CN101532441A - Control method of idling speed double closed-loop of gaseous propellant engine - Google Patents

Abstract

The invention relates to a control method of idling speed stability of a gaseous propellant engine for automobiles, belonging to the field of internal-combustion engine electronic control. The gaseous propellant engine needs to operate under relatively stable rotating speed in case of idling operation and the idling speed is as low as possible so as to reduce fuel consumption; however, much too low idling speed is prone to facilitate the engine to tremendously wobble. In the invention, idling speed of the gaseous propellant engine is taken as a control objective, a double closed-loop control algorithm is adopted, that is, closed-loop control is carried out on natural gas injection pulse width and bypass air input respectively by PID algorithm; an idling speed double closed-loop test snoopware is adopted to carry out real-time monitoring on the natural gas engine, so as to seek the optimal PID parameter matching and obtain stable idling speed, as a result, automobiles powered by natural gas can be provided with comfortable driving environment in case of idling operation.

Description

Control method of idling speed double closed-loop of gaseous propellant engine

Technical field

The present invention relates to a kind of controlling method of gaseous propellant engine idling speed, be mainly used in the stability of the idling operation of control vehicular gaseous propellant engine, thereby reduce the idling speed undulate quantity of gaseous propellant engine, thereby obtain more stable idling speed.Belong to the internal-combustion engine field of electric control.

Background technique

The idling operation of motor is meant that gas pedal is decontroled fully, external inactivity is exported and can keep minimum stable engine speed, keep the steady running condition that motor does not stop working.Idling operation is one of most important operating conditions of motor, and especially along with the continuous increase of automobile pollution, urban traffic conditions can not get timely improvement, and the working time that motor is under the idling operation is more and more.Therefore, the control to idling operation seems particularly important.

The operation of engine idling condition is very complicated, has characteristics such as non-linear significantly, time variation and uncertainty.When motor was worked under idling operation, its rotating speed mainly was subjected to the influence of ignition advance angle, bypath air air inflow and fuel feed.In traditional idle speed control process, mainly adopt single closed loop control algorithm, promptly only the bypath air air inflow is controlled in real time.The size of the air ventilation sectional area by regulating the bypass air flue, and then change the charge flow rate of bypath air, thus finish closed loop control process to idling speed.Adopt this kind control algorithm, make the delivery volume of fuel not change along with the variation of idling operation, therefore under the situation of idling operation sudden change, the fluctuation of speed amount of motor can increase, even make motor that more violent shake take place, influence the travelling comfort of automobile.

So-called PID (Proportion-Integral-Derivative) control algorithm is a kind of very widely control algorithm of present industrial application, and the increment type PID control algorithm is to be under the jurisdiction of a kind of in numerous pid algorithms, because of advantages such as its algorithm is simple, reliable, amount of calculation is little have obtained using widely.The calculating formula of increment type PID control algorithm is as follows:

ΔH _p＝K _p×[e _n-e _n-1]

ΔH _i＝K _i×e _n

ΔH _d＝K _d×[e _n-2×e _n-1+e _n-2]

ΔH＝ΔH _p+ΔH _i+ΔH _d

E wherein _n=m-n

Annotate: m is the idling rotating speed of target

N is an actual engine speed

K _pBe the proportional coefficient

K _iBe integral item coefficient

K _dBe the differential term coefficient

e _nDeviation for this rotating speed of target and actual speed

e _N-1Deviation for last time rotating speed of target and actual speed

e _N-2Deviation for rotating speed of target and actual speed of last last time

In the formula, Δ H is a total variation; Δ H _p, Δ H _i, Δ H _dBe respectively the caused variable quantity of proportional, integral and differential term.

Summary of the invention

The invention provides a kind of idling speed controlling method of new gaseous propellant engine, promptly two closed loop control methods, this method can reduce the fluctuation of speed amount of gaseous propellant engine under idling operation, thereby make gaseous propellant engine obtain to make gaseous fuel automobile under idling operation, can have travelling comfort preferably simultaneously than stable rotating speed output.

