print("defaults done.")
print("Begin Rankine cycle setup...")
wf = mc.FlowState(
fluid="R245fa",
m=1.0,
inputPair=mc.PT_INPUTS,
input1=mc.atm2Pa(1),
input2=298)
print(" - created working fluid")
exp = mc.ExpBasic(pRatio=1, efficiencyIsentropic=0.9, sizeAttr="pRatio")
print(" - created expander")
cond = mc.ClrBasic(constraint=mc.CONSTANT_P, QCool=1, efficiencyThermal=1.0, sizeAttr="Q")
print(" - created condenser")
comp = mc.CompBasic(pRatio=1, efficiencyIsentropic=0.85, sizeAttr="pRatio")
print(" - created compressor")
evap = mc.HtrBasic(constraint=mc.CONSTANT_P, QHeat=1, efficiencyThermal=1.0, sizeAttr="Q")
print(" - created evaporator")
config = mc.Config()
print(" - created configuration object")
cycle = mc.RankineBasic(
wf=wf, evap=evap, exp=exp, cond=cond, comp=comp, config=config)
cycle.update({
"pEvap": mc.bar2Pa(10),
"superheat": 10.,
"TCond": mc.degC2K(25),
def run_example():
"""run example: zarati2017.py"""
# ************************************************
# Set up formatting
# ************************************************
# cycle.plot parameters
plots_folder = "plots"
plots_format = "png" # change to "jpg" if preferred
plots_dpi = 600
if not os.path.exists(plots_folder):
os.makedirs(plots_folder)
# custom format for matplotlib
mpl.rc("lines", lw=2.0)
mpl.rc("lines", markersize=2)
colours = ["blue", "red", "green", "black"]
linestyles = ["-", "--", "-.", ":"]
markerstyles = ["o", "v", "s", "^"]
# ************************************************
# Set up default cycle parameters
# ************************************************
#
comp = mc.CompBasic(None, 0.9, sizeAttr="pRatio")
#
exp = mc.ExpBasic(None, 0.85, sizeAttr="pRatio")
#
sourceFluid = "Air"
sourceIn_m = 5.5
sourceIn_T = 744. # from Table 9
sourceIn_p = 0.37e5 # from cp=1085.4
sourceIn = mc.FlowState(sourceFluid, "HEOS", None, sourceIn_m,
CP.PT_INPUTS, sourceIn_p, sourceIn_T)
evapGeomPlateWf = mc.GeomHxPlateSmooth(b=0.024375)
evapGeomPlateSf = mc.GeomHxPlateFinOffset(s=0.008,
h=0.03,
t=0.0002,
l=0.02)
stainlessSteel = mc.SolidMaterial(rho=8010., k=17.)
evap = mc.HxPlate(flowSense="counterflow",
NPlate=17,
RfWf=0,
RfSf=0,
plate=stainlessSteel,
tPlate=0.2e-3,
geomPlateWf=evapGeomPlateWf,
geomPlateSf=evapGeomPlateSf,
L=0.2,
W=0.44,
effThermal=1.0)
#
ambient = mc.isa(mc.ft2m(20000))
sinkFluid = "Air"
sinkIn_m = None
sinkIn_T = ambient.T / mc.TTotalRatio(gamma=1.4,
M=0.49) # from alt=20000ft
sinkIn_p = ambient.p / mc.pTotalRatio(gamma=1.4,
M=0.49) # TODO from alt=20000ft
sinkIn = mc.FlowState(sinkFluid, "HEOS", None, sinkIn_m, CP.PT_INPUTS,
sinkIn_p, sinkIn_T)
sinkDead = sinkIn.copy()
sourceDead = mc.FlowState(sourceFluid, "HEOS", None, None, CP.PT_INPUTS,
sinkIn_p, sinkIn_T)
cond = mc.ClrBasicConstP(None, 1, sizeAttr="Q")
#
config = mc.Config(dpEvap=False,
dpCond=False,
dpF=True,
dpAcc=False,
dpPort=False,
dpHead=False)
config.methods.set("shah_1phase_h", ["GeomHxPlateSmooth"], ["heat"],
["wf"], "all-sp")
cycle = mc.RankineBasic(wf=mc.FlowState("R245fa", "HEOS", None),
evap=evap,
exp=exp,
cond=cond,
comp=comp,
TEvap=416.18,
superheat=1.,
pCond=180.e3,
subcool=3.,
config=config,
sourceIn=sourceIn,
sinkIn=sinkIn,
sourceDead=sourceDead,
sinkDead=sinkDead)
# ************************************************
# Computations
# ************************************************
mWf_vals = np.linspace(1.0, 10.0, 20)
plot_x = []
plot_y0 = []
plot_y1 = []
plot_y2 = []
for m in mWf_vals:
cycle.update(mWf=m)
cycle.sizeSetup(True, False)
try:
cycle.evap.run()
print("---------")
print(cycle.evap.L)
plot_x.append(m)
plot_y0.append(cycle.evap.flowOutSf.cp)
plot_y1.append(cycle.evap.flowOutWf.T)
plot_y2.append(cycle.evap.dpSf / cycle.evap.flowInSf.p)
except:
print("No convergence for m={}".format(m))
plt.figure()
plt.plot(plot_x, plot_y0)
plt.savefig("{}/cp_vs_mWf.{}".format(plots_folder, plots_format))
plt.figure()
plt.plot(plot_x, plot_y1)
plt.savefig("{}/T3Wf_vs_mWf.{}".format(plots_folder, plots_format))
plt.figure()
plt.plot(plot_x, plot_y2)
plt.savefig("{}/dpSf/pSf_vs_mWf.{}".format(plots_folder, plots_format))
"""
sourceIn_T = 1170.
