This application claims the priority of Chinese Patent Application No. CN20191138824.6, entitled “Simulation Method for Two-Stage Plunger Pressurized Common Rail Fuel System of Marine Low-Speed Engine” filed with the China National Intellectual Property Administration on Dec. 30, 2019, which is incorporated herein by reference in its entirety.
The disclosure relates to a simulation method for a diesel engine, in particular to a simulation method for a marine diesel engine.
Marine low-speed diesel engine has the advantages of high power and high thermal efficiency, and has become the main propulsion power unit of large ocean-going ships.
After the end of the 20th century, countries around the world have gradually increased their requirements for the emissions and performance indicators of the internal combustion engine (ICE). In order to improve the emissions indicators of the ICE, research and development of electronically controlled fuel injection systems have become an inevitable trend. The design of the low-speed engine is a comprehensive subject covering multiple systems and multiple disciplines. The working process of the low-speed engine's fuel system is a multi-physics coupling process, in which different physical fields affect each other and jointly determine the stability of the working process. The use of the computer integrated simulation technology to establish a mathematical model to conduct multi-angle research on the system performance is the focus of current research.
An objective of the disclosure is to provide a simulation method for a two-stage plunger pressurized common rail fuel system of a marine low-speed engine. This method is designed to conduct multi-angle and multi-disciplinary simulation analysis.
The objective of the disclosure is achieved as follows:
A simulation method for a two-stage plunger pressurized common rail fuel system of a marine low-speed engine, including:
(1) setting initial parameters, such as a control step Nt of the system, a total time NT (0<Nt≤NT) of a calculation process, and structure parameters and pressures of a booster unit, a high-pressure fuel pipe and a fuel injector;
(2) establishing a mathematical model of the fuel system, including a mathematical model of the fuel booster unit, a mathematical model of the high-pressure fuel pipe and a mathematical model of the fuel injector; and
(3) connecting input and output parameters of the established models to realize data transfer between the models: calculating real-time pressure changes and pressures of fuel flowing through each part of the fuel system in one step Nt, and obtaining an injection pressure at this step; performing an iterative calculation on the fuel system model in NT/Nt steps based on the status parameters in a previous step, to obtain injection pressure data for an entire working process of the fuel system.
The disclosure may further include:
1. In step (1), the initial parameters that need to be set include:
a control step Nt of the system, a total time NT (0<Nt≤NT) of a calculation process, a common rail servo oil pressure Ps, diameters D1 and D2 of large and small plungers in the booster unit, a volume Vy of a fuel booster chamber, a length L and diameter dhp of the high-pressure fuel pipe, and a volume Vf of a fuel sump and a volume Vin of a pressure chamber in the fuel injector.
2. In step (2), the established mathematical model of the fuel system includes a mathematical model of the fuel booster unit, a mathematical model of the high-pressure fuel pipe and a mathematical model of the fuel injector:
(a) the mathematical model of the fuel booster unit is specifically established as follows:
setting an electromagnetic signal I to drive a two-position three-way solenoid valve in the fuel booster unit to switch between open and close states to boost the low-pressure fuel;
where, after boosting, a fuel pressure changes to
where, ΔVz is a volume change of the fuel booster chamber, and Qout is a flow rate of fuel flowing into the high-pressure fuel pipe;
(b) by considering one-dimensional (1D) fluctuations in the high-pressure fuel pipe, the mathematical model of the high-pressure fuel pipe is specifically established as follows:
dividing a flow in the high-pressure fuel pipe according to a spatial length into sections for solving, to obtain: a forward pressure fluctuation in one control step Nt in the length of L from a length of ΔL:
a reverse pressure fluctuation from the current length of ΔL:
forward and reverse pressure fluctuations in NT/Nt steps from Nt:
Fnd(L*+ΔL)=F(L*)·e−KN′, and Rnd(L*+ΔL)=R(L*)·e−KN′;
where, K is a dissipation factor; and
obtaining flow rates at an inlet and an outlet of the high-pressure fuel pipe as follows:
v(0)=[F(0)+R(0)]/(αρ), and v(L)=[F(L)+R(L)]/(αρ);
(c) the mathematical model of the fuel injector is specifically established as follows:
calculating a fuel pressure change in the fuel sump as follows:
where, ΔVf is a volume change of the fuel sump, Qin is a flow rate of fuel flowing from the high-pressure fuel pipe into the fuel sump, and Qout is a flow rate of fuel flowing into the pressure chamber;
calculating a fuel pressure change in the pressure chamber as follows:
where, Qin is a flow rate of fuel flowing from the fuel sump into the pressure chamber, and Qout is a flow rate of fuel injected from a nozzle;
where, Ain is a flow area from the fuel sump to the pressure chamber;
where, P0 is an in-cylinder pressure, and A* is a total area of the nozzle.