The control method of idling speed double closed-loop of the gaseous propellant engine among the present invention is based on to be realized on the basis of classical pid control algorithm.So-called pair of closed loop control method adopts two cover increment type PID control algorithms exactly, and the injection pulse width and the bypath air air inflow of the gaseous fuel under the idling operation are carried out PID closed loop control, both mutual noninterferences, separate coming respectively.

The concrete technological scheme that the present invention adopts is as follows: by the tach signal of speed probe output motor, and tach signal is input among the ECU (Electrical Control Unit) ECU, catch then and calculate, draw current actual engine speed, actual engine speed and predefined rotating speed of target compare, and obtain the rotating speed deviation.Calculate the total variation of gaseous fuel injection pulse width and the variable quantity of the stepper motor action step-length of controlling the bypath air air inflow respectively according to closed loop control method, thereby draw required gaseous fuel injection pulse width of next operating point and stepper motor action step-length, finish two closed loop controls rotating speed.

The closed loop control method of described gaseous fuel injection pulse width is as follows: the total variation Δ H_Gas that calculates the gaseous fuel injection pulse width earlier according to following formula:

ΔH _p_Gas＝K _p_Gas×[e _n-e _n-1]

ΔH _i_Gas＝K _i_Gas×e _n

ΔH _d_Gas＝K _d_Gas×[e _n-2×e _n-1+e _n-2]

ΔH_Gas＝ΔH _p_Gas+ΔH _i_Gas+ΔH _d_Gas

In the following formula: e _n=m-n

M is the idling rotating speed of target

N is an actual engine speed

e _nDeviation for this rotating speed of target and actual speed

e _N-1Deviation for last time rotating speed of target and actual speed

e _N-2Deviation for rotating speed of target and actual speed of last last time

K _p_ Gas is the proportional coefficient

K _i_ Gas is an integral item coefficient

K _d_ Gas is the differential term coefficient

Δ H _p_ Gas is the variable quantity of the caused gaseous fuel injection pulse width of proportional

Δ H _i_ Gas is the variable quantity of the caused gaseous fuel injection pulse width of integral

Δ H _d_ Gas is the variable quantity of the caused gaseous fuel injection pulse width of differential term

Δ H_Gas is a gaseous fuel injection pulse width total variation

Control the required gaseous fuel injection pulse width of next operating point according to gaseous fuel injection pulse width total variation Δ H_Gas again, realize closed loop control rotating speed.

The closed loop control method of described bypath air air inflow is as follows: calculate stepper motor action step-length total variation Δ H_Air according to following formula earlier:

ΔH _p_Air＝K _p_Air×[e _n-e _n-1]

ΔH _i_Air＝K _i_Air×e _n

ΔH _d_Air＝K _d_Air×[e _n-2×e _n-1+e _n-2]

ΔH_Air＝ΔH _p_Air+ΔH _i_Air+ΔH _d_Air

In the following formula: e _n=m-n

M is the idling rotating speed of target

N is an actual engine speed

e _nDeviation for this rotating speed of target and actual speed

e _N-1Deviation for last time rotating speed of target and actual speed

e _N-2Deviation for rotating speed of target and actual speed of last last time.

K _p_ Air is the proportional coefficient

K _i_ Air is an integral item coefficient

K _d_ Air is the differential term coefficient

Δ H _p_ Air is that the caused stepper motor action of proportional step-size amounts changes

Δ H _i_ Air is that the caused stepper motor action of integral step-size amounts changes

Δ H _d_ Air is that the caused stepper motor action of differential term step-size amounts changes

Δ H_Air is a stepper motor action step-length total variation

According to stepper motor action step-length total variation Δ H_Air control step motor action, realize closed loop control again to rotating speed.

This controlling method can be applied on the gaseous propellant engines such as natural gas engine, LPG (liquefied petroleum gas (LPG)) motor, hydrogen engine.

Controlling method among the present invention can reduce the fluctuation of speed amount of gaseous propellant engine under idling operation, thereby makes gaseous propellant engine obtain to make gaseous fuel automobile can have travelling comfort preferably simultaneously under idling operation than stable rotating speed output.

