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compressor.mso @ 991

Last change on this file since 991 was 864, checked in by gerson bicca, 14 years ago
revised compressor model
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Rev	Line
[739]	1	#*-------------------------------------------------------------------
	2	* EMSO Model Library (EML) Copyright (C) 2004 - 2007 ALSOC.
	3	*
	4	* This LIBRARY is free software; you can distribute it and/or modify
	5	* it under the therms of the ALSOC FREE LICENSE as available at
	6	* http://www.enq.ufrgs.br/alsoc.
	7	*
	8	* EMSO Copyright (C) 2004 - 2007 ALSOC, original code
	9	* from http://www.rps.eng.br Copyright (C) 2002-2004.
	10	* All rights reserved.
	11	*
	12	* EMSO is distributed under the therms of the ALSOC LICENSE as
	13	* available at http://www.enq.ufrgs.br/alsoc.
	14	*
	15	*----------------------------------------------------------------------
	16	* Author: Marcos L. Alencastro, Estefane S. Horn (Revised Gerson B. Bicca)
	17	* $Id: compressor.mso 864 2009-10-19 19:41:09Z bicca $
	18	--------------------------------------------------------------------#
	19
	20	using "streams";
	21
	22	Model centrifugal_compressor
	23
	24	ATTRIBUTES
	25	Pallete = true;
	26	Icon = "icon/CentrifugalCompressor";
	27	Brief = "Model of a centrifugal compressor.";
	28	Info =
	29	"To be documented
	30
	31	== References ==
	32
	33	[1] GPSA, 1979, Engineering Data Book, Chapter 4, 5-9 - 5-10.
	34
	35	[2] Bloch, Heinz P., A Practical Guide to Compressor Technology, John Wiley & Sons, Incorporate, 2006.
	36
	37	[3] Mark R. Sandberg, Equation Of State Influences On Compressor Performance Determination,PROCEEDINGS OF THE THIRTY-FOURTH TURBOMACHINERY SYMPOSIUM, 2005.";
	38
	39	PARAMETERS
	40
	41	outer PP as Plugin (Brief = "External Physical Properties", Type="PP");
	42	outer NComp as Integer (Brief = "Number of chemical components", Lower = 1);
	43	Rgas as positive (Brief = "Constant of Gases", Unit= 'kJ/kmol/K', Default = 8.31451,Hidden=true);
[864]	44	Mw(NComp) as molweight (Brief = "Molar Weight",Hidden=true);
	45	CompressorOperation as Switcher (Brief = "Compressor Operation Model",Valid=["Polytropic","Isentropic"], Default="Isentropic");
	46	Method as Switcher (Brief = "Method of Calculation",Valid=["GPSA Method","ASME Method"], Default="GPSA Method");
[739]	47
	48	VARIABLES
	49
	50	Pratio as positive (Brief = "Pressure Ratio", Lower = 1E-6, Symbol ="P_{ratio}");
	51	Pdrop as press_delta (Brief = "Pressure Drop", DisplayUnit = 'kPa', Symbol ="\Delta P");
	52	Pincrease as press_delta (Brief = "Pressure Increase",Lower = 0, DisplayUnit = 'kPa', Symbol ="P_{incr}");
	53	EfficiencyOperation as positive (Brief = "Compressor efficiency - Polytropic or Isentropic (See Compressor Type)",Lower=1E-3,Upper=1);
	54	MechanicalEff as positive (Brief = "Mechanical efficiency",Lower=1E-3,Upper=1);
	55	PowerLoss as power (Brief = "Power Losses");
	56	Head as energy_mass (Brief = "Actual Head", Protected=true);
	57	HeadIsentropic as energy_mass (Brief = "Isentropic Head", Protected=true);
	58	HeadPolytropic as energy_mass (Brief = "Polytropic Head", Protected=true);
	59	HeadCorrection as positive (Brief = "Schultz Polytropic Head Correction", Protected=true);