3. In step (3), the connecting input and output parameters of the established models to realize data transfer between the models specifically includes:
applying
to calculate a fuel pressure change ΔPy, to obtain a real-time fuel pressure in the booster chamber:
Py=Py0+ΔPy;
applying
to calculate a fuel pressure change ΔPf, to obtain a real-time fuel pressure in the fuel sump:
Pf=Pf0+ΔPf;
calculating real-time pressure changes and pressures of fuel flowing through each part of the fuel system in one step Nt, and obtaining an injection pressure at this step; performing an iterative calculation on the fuel system model in NT/Nt steps based on the status parameters in a previous step, to obtain injection pressure data for an entire working process of the fuel system.
The disclosure has the following advantages. The disclosure provides a modeling and simulation method for a two-stage plunger pressurized common rail fuel system of a marine low-speed engine. The method of the disclosure establishes a high-precision model of the fuel system by using MATLAB simulation software. This method considers one-dimensional (1D) spatial fluctuations in the high-pressure fuel pipe, and can be used to optimize and verify the design of the common rail fuel system. In addition, this method has accurate calculation results, good practicability, and is applicable to engine models.
The disclosure is described in detail below with reference to the accompanying drawings and examples.
As shown in
Step 1, set initial parameters of a system model, including:
a control step Nt of the system, a total time NT (0<Nt≤NT) of a calculation process, a common rail servo oil pressure Ps, diameters D1 and D2 of large and small plungers in the booster unit, a volume Vy of a fuel booster chamber, a length L and diameter dhp of the high-pressure fuel pipe, a volume Vf of a fuel sump and a volume Vin of a pressure chamber in the fuel injector, a parameter of a needle valve component, and other related parameters.
Step 2: establish a mathematical model of the fuel system, including a mathematical model of the fuel booster unit, a mathematical model of the high-pressure fuel pipe and a mathematical model of the fuel injector, where
(a) the mathematical model of the fuel booster unit is specifically established as follows:
set an electromagnetic signal I to drive a two-position three-way solenoid valve in the fuel booster unit to switch between open and close states to boost the low-pressure fuel;
where, after boosting, a fuel pressure changes to
where, ΔVz is a volume change of the fuel booster chamber, and Qout is a flow rate of fuel flowing into the high-pressure fuel pipe;
ΔVz=S2·H, where, H is obtained according to a mechanical motion equation of the plunger;
(b) by considering one-dimensional (1D) fluctuations in the high-pressure fuel pipe, the mathematical model of the high-pressure fuel pipe is specifically established as follows:
divide a flow in the high-pressure fuel pipe according to a spatial length into sections for solving, to obtain: a forward pressure fluctuation in one control step Nt in the length of L from a length of ΔL:
a reverse pressure fluctuation from the current length of ΔL:
forward and reverse pressure fluctuations in NT/Nt steps from Nt:
Fnd(L*+ΔL)=F(L*)·e−KN′, and Rnd(L*+ΔL)=R(L*)·e−KN′ (4)
where, K is a dissipation factor, which is specifically calculated as follows:
assume that the flow in the pipe is a turbulent flow, and calculate a Reynolds number based on a current average flow velocity in the pipe according to the following formula:
where,
calculate a resistance coefficient λ of the fuel pipe according to a semi-empirical formula of the target fuel pipe, after obtaining the current Reynolds number; and
obtain the dissipation factor according to
obtain flow rates at an inlet and an outlet of the high-pressure fuel pipe as follows:
v(0)=[F(0)+R(0)]/(αρ), and v(L)=[F(L)+R(L)]/(αρ) (7);
where, α is a speed of sound, and ρ is a fuel density;
(c) the mathematical model of the fuel injector is specifically established as follows:
calculate a fuel pressure change in the fuel sump as follows:
where, ΔVf is a volume change of the fuel sump, Qin is a flow rate of fuel flowing from the high-pressure fuel pipe into the fuel sump, and Qout is a flow rate of fuel flowing into the pressure chamber;
calculate a fuel pressure change in the pressure chamber as follows:
where, Qin is a flow rate of fuel flowing from the fuel sump into the pressure chamber, and Qout is a flow rate of fuel injected from a nozzle;
where, Ain is a flow area from the fuel sump to the pressure chamber;
where, P0 is an in-cylinder pressure, and A* is a total area of the nozzle.
Step 3: connect input and output parameters of the established models to realize data transfer between the models:
apply
to calculate a fuel pressure change ΔPy, to obtain a real-time fuel pressure in the booster chamber:
Py=Py0+ΔPy (12)
apply
to calculate a fuel pressure change ΔPf, to obtain a real-time fuel pressure in the fuel sump:
Pf=Pf0+ΔPf (13)
calculating real-time pressure changes and pressures of fuel flowing through each part of the fuel system in one step Nt, and obtaining an injection pressure at this step; performing an iterative calculation on the fuel system model in NT/Nt steps based on the status parameters in a previous step, to obtain injection pressure data for an entire working process of the fuel system.
Assuming j is a number of iterations, then an injection pressure is as follows:
Pin(j+1)=Pin(j)+ΔPin (14)
Number | Name | Date | Kind |
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5709341 | Graves | Jan 1998 | A |
20100005872 | Vennettilli | Jan 2010 | A1 |
Number | Date | Country |
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2669172 | Dec 2013 | EP |
Number | Date | Country | |
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20210197942 A1 | Jul 2021 | US |