JPS6359017B2 - - Google Patents

Description

[Detailed description of the invention] When starting an LPG engine at low temperatures, normally
Close the LPG valve, open the gasoline tank on the upstream side of the carburetor float chamber, perform cranking, start the engine with gasoline, and perform idling to warm up the engine. After warming up the engine, close the gasoline tank. , open the LPG pot and switch to LPG operation. Both LPG and gasoline are supplied to the engine until the gasoline in the float chamber is completely consumed.
During that time, overbalance operation will be performed. Starting an LPG engine using the above-mentioned conventional method is troublesome, and overbalance operation also causes air pollution. The purpose of this invention is to fully automate the start-up and subsequent warm-up of LPG engines at low temperatures.
When the engine is started and during warm-up, the difference between the required LPG fuel flow rate and the actual flow rate during start-up and warm-up, depending on the intake air temperature and engine temperature;
That is, the present invention relates to a starting device for an LPG engine that uses a gasoline injector to compensate for and increase LPG fuel shortage during cranking and during warm-up after complete explosion. The details of the present invention will be explained below with reference to the drawings. Figure 1 shows the case where the above gasoline injector is placed just before the intake valve of the LPG engine, and Figure 2 shows the case where the gasoline injector is placed just before the intake valve of the LPG engine.
An embodiment is shown in which a gasoline injector is placed above a bench lily in a main intake passage of a carburetor. In Figure 1, numeral 1 is the LPG vaporizer, 2 is the above
A bench lily of the LPG vaporizer main intake passage, 3 a main nozzle opening into the bench lily portion, 4 a throttle valve,
Reference numeral 5 denotes a lever that rotates together with the throttle valve, and is biased in the closing direction of the throttle valve 4 by a spring not shown. 6 is an LPG cylinder, 7 is a valve that opens and closes by turning on and off a key switch, 8
is LPG regulator (including vaporizer),
9 is a gasoline tank, 10 is a gasoline pump, 1
1 is an oil pipe connecting the gasoline tank 9 and the gasoline pump 10, 12 is a regulator, 13 is a gasoline return pipe, 14 is an injector, 15 is an idling speed control device (ISC), and 16 is a shaft of the idling speed control device. This is a pin that moves in the direction to control the opening degree of the throttle valve 4 during starting and idling of the LPG engine, and one end of the pin is in contact with the end of the lever 5. 17 is a control circuit based on a microprocessor, which controls the gasoline pump 10, the gasoline injector 14, and the idling speed control device, and includes a starting motor on/off signal 18, an engine temperature signal 19, an engine speed signal 20, Input the intake pressure signal 21, throttle valve opening signal 22 (by potentiometer), intake temperature signal 23, gasoline pump drive signal 25, and injector gasoline injection amount control signal 2.
6. Output the idling rotation speed control signal 27. 28 is the intake valve of the LPG engine, and 29 is the pilot port. In FIG. 1, the injector 14 is located just before the intake valve 28, while in FIG.
The outside of the carburetor 1, which is placed above the bench lily 2, is exactly the same as that shown in FIG.
Details are omitted in the figure.