	60
	61	FluidPower as power (Brief = "Fluid Power", Protected=true);
	62	BrakePower as power (Brief = "Brake Power", Protected=true);
	63
	64	PolyCoeff as positive (Brief = "Polytropic Coefficient", Lower=0.2,Protected=true);
	65	IseCoeff as positive (Brief = "Isentropic Coefficient", Lower=0.2,Protected=true);
	66	PolytropicEff as positive (Brief = "Polytropic efficiency",Lower=1E-3,Upper=1,Protected=true);
	67	IsentropicEff as positive (Brief = "Isentropic efficiency",Lower=1E-3,Upper=1,Protected=true);
	68
	69	Tisentropic as temperature (Brief = "Isentropic Temperature",Protected=true);
	70	hise as enth_mol (Brief = "Enthalpy at constant entropy",Hidden=true);
	71	Mwm as molweight (Brief = "Mixture Molar Weight",Hidden=true);
	72	rho_in as dens_mass (Brief = "Mass Density at inlet conditions", Lower = 1E-6, Protected=true);
	73	rho_out as dens_mass (Brief = "Mass Density at outlet conditions", Lower = 1E-6, Protected=true);
	74	rho_ise as dens_mass (Brief = "Mass Density at isentropic conditions", Lower = 1E-6, Hidden=true);
	75	Zfac_in as fraction (Brief = "Compressibility factor at inlet", Lower = 1E-3, Protected=true);
	76	Zfac_out as fraction (Brief = "Compressibility factor at outlet", Lower = 1E-3, Protected=true);
	77
	78	in Inlet as stream (Brief = "Inlet stream", PosX=0.16, PosY=1, Symbol="_{in}");
	79	out Outlet as streamPH (Brief = "Outlet stream", PosX=0.87, PosY=0.0, Symbol="_{out}");
	80
	81	in WorkIn as power (Brief = "Work Inlet", PosX=0, PosY=0.45, Protected=true);
	82
	83	SET
	84
	85	Mw = PP.MolecularWeight();
	86
	87	Rgas = 8.31451*'kJ/kmol/K';
	88
	89	EQUATIONS
	90
	91	"Overall Molar Balance"
	92	Outlet.F = Inlet.F;
	93
	94	"Component Molar Balance"
	95	Outlet.z = Inlet.z;
	96
	97	"Average Molecular Weight"
	98	Mwm = sum(Mw*Inlet.z);
	99
	100	"Pressure Ratio"
	101	Outlet.P = Inlet.P * Pratio;
	102
	103	"Pressure Drop"
	104	Outlet.P = Inlet.P - Pdrop;
	105
	106	"Pressure Increase"
	107	Outlet.P = Inlet.P + Pincrease;
	108
	109	"Mass Density at inlet conditions"
	110	rho_in = PP.VapourDensity(Inlet.T, Inlet.P, Inlet.z);
	111
	112	"Mass Density at outlet conditions"
	113	rho_out= PP.VapourDensity(Outlet.T, Outlet.P, Outlet.z);
	114
	115	"Mass Density at isentropic conditions"
	116	rho_ise= PP.VapourDensity(Tisentropic, Outlet.P, Outlet.z);
	117
	118	"Enthalpy at isentropic conditions"
	119	hise = PP.VapourEnthalpy(Tisentropic, Outlet.P, Outlet.z);
	120
	121	"Compressibility factor at Inlet Conditions"
	122	Zfac_in = PP.VapourCompressibilityFactor(Inlet.T,Inlet.P,Inlet.z);
	123
	124	"Compressibility factor at Outlet Conditions"
	125	Zfac_out = PP.VapourCompressibilityFactor(Outlet.T,Outlet.P,Outlet.z);
	126
	127	"Isentropic Efficiency"
	128	IsentropicEff*(Outlet.h-Inlet.h) = (hise-Inlet.h);
	129
	130	"Actual Head"
	131	Head*Mwm = (Outlet.h-Inlet.h);
	132
	133	"Isentropic Outlet Temperature"
	134	PP.VapourEntropy(Tisentropic, Outlet.P, Outlet.z) = PP.VapourEntropy(Inlet.T, Inlet.P, Inlet.z);
	135
	136	"Brake Power"
	137	BrakePower = -WorkIn;
	138
	139	"Brake Power"
	140	BrakePower*MechanicalEff = FluidPower;
	141
	142	"Power Loss"
	143	PowerLoss = BrakePower - FluidPower;
	144
	145	"Polytropic-Isentropic Relation"