Description of drawings

The two loop control theory figure of Fig. 1 idling

The two closed test monitoring interfaces of Fig. 2 idling

The fluctuation of speed figure contrast when rotating speed of target is 1200rpm of the two closed loops of Fig. 3 idling and single closed loop

Two closed loops of Fig. 4 and the comparison of test results of single closed loop when rotating speed of target is 1200rpm

The fluctuation of speed figure contrast when rotating speed of target is 850rpm of the two closed loops of Fig. 5 idling and single closed loop

Two closed loops of Fig. 6 and the comparison of test results of single closed loop when rotating speed of target is 850rpm

Embodiment

The invention will be further described below in conjunction with accompanying drawing:

Present embodiment adopts two cover increment type PID control algorithms, and the injection pulse width and the bypath air air inflow of the gaseous fuel under the idling operation are carried out the PID closed loop control respectively, both mutual noninterferences, and separate coming, the control principle figure of two closed loops is as shown in Figure 1.In the operation process of motor, certainly lead to certain rotating speed deviation between rotating speed of target and the actual speed, at this moment, gaseous fuel injection pulse width and bypath air air inflow basis pid algorithm separately, can draw adjustment amount separately, and control cycle also can adjust by the parameter setting, thereby finishes two closed loop controls.Adopt this kind controlling method can make the injection pulse width of gaseous fuel and bypath air air inflow carry out the self adaption adjustment according to the idling speed deviation separately, under the situation of motor in idling operation sudden change, when especially load changes, this moment, the injection pulse width and the bypath air air inflow of gaseous fuel can adjust in time, and then make the fluctuation of speed variable quantity of motor as far as possible little, thereby can export comparatively stable rotating speed, make gaseous fuel automobile obtain travelling comfort preferably.

The controlling method of gaseous fuel injection pulse width is as follows:

ΔH _p_Gas＝K _p_Gas×[e _n-e _n-1]

ΔH _i_Gas＝K _i_Gas×en

ΔH _d_Gas＝K _d_Gas×[e _n-2×e _n-1+e _n-2]

ΔH_Gas＝ΔH _p_Gas+ΔH _i_Gas+ΔH _d_Gas

The controlling method of bypath air air inflow is as follows:

ΔH _p_Air＝K _p_Air×[e _n-e _n-1]

ΔH _i_Air＝K _i_Air×e _n

ΔH _d_Air＝K _d_Air×[e _n-2×e _n-1+e _n-2]

ΔH_Air＝ΔH _p_Air+ΔH _i_Air+ΔH _d_Air

E wherein _n=m-n

Annotate: m is the idling rotating speed of target

N is an actual engine speed

K _p_ Gas is the proportional coefficient, and its span is 0.01～0.26

K _i_ Gas is an integral item coefficient, and its span is 0.01～0.12

K _d_ Gas is the differential term coefficient, and its span is 0～0.05

K _p_ Air is the proportional coefficient, and its span is 0.01～0.58

K _i_ Air is an integral item coefficient, and its span is 0.01～0.28

K _d_ Air is the differential term coefficient, and its span is 0～0.04

e _nDeviation for this rotating speed of target and actual speed

e _N-1Deviation for last time rotating speed of target and actual speed

e _N-2Deviation for rotating speed of target and actual speed of last last time

In the formula, Δ H_Gas and Δ H_Air are gaseous fuel injection pulse width and stepper motor action step-length total variation; Δ H _p_ Gas, Δ H _i_ Gas, Δ H _d_ Gas is respectively the variable quantity of the caused gaseous fuel injection pulse width of proportional, integral and differential term; Δ H _p_ Air, Δ H _p_ Air, Δ H _d_ Air is respectively the caused stepper motor action of proportional, integral and differential term step-size amounts to be changed.In addition, gaseous fuel injection pulse width and stepper motor move total step-size amounts all separately control cycle, is respectively T_Gas and T_Air, and its span is as follows respectively:

The span of T_Gas is 16～80

The span of T_Air is 8～16

Wherein, when T_Air or T_Gas were 4, the cycle of representative was a work cycle of motor, and the rest may be inferred; Above parameter range all is to be to obtain on the JL465Q5 natural gas engine test-bed in model.

