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flightgear/src/FDM/IO360.hxx

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// Module: 10520c.c
// Author: Phil Schubert
// Date started: 12/03/99
// Purpose: Models a Continental IO-520-M Engine
// Called by: FGSimExec
//
// Copyright (C) 1999 Philip L. Schubert (philings@ozemail.com.au)
//
// This program is free software; you can redistribute it and/or
// modify it under the terms of the GNU General Public License as
// published by the Free Software Foundation; either version 2 of the
// License, or (at your option) any later version.
//
// This program is distributed in the hope that it will be useful, but
// WITHOUT ANY WARRANTY; without even the implied warranty of
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
// General Public License for more details.
//
// You should have received a copy of the GNU General Public License
// along with this program; if not, write to the Free Software
// Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA
// 02111-1307, USA.
//
// Further information about the GNU General Public License can also
// be found on the world wide web at http://www.gnu.org.
//
// FUNCTIONAL DESCRIPTION
// ------------------------------------------------------------------------
// Models a Continental IO-520-M engine. This engine is used in Cessna
// 210, 310, Beechcraft Bonaza and Baron C55. The equations used below
// were determined by a first and second order curve fits using Excel.
// The data is from the Cessna Aircraft Corporations Engine and Flight
// Computer for C310. Part Number D3500-13
//
// ARGUMENTS
// ------------------------------------------------------------------------
//
//
// HISTORY
// ------------------------------------------------------------------------
// 12/03/99 PLS Created
// 07/03/99 PLS Added Calculation of Density, and Prop_Torque
// 07/03/99 PLS Restructered Variables to allow easier implementation
// of Classes
// 15/03/99 PLS Added Oil Pressure, Oil Temperature and CH Temp
// ------------------------------------------------------------------------
// INCLUDES
// ------------------------------------------------------------------------
#ifndef _IO360_HXX_
#define _IO360_HXX_
#define NEVS_PROP_MODEL
#ifndef NEVS_PROP_MODEL
#define PHILS_PROP_MODEL
#endif
#include <iostream.h>
#include <fstream.h>
#include <math.h>
class FGEngine {
private:
float CONVERT_HP_TO_WATTS;
float CONVERT_CUBIC_INCHES_TO_METERS_CUBED;
// Control and environment inputs
float IAS;
// 0 = Closed, 100 = Fully Open
float Throttle_Lever_Pos;
// 0 = Full Course 100 = Full Fine
float Propeller_Lever_Pos;
// 0 = Idle Cut Off 100 = Full Rich
float Mixture_Lever_Pos;
// Engine Specific Variables used by this program that have limits.
// Will be set in a parameter file to be read in to create
// and instance for each engine.
float Max_Manifold_Pressure; //will be lower than ambient pressure for a non turbo/super charged engine due to losses through the throttle. This is the sea level full throttle value.
float Min_Manifold_Pressure; //Closed throttle valueat idle - governed by the idle bypass valve
float Max_RPM;
float Min_RPM;
float Max_Fuel_Flow;
float Mag_Derate_Percent;
float MaxHP;
float Gear_Ratio;
// Initialise Engine Variables used by this instance
float Percentage_Power; // Power output as percentage of maximum power output
float Manifold_Pressure; // Inches
float RPM;
float Fuel_Flow; // lbs/hour
float Torque;
float CHT; // Cylinder head temperature
float EGT; // Exhaust gas temperature
float Mixture;
float Oil_Pressure; // PSI
float Oil_Temp; // Deg C
float HP; // Current power output in HP
float Power_SI; // Current power output in Watts
float Torque_SI; // Torque in Nm
float RPS;
float Torque_Imbalance;
float Desired_RPM; // The RPM that we wish the constant speed prop to maintain if possible
bool started; //flag to indicate the engine is running self sustaining
bool cranking; //flag to indicate the engine is being cranked
//DCL
float volumetric_efficiency;
float combustion_efficiency;
float equivalence_ratio;
float v_dot_air;
float m_dot_air;
float m_dot_fuel;
float swept_volume;
float True_Manifold_Pressure; //in Hg
float rho_air_manifold;
float R_air;
float p_amb_sea_level; // Pascals
float p_amb; // Pascals
float T_amb; // deg Kelvin
float calorific_value_fuel;
float thi_sea_level;
float delta_T_exhaust;
float displacement; // Engine displacement in cubic inches - to be read in from config file for each engine
float displacement_SI; // ditto in meters cubed
float Cp_air; // J/KgK
float Cp_fuel; // J/KgK
float heat_capacity_exhaust;
float enthalpy_exhaust;
float Percentage_of_best_power_mixture_power;
float abstract_mixture; //temporary hack
float engine_inertia; //kg.m^2
float prop_inertia; //kg.m^2
float angular_acceleration; //rad/s^2
double time_step;
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// Initialise Propellor Variables used by this instance
float FGProp1_Angular_V;
float FGProp1_Coef_Drag;
float FGProp1_Torque;
float FGProp1_Thrust;
float FGProp1_RPS;
float FGProp1_Coef_Lift;
float Alpha1;
float FGProp1_Blade_Angle;
float FGProp_Fine_Pitch_Stop;
#ifdef NEVS_PROP_MODEL
//Extra Propellor variables used by Nev's prop model
float prop_fudge_factor;
float prop_torque; //Nm
float prop_thrust;
float blade_length;
float allowance_for_spinner;
float num_elements;
float distance;
float number_of_blades;
float forward_velocity;
float angular_velocity_SI;
float element;
float element_drag;
float element_lift;
float element_torque;
float rho_air;
float prop_power_consumed_SI;
float prop_power_consumed_HP;
float theta[6]; //prop angle of each element
#endif // NEVS_PROP_MODEL
// Other internal values
float Rho;
// Calculate Engine RPM based on Propellor Lever Position
float Calc_Engine_RPM (float Position);
// Calculate combustion efficiency based on equivalence ratio
float Lookup_Combustion_Efficiency(float thi_actual);
// Calculate exhaust gas temperature rise
float Calculate_Delta_T_Exhaust(void);
public:
ofstream outfile;
//constructor
FGEngine() {
// outfile.open("FGEngine.dat", ios::out|ios::trunc);
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}
//destructor
~FGEngine() {
// outfile.close();
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}
// set initial default values
void init(double dt);
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// update the engine model based on current control positions
void update();
inline void set_IAS( float value ) { IAS = value; }
inline void set_Throttle_Lever_Pos( float value ) {
Throttle_Lever_Pos = value;
}
inline void set_Propeller_Lever_Pos( float value ) {
Propeller_Lever_Pos = value;
}
inline void set_Mixture_Lever_Pos( float value ) {
Mixture_Lever_Pos = value;
}
// accessors
inline float get_RPM() const { return RPM; }
inline float get_Manifold_Pressure() const { return Manifold_Pressure; }
inline float get_FGProp1_Thrust() const { return FGProp1_Thrust; }
inline float get_FGProp1_Blade_Angle() const { return FGProp1_Blade_Angle; }
inline float get_Rho() const { return Rho; }
inline float get_MaxHP() const { return MaxHP; }
inline float get_Percentage_Power() const { return Percentage_Power; }
inline float get_EGT() const { return EGT; }
inline float get_prop_thrust_SI() const { return prop_thrust; }
};
#endif // _10520D_HXX_