	146	PolytropicEffHeadIsentropic = HeadPolytropicIsentropicEff;
	147
	148	"Fluid Power"
	149	FluidPower = HeadMwmInlet.F;
	150
[864]	151	switch CompressorOperation
[739]	152
[864]	153	case "Isentropic":
	154
	155	switch Method
	156
	157	case "ASME Method":
[739]	158
	159	"Efficiency"
	160	EfficiencyOperation = IsentropicEff;
	161
[864]	162	"Isentropic Coefficient"
	163	IseCoeff*ln(rho_ise/rho_in) = ln(Outlet.P/Inlet.P);
	164
	165	"Polytropic Coefficient"
	166	PolyCoeff*ln(rho_out/rho_in) = ln(Outlet.P/Inlet.P);
	167
	168	"Isentropic Head"
	169	HeadIsentropicrho_in = (IseCoeff/(IseCoeff-1.001))Inlet.PHeadCorrection((Pratio)^((IseCoeff-1.001)/IseCoeff) - 1);
	170
	171	"Polytropic Head"
	172	HeadPolytropicrho_in = (PolyCoeff/(PolyCoeff-1.001))Inlet.PHeadCorrection((Pratio)^((PolyCoeff-1.001)/PolyCoeff) - 1);
	173
	174	"Schultz Polytropic Head Correction"
	175	HeadCorrectionMwm(IseCoeff/(IseCoeff-1.001))*(Outlet.P/rho_ise -Inlet.P/rho_in) = (hise-Inlet.h);
	176
	177	case "GPSA Method":
	178
	179	"Efficiency"
	180	EfficiencyOperation = IsentropicEff;
	181
[739]	182	"Polytropic Efficiency"
	183	PolytropicEffIseCoeff(PolyCoeff-1) = PolyCoeff*(IseCoeff-1);
	184
	185	"Isentropic Coefficient"
	186	HeadIsentropicMwm((IseCoeff-1.001)/IseCoeff) = (0.5Zfac_in+0.5Zfac_out)RgasInlet.T*((Pratio)^((IseCoeff-1.001)/IseCoeff) - 1);
	187
	188	"Polytropic Coefficient"
	189	HeadPolytropicMwm((PolyCoeff-1.001)/PolyCoeff) = (0.5Zfac_in+0.5Zfac_out)RgasInlet.T*((Pratio)^((PolyCoeff-1.001)/PolyCoeff) - 1);
	190
	191	"Head Correction"
	192	HeadCorrection =1;
	193
	194	"Isentropic Head"
	195	HeadIsentropic = Head*IsentropicEff;
	196
[864]	197	end
	198
	199	case "Polytropic":
	200
	201	switch Method
	202
	203	case "GPSA Method":
	204
[739]	205	"Efficiency"
	206	EfficiencyOperation = PolytropicEff;
	207
	208	"Polytropic Efficiency"
	209	PolytropicEffIseCoeff(PolyCoeff-1) = PolyCoeff*(IseCoeff-1);
	210
	211	"Isentropic Coefficient"
	212	HeadIsentropicMwm((IseCoeff-1.001)/IseCoeff) = (0.5Zfac_in+0.5Zfac_out)RgasInlet.T*((Pratio)^((IseCoeff-1.001)/IseCoeff) - 1);
	213
	214	"Polytropic Coefficient"
	215	HeadPolytropicMwm((PolyCoeff-1.001)/PolyCoeff) = (0.5Zfac_in+0.5Zfac_out)RgasInlet.T*((Pratio)^((PolyCoeff-1.001)/PolyCoeff) - 1);
	216
	217	"Head Correction"
	218	HeadCorrection =1;
	219
	220	"Isentropic Head"
	221	HeadIsentropic = Head*IsentropicEff;
	222
[864]	223	case "ASME Method":
[739]	224
	225	"Efficiency"
	226	EfficiencyOperation = PolytropicEff;
	227
	228	"Isentropic Coefficient"
	229	IseCoeff*ln(rho_ise/rho_in) = ln(Outlet.P/Inlet.P);
	230
	231	"Polytropic Coefficient"
	232	PolyCoeff*ln(rho_out/rho_in) = ln(Outlet.P/Inlet.P);
	233
	234	"Isentropic Head"
	235	HeadIsentropicrho_in = (IseCoeff/(IseCoeff-1.001))Inlet.PHeadCorrection((Pratio)^((IseCoeff-1.001)/IseCoeff) - 1);
	236
	237	"Polytropic Head"
	238	HeadPolytropicrho_in = (PolyCoeff/(PolyCoeff-1.001))Inlet.PHeadCorrection((Pratio)^((PolyCoeff-1.001)/PolyCoeff) - 1);
	239
	240	"Schultz Polytropic Head Correction"
	241	HeadCorrectionMwm(IseCoeff/(IseCoeff-1.001))*(Outlet.P/rho_ise -Inlet.P/rho_in) = (hise-Inlet.h);
	242	end
	243
	244	end
[864]	245
	246	end

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