Idling double closed-loop control system in the present embodiment is to have carried out experimental study on the JL465Q5 natural gas engine in the model after the repacking, and it mainly is made up of hall-effect speed sensor, ECU (Electrical Control Unit) ECU, natural gas injection valve, spark coil, stepper motor etc.Wherein hall-effect speed sensor is positioned at distributor, is responsible for the tach signal of output natural gas engine, and signal type is the square signal of standard; The natural gas injection valve mainly is responsible for the fuel supply of control natural gas engine; Required high-tension electricity when spark coil is responsible for producing the mixed gas ignition; Stepper motor is responsible for controlling the bypath air air inflow.

For the ease of verifying the feasibility of two closed loop control methods, developed the two closed test monitoring softwares of natural gas engine idling with Visual Basic 6.0, use this software to carry out real-time two closed loop controls to the idling speed of natural gas engine.This software is by the RS-232 serial communication between PC and the ECU (Electrical Control Unit) ECU, ignition advance angle, idling rotating speed of target in can online real time modifying ECU (Electrical Control Unit) ECU and influence the natural gas injection pulsewidth and the parameters such as two pid control parameters of bypath air air inflow, the pid parameter of being convenient to carry out is separately adjusted.

After the natural gas engine entry into service, ECU (Electrical Control Unit) ECU according to each road sensor acquisition of motor to signal judge motor present located state.When if motor is in idling operation, the signal that collects by cooling-water temperature sensor then, determine the rotating speed of target of required setting under the engine idling condition, tach signal and seizure by Hall transducer output motor, thereby calculate the rotating speed deviation, when the absolute value of deviation is not more than 5rpm, then think the natural gas engine running steadily, this moment, stepper motor kept the original position transfixion; Otherwise draw comparatively desirable stepper motor action step-length according to the increment type PID control algorithm, the direction of action of stepper motor also can draw by the increment type PID control algorithm.Its deterministic process is as follows: when the Δ H_Air that calculates is positive number, then should improve engine speed this moment, promptly should strengthen the air inlet circulation area of bypass air flue, so answer the valve vertebra retraction of control step motor, the step-size amounts of concrete action is the absolute value of Δ H_Air; When the Δ H_Air that calculates is negative, then should reduce engine speed this moment, promptly should reduce the air inlet circulation area of bypass air flue, so answer the valve vertebra of control step motor to stretch out, the step-size amounts of concrete action is the absolute value of Δ H_Air; When the Δ H_Air that calculates was zero, then stepper motor kept original position static.Meanwhile, the natural gas injection pulsewidth is the real time altering along with the variation of rotating speed deviation also, when the Δ H_Gas that calculates is positive number, then should improve engine speed this moment, promptly increases the natural gas injection pulsewidth; When the Δ H_Gas that calculates is negative, then should reduce engine speed this moment, promptly reduce the natural gas injection pulsewidth; When the Δ H_Gas that calculates is zero, then keep the natural gas injection pulsewidth constant.In the pid algorithm of control natural gas injection pulsewidth because the natural gas injection pulsewidth is bigger to the undulate quantity influence of idling speed, therefore its adjustment amount is limited, promptly when the Δ H_Gas that calculates greater than 20 the time, its automatic value is 20; And the control cycle of natural gas injection pulsewidth and bypath air air inflow is separate, and generally speaking, the control cycle of natural gas injection pulsewidth is the multiple of bypath air air inflow control cycle.

In the process of the test, control by the two closed test monitoring interfaces of natural gas engine idling shown in Figure 2, it can influence natural gas injection pulsewidth and bypath air air inflow pid control parameter separately by online real time modifying, carry out the experimental study of different condition, thereby seek out optimum pid control parameter coupling, thereby obtain good test effect.Purpose by this control is exactly to make the actual speed of natural gas engine gradually to the rotating speed of target convergence, and fluctuates in the as far as possible little scope near rotating speed of target, thereby makes the natural gas engine running steadily.

On the basis of this control strategy, carried out comparative experimental research, and the idling rotating speed of target is set at 1200rpm and 850rpm respectively, carried out the comparative experimental research of single closed loop and two closed loops.So-called single closed loop is exactly only the bypath air air inflow to be carried out PID control; And two closed loops are on the basis of single closed loop control, have increased the PID closed loop control to the natural gas injection pulsewidth, thus the comparative trial of finishing.