sourceIn_p = 1.116e5
sourceFluid = "N2[{0}]&CO2[{1}]".format(0.75, 0.25)
TData = [300, 500, 700, 900, sourceIn_T]
sourceRefData = mc.RefData(sourceFluid,
2,
sourceIn_p, {'T': TData},
phaseCP=CP.iphase_gas)
sourceIn = mc.FlowStatePoly(sourceRefData, 0.09, CP.PT_INPUTS, sourceIn_p,
sourceIn_T)
sourceAmbient = mc.FlowState(sourceFluid, CP.iphase_gas, -1, CP.PT_INPUTS,
0.88260e5, 281.65)
evap = mc.library.alfaLaval_AC30EQ(sizeAttr="NPlate")
print(" - created evaporator")
exp = mc.ExpBasic(-1, 0.7, sizeAttr="pRatio")
print(" - created expander")
sinkIn = mc.FlowState("Air", -1, -1, CP.PT_INPUTS, 0.88260e5, 281.65)
sinkAmbient = sinkIn.copy()
cond = mc.ClrBasic(constraint=mc.CONSTANT_P, -1, 1, sizeAttr="Q")
print(" - created condenser")
config = mc.Config()
config.update({
'dpEvap': False,
'dpCond': False,
'dpF': True,
'dpAcc': False,
'dpPort': False,
'dpHead': False
})
config.set_method("chisholmWannairachchi_sp", ["GeomHxPlateCorrugatedChevron"],
class TestRankineBasic(unittest.TestCase):
wf = mc.FlowState("R123", "HEOS", None)
pEvap = 10.e5
superheat = 30.
TCond = 300.
subcool = None
comp = mc.CompBasic(None, 0.7, sizeAttr="pRatio")
sourceIn = mc.FlowState("Air", "HEOS", None, 0.09, CP.PT_INPUTS, 1.116e5,
1170.)
evap = mc.library.alfaLaval_AC30EQ()
evap.update(sizeAttr="NPlate")
exp = mc.ExpBasic(None, 0.7, sizeAttr="pRatio")
sinkIn = mc.FlowState("Air", "HEOS", None, 0.20, CP.PT_INPUTS, 0.88260e5,
281.65)
sinkDead = sinkIn.copy()
sourceDead = sinkIn.copy()
#cond = mc.library.alfaLaval_CBXP27, sizeAttr="NPlate")
cond = mc.ClrBasicConstP(None, 1, sizeAttr="Q")
config = mc.Config(dpEvap=False,
dpCond=False,
dpAcc=False,
dpPort=False,
dpHead=False)
cycle = mc.RankineBasic(wf,
evap,
exp,
cond,
comp,
pEvap,
superheat,
None,
subcool,
config,
TCond=TCond,
sourceIn=sourceIn,
sinkIn=sinkIn,
sourceDead=sourceDead,
sinkDead=sinkDead)
cycle.pptdEvap = 10.
def test_0_setup_cycle(self):
self.assertAlmostEqual(self.cycle.pCond, 97797.60828695059, 5)
self.assertIs(self.cycle.exp.config, self.config)
self.assertAlmostEqual(self.cycle.mWf, 0.34307814292524513, 10)
def test_1_size(self):
self.cycle.config.dpEvap = False
self.cycle.size()
self.assertAlmostEqual(abs(self.cycle.evap.L - 0.268278920236407), 0,
2)
self.assertAlmostEqual(self.cycle.comp.pRatio, 10.22519893, 4)
self.assertAlmostEqual(self.cycle.exp.pRatio, 10.22519893, 4)
self.assertAlmostEqual(self.cycle.evap.Q, 83891.17350428084, 6)
def test_1_size_dpEvap_True(self):
self.cycle.config.dpEvap = True
self.cycle.size()
self.assertAlmostEqual(abs(self.cycle.evap.L - 0.268278920236407), 0,
2)
self.assertAlmostEqual(
(self.cycle.comp.pRatio - 10.22519893) / 10.22519893, 0, 4)
self.assertAlmostEqual(self.cycle.exp.pRatio,
(self.cycle.pEvap - 39607.4552153897) /
self.cycle.pCond, 4)
self.assertAlmostEqual(self.cycle.evap.Q, 83891.17350428084, 4)
def test_cycle_plot(self):
import os
self.cycle.sizeSetup()
self.cycle.plot(title="test_cycle_plot",
show=False,
savefig=True,
savefig_name="test_cycle_plot",
savefig_format="png",
savefig_folder="")
cwd = os.getcwd()
os.remove(cwd + "/test_cycle_plot.png")