Next, the operation of the LPG engine starting device according to the present invention will be explained. In order for an LPG engine to start using only LPG, the intake air temperature and engine temperature must be above a certain value. When the starting motor is turned on and cranking starts below this temperature, the pressure on the outlet side of the regulator 8 decreases, and LPG is sucked into the main intake passage of the LPG vaporizer by the action of the regulator 8. Since the temperature is low, the mixture concentration is low and ignition is difficult. On the other hand, when the starting motor is turned on and the starting motor on signal, cranking rotational speed, suction pressure, engine temperature, and atmospheric temperature signals are input to the control circuit 17, the idling rotational speed control device outputs the output from the control circuit. The gasoline injector 14 is controlled by the signal to give an appropriate throttle valve opening, and the gasoline flow rate signal that corrects the LPG shortage calculated by the control circuit 17 is transmitted to the gasoline injector 14.
is output to form a mixture with an ignitable concentration.
The LPG engine starts (complete explosion). During warm-up operation after a complete explosion, the LPG shortage is compensated by gasoline injection according to the engine temperature and intake air temperature, and the engine rotation speed is maintained at the set value by the idling rotation speed control device. Gasoline injection stops upon completion of warm-up. When the engine has been warmed up, the intake air has been sufficiently preheated, so there is no actual need to correct the intake air temperature by increasing the amount of fuel by gasoline injection. Engine temperature is often represented by cooling water temperature. Also, since the starting device of the present invention has an idling rotation speed control device 15,
Idle-up control for various electrical loads and cooler compressor loads on the LPG engine is also possible by inputting these idle-up request signals to the control circuit. (These inputs are omitted in the drawing.) In Fig. 1, the control circuit 1
The input 24 indicated by a broken line in 7 is a signal input from the exhaust gas O ₂ sensor, and enables air-fuel ratio feedback control after transition to normal operation after starting and warming up. It was established for this purpose. Even after warm-up is complete, if the mixture ratio of air and LPG tends to be lean throughout the entire operating range, a small amount of gasoline will always be injected, and O ₂
Feedback air-fuel ratio control can be performed using sensors. In addition, when the air-fuel ratio is set to be controllable as described above, the LPG engine starting device of the present invention is capable of running a short distance to one side of the road by injecting gasoline when the vehicle runs out of LPG while the vehicle is running. It is also possible to operate the system, but since this is not the purpose of this invention, the details will be omitted.

An LPG engine equipped with the starting device according to the present invention does not require any throttle operation, accelerator operation, or fuel switching operation at the time of starting, and can be started and warmed up with the accelerator pedal released. This has the advantage of saving fuel compared to switching between gasoline and LPG.

[Brief explanation of drawings]

1 and 2 show an LPG engine equipped with a starting device according to the present invention. 1... LPG vaporizer, 2... bench lily, 3...
...LPG main nozzle, 8...LPG regulator,
7...Valve that opens and closes with a key switch, 9...Gasoline tank, 10...Gasoline pump, 11...
... Oil pipe, 12 ... Regulator, 13 ... Retan pipe, 14 ... Injector, 15 ... Idling rotation speed control device, 17 ... Control circuit,
18... Starting motor on/off signal, 19... Engine temperature signal, 20... Rotational speed signal, 21... Intake pressure signal, 22... Throttle valve opening signal, 23...
Intake air temperature signal, 24... _O2 sensor signal, 25...
...gasoline pump drive signal, 26...injection amount control signal, 27...idling rotation speed control signal.

Claims (1)

[Claims] 1. Consisting of an electronic control circuit 17, a Gatulin injector 14 controlled by the electronic control circuit, and an idling rotation speed control device 15, when starting an LPG engine at a low temperature, the intake air temperature is controlled. ,
Above LPG engine temperature and starting motor ON signal 1
8 is input and calculated by the electronic control circuit 17, and outputs a starting fuel increase correction signal and a throttle valve opening signal to the gasoline injector 14 and the idling rotation speed control device 15, respectively, to warm up the LPG engine after complete explosion. When transitioning to machine operation, the intake air temperature, above
Signals such as LPG engine temperature, engine speed, intake pressure, throttle valve opening and starting motor off are input and calculated to generate a warm-up fuel increase correction signal and a throttle valve opening signal for the gasoline injector 14 and idling, respectively. A starting device for the LPG engine that outputs to the rotation speed control device 15. 2 The control circuit 17 controls the LPG at each intake air temperature and engine temperature during low-temperature startup and warm-up operation.
The gasoline injection amount of the gasoline injector is memorized to compensate for the shortage of fuel supply, and when the engine is started and warmed up after a complete explosion, each of the above input signals is input, and each The starting device for an LPG engine according to claim 1, wherein the LPG engine starting device is programmed to output necessary throttle valve opening and gasoline injection amount control signals to the idling opening control device and gasoline injector. 3. When the LPG engine has various electrical loads and cooler compressor loads, the control circuit inputs and calculates the idle up request signal and outputs the idle up signal to the idling speed control device 17. A starting device for an LPG engine according to items 1 and 2 of the scope. 4 After the LPG engine has been warmed up, the control circuit 17 inputs the engine temperature, especially the signal from the cooling water temperature sensor, and stops outputting the gasoline injection signal from the injector.
The LPG engine starting device according to any one of claims 1 to 3, wherein gasoline injection for correction increase is stopped.