The processing method of test data has adopted the computational methods of mean value and mean square deviation in the mathematical statistics.In the numerical characteristic of stochastic variable, except considering its mean value, also to consider the average departure degree of its value deviation average.Its formula is as follows:

Mean value: $\stackrel{\‾}{X}=\frac{1}{n}\underset{i=1}{\overset{n}{\mathrm{\Σ}}}{X}_i$

Mean square deviation: $S=\sqrt{\frac{1}{n-1}\underset{i=1}{\overset{n}{\mathrm{\Σ}}}{(X_i-\stackrel{\‾}{X})}^2}$

Wherein, mean value has reflected the information of sample data ensemble average, and mean square deviation has reflected the information of sample data population variance.The engine speed acquisition system can 900 rotary speed data points of disposable collection, it is the rotary speed information that engine crankshaft rotation 450 is changeed, when analyzing at idling speed, filter out 900 maximum value and minimum value in the data point, thereby obtained the maximum (top) speed deviation of motor in continuous operation 450 is changeed, thereby researched and analysed.

(1) rotating speed of target is 1200rpm

Carrying out rotating speed of target when being the single closed loop control test of the idling of 1200rpm, can learn by test result in the past, when the proportional COEFFICIENT K of control bypath air air inflow _p_ Air is 0.09, integral item coefficient K _i_ Air is 0.03, the differential term COEFFICIENT K _d_ Air is 0.01, control cycle T_Air is two work cycle of motor, and the natural gas injection pulsewidth is 130/4.16ms, and when ignition advance angle was 28 ℃ of A, the idling speed of the natural gas engine that obtains was more stable.Therefore, on the basis of pid control parameter that does not change the bypath air air inflow and ignition advance angle, increase PID control, thereby obtain a series of test result, specifically as shown in Figure 3 and Figure 4 the natural gas injection pulsewidth.

From Fig. 4, can learn, get fixed value and only the bypath air air inflow is carried out PID when control in the natural gas injection pulsewidth, continuous acquisition to 900 mean square deviations that rotary speed data point drew be 13.53rpm, the maximum (top) speed difference is 85rpm, the engine cooling water temperature of this moment is 5l.3 ℃, oil temperature is 51.1 ℃, and fluctuation of speed situation is shown in the D figure among Fig. 3.On the basis of the single closed loop control parameter constant of the idling of adhering to the bypath air air inflow, increased PID control, thereby carried out the control test of the two closed loops of idling at the natural gas injection pulsewidth.Proportional COEFFICIENT K when control natural gas injection pulsewidth _p_ Gas is 0.14, integral item coefficient K _i_ Gas is 0.10, the differential term COEFFICIENT K _d_ Gas is 0.02, when control cycle T_Gas is 16 work cycle of motor, this moment continuous acquisition to the mean square deviation of 900 rotary speed data points be 8.41rpm, and the maximum (top) speed difference is 47rpm, the engine cooling water temperature of this moment is 69.8 ℃, oil temperature is 67.1 ℃, specifically shown in the A figure among Fig. 3; Proportional COEFFICIENT K when control natural gas injection pulsewidth _p_ Gas is 0.20, integral item coefficient K _i_ Gas is 0.10, the differential term COEFFICIENT K _d_ Gas is 0, when control cycle T_Gas is 16 work cycle of motor, this moment continuous acquisition to the mean square deviation of 900 rotary speed data points be 8.08rpm, and the maximum (top) speed difference is 47rpm, the engine cooling water temperature of this moment is 67.1 ℃, oil temperature is 65.7 ℃, specifically shown in the C figure among Fig. 3; Proportional COEFFICIENT K when control natural gas injection pulsewidth _p_ Gas is 0.14, integral item coefficient K _i_ Gas is 0.10, the differential term COEFFICIENT K _d_ Gas is 0.01, when control cycle T_Gas is 16 work cycle of motor, this moment, the mean square deviation of 900 rotary speed data points that continuous acquisition arrives only was 7.47rpm, and the maximum (top) speed difference only is 45rpm, the engine cooling water temperature of this moment is 46.3 ℃, oil temperature is 44.1 ℃, specifically shown in the B figure among Fig. 3.

Can draw from test result, when rotating speed of target is 1200rpm, the control effect that is better than the single closed loop of idling based on the two closed loop control test effects of the idling of natural gas injection pulsewidth and bypath air air inflow, the fluctuation of speed amount that obtains is littler, can obviously draw this conclusion in the idling speed variation diagram from Fig. 3.Passable thus draws, and the two closed loop controls of idling can reduce the idling speed undulate quantity of natural gas engine during for 1200rpm effectively at rotating speed of target, make its working state more stable.

(2) rotating speed of target is 850rpm

When the single closed loop control of the idling of carrying out 850rpm is tested, can learn from test result in the past, when the proportional COEFFICIENT K of control bypath air air inflow _p_ Air is 0.09, integral item coefficient K _i_ Air is 0.03, the differential term COEFFICIENT K _d_ Air is 0.01, control cycle T_Air is two work cycle of motor, and the natural gas injection pulsewidth is 110/3.52ms, and when ignition advance angle was 28 ℃ of A, the engine idle rotating speed that obtains was more stable.Therefore, on the basis of pid control parameter that does not change the bypath air air inflow and ignition advance angle, increase PID control, thereby obtain a series of test result, specifically as shown in Figure 5 and Figure 6 the natural gas injection pulsewidth.From Fig. 6, can learn, get fixed value and only the bypath air air inflow is carried out PID when control, carry out the collection of two groups of rotary speed datas in the natural gas injection pulsewidth.Wherein the battery of tests result for continuous acquisition to 900 mean square deviations that rotary speed data point drew be 8.16rpm, the maximum (top) speed difference is respectively 47rpm, the engine cooling water temperature of this moment is 71.4 ℃, and oil temperature is 65.2 ℃, and fluctuation of speed situation is shown in the E figure among Fig. 5; Other one group of resulting rotating speed mean square deviation is 8.63rpm, the maximum (top) speed difference is 50rpm, the engine cooling water temperature of this moment is 75 ℃, oil temperature is 67.7 ℃, fluctuation of speed situation is shown in the F figure among Fig. 5, can learn that from these two groups of test datas this moment, the idling speed undulate quantity of motor was less, the control effect is more satisfactory.On the basis of the single closed loop control parameter constant of the idling of adhering to the bypath air air inflow, increased PID control, thereby carried out the control test of the two closed loops of idling at the natural gas injection pulsewidth.The proportional COEFFICIENT K of control natural gas injection pulsewidth _p_ Gas is 0.15, integral item coefficient K _i_ Gas is 0.08, the differential term COEFFICIENT K _d_ Gas is 0, when control cycle T_Gas is 16 work cycle of motor, has gathered a series of test data, selects four groups of data for analysis.First group of data continuous acquisition to the mean square deviation of 900 rotary speed data points be 7.69rpm, and the maximum (top) speed difference only is 40rpm, the engine cooling water temperature of this moment is 75.4 ℃, oil temperature is 68.9 ℃, specifically shown in the A figure among Fig. 5; Second group of data capture to the rotary speed data mean square deviation be 8.17rpm, the maximum (top) speed difference is 43rpm, the engine cooling water temperature of this moment is 77.1 ℃, oil temperature is 70.1 ℃, specifically shown in the B figure among Fig. 5; The 3rd group of data capture to the rotary speed data mean square deviation be 8.29rpm, the maximum (top) speed difference is 44rpm, the engine cooling water temperature of this moment is 79.9 ℃, oil temperature is 71.4 ℃, specifically shown in the C figure among Fig. 5; The 4th group of data capture to the rotary speed data mean square deviation be 7.91rpm, the maximum (top) speed difference is 42rpm, the engine cooling water temperature of this moment is 81.1 ℃, oil temperature is 78.6 ℃, specifically shown in the D figure among Fig. 5.The comparison object rotating speed is that single closed loop of 850rpm can draw with two closed test results, generally speaking the control effect of the idling speed of two closed loops slightly is better than the control effect of single closed loop, the fluctuation of speed amount of natural gas engine is less, and it is more smooth-going to turn round, and operating noise is less.

In sum, when rotating speed of target when value is 1200rpm and 850rpm respectively, can draw from test result, the two closed loop control methods of idling can make natural gas engine obtain better idling speed stability, and the more single closed loop of this controlling method is more excellent.

Claims (4)

1, control method of idling speed double closed-loop of gaseous propellant engine, tach signal by speed probe output motor, and tach signal is input among the ECU (Electrical Control Unit) ECU, catch then and calculate, draw current actual engine speed, actual engine speed and predefined rotating speed of target compare, and obtain the rotating speed deviation; It is characterized in that: calculate the total variation of gaseous fuel injection pulse width and the variable quantity of the stepper motor action step-length of controlling the bypath air air inflow respectively according to closed loop control method, thereby draw required gaseous fuel injection pulse width of next operating point and stepper motor action step-length, finish two closed loop controls rotating speed.

2, control method of idling speed double closed-loop of gaseous propellant engine according to claim 1 is characterized in that: the closed loop control method of described gaseous fuel injection pulse width is as follows:

Earlier calculate gaseous fuel injection pulse width total variation Δ H_Gas according to following formula:

ΔH _p_Gas＝K _p_Gas×[e _n-e _n-1]

Δ _i_Gas＝K _i_Gas×e _n

ΔH _d_Gas＝K _d_Gas×[e _n-2×e _n-1+e _n-2]

ΔH_Gas＝ΔH _p_Gas+ΔH _i_Gas+ΔH _d_Gas

In the following formula: e _n=m-n

M is the idling rotating speed of target

N is an actual engine speed

e _nDeviation for this rotating speed of target and actual speed

e _N-1Deviation for last time rotating speed of target and actual speed

e _N-2Deviation for rotating speed of target and actual speed of last last time

K _p_ Gas is the proportional coefficient

K _i_ Gas is an integral item coefficient

K _d_ Gas is the differential term coefficient

Δ H _p_ Gas is the variable quantity of the caused gaseous fuel injection pulse width of proportional

Δ H _i_ Gas is the variable quantity of the caused gaseous fuel injection pulse width of integral

Δ H _d_ Gas is the variable quantity of the caused gaseous fuel injection pulse width of differential term

Δ H_Gas is a gaseous fuel injection pulse width total variation

Control the required gaseous fuel injection pulse width of next operating point according to gaseous fuel injection pulse width total variation Δ H_Gas again, realize closed loop control rotating speed.

3, control method of idling speed double closed-loop of gaseous propellant engine according to claim 1 is characterized in that: the closed loop control method of described bypath air air inflow is as follows:

Calculate stepper motor action step-length total variation Δ H_Air according to following formula earlier:

ΔH _p_Air＝K _p_Air×[e _n-e _n-1]

ΔH _i_Air＝K _i_Air×e _n

ΔH _d_Air＝K _d_Air×[e _n-2×e _n-1+e _n-2]

ΔH_Air＝ΔH _p_Air+ΔH _i_Air+ΔH _d_Air

In the following formula: e _n=m-n

M is the idling rotating speed of target

N is an actual engine speed

e _nDeviation for this rotating speed of target and actual speed

e _N-1Deviation for last time rotating speed of target and actual speed

e _N-2Deviation for rotating speed of target and actual speed of last last time.

K _p_ Air is the proportional coefficient

K _i_ Air is an integral item coefficient

K _d_ Air is the differential term coefficient

Δ H _p_ Air is that the caused stepper motor action of proportional step-size amounts changes

Δ H _i_ Air is that the caused stepper motor action of integral step-size amounts changes

Δ H _d_ Air is that the caused stepper motor action of differential term step-size amounts changes

Δ H_Air is a stepper motor action step-length total variation

According to stepper motor action step-length total variation Δ H_Air control step motor action, realize closed loop control again to rotating speed.

4, control method of idling speed double closed-loop of gaseous propellant engine according to claim 1 is characterized in that: described gaseous fuel is rock gas or LPG or hydrogen.

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