CN213743700U - Control system for multi-fuel generator engine - Google Patents

Abstract

The utility model relates to a control system for many fuel generator engine, mainly used many fuel generator product is last. The technical scheme comprises the following steps: a controller having a first signal input, a second signal input, a third signal input, and an output coupled to an ignition of the generator engine; and when the third signal input end of the controller receives a generator engine starting signal and only one port of the first signal input end and the second signal input end receives a signal corresponding to the opening state of the valve assembly, the controller controls the ignition device to ignite. The utility model discloses a controller detects the signal that two fuel valve component states correspond and judges whether fuel supply is normal, has avoided two kinds of fuels to supply with to the generator engine simultaneously and has leaded to the operation unstability or trouble.

Description

Control system for multi-fuel generator engine

Technical Field

The utility model relates to a control system for many fuel generator engines mainly used is on many fuel generator products to ensure that the generator only has a fuel to be used in same time quantum.

Background

The invention relates to a generator, in particular to mechanical equipment which is driven by a non-road ignition engine, converts chemical energy generated by fuel combustion into mechanical energy and transmits the mechanical energy to a generator, and then converts the mechanical energy into electric energy by the generator.

In order to adapt to different application scenarios, a "dual-fuel" generator is available on the market, and one of the fuels (which may be gasoline, liquefied petroleum gas, natural gas, etc.) can be selected as a generator fuel according to needs or the current environment. Since the dual-fuel generator has two different fuel delivery pipelines, different valves are required to control the on-off of the two fuel delivery pipelines respectively. In practice, it may happen that both fuel delivery lines are connected due to operator error, which may result in two different fuels being mixed together, thereby posing a potential safety risk.

SUMMERY OF THE UTILITY MODEL

The utility model aims at overcoming the not enough among the prior art, provide a control system for many fuel generator engine.

The purpose of the utility model is realized through the following technical scheme:

a control system for a multi-fuel generator engine, comprising,

a first fuel valve assembly having an open state and a closed state to control a supply of a first fuel;

a second fuel valve assembly having an open state and a closed state to control a supply of a second fuel;

the control system further comprises:

a controller having a first signal input coupled to the first fuel valve assembly for obtaining a signal corresponding to a current state of the valve assembly, a second signal input coupled to the second fuel valve assembly for obtaining a signal corresponding to a current state of the valve assembly, a third signal input for receiving a generator engine start and/or stop signal, and an output coupled to an ignition device of the generator engine;

the power supply unit is used for supplying power to the controller;

and when the third signal input end of the controller receives a generator engine starting signal and only one port of the first signal input end and the second signal input end receives a signal corresponding to the opening state of the valve assembly, the controller controls the ignition device to ignite. When the third signal input end of the controller receives a starting signal of the engine of the generator, the first signal input end receives a signal corresponding to the opening state of the first fuel valve component, and the second signal input end receives a signal corresponding to the closing state of the second fuel valve component, the controller controls the ignition device to ignite; or when the third signal input end of the controller receives a generator engine starting signal, the first signal input end receives a signal corresponding to the closed state of the first fuel valve component, and the second signal input end receives a signal corresponding to the open state of the second fuel valve component, the controller controls the ignition device to ignite.

Preferably, the first fuel valve assembly comprises a first fuel valve disposed on the first fuel delivery line, and a first switch disposed adjacent the first fuel valve; a first trigger part matched with the first switch is arranged at the first fuel valve, and the first switch is triggered by the trigger part in the opening state or the closing state; one end of the first switch is connected with the first signal input end, and the other end of the first switch is grounded or connected with a high level. The first trigger part triggers a first switch (a microswitch can be selected) by opening and closing the first fuel valve, and the first signal input end obtains a low-level (grounding) or high-level signal as a signal of the opening state or the closing state of the first fuel valve component.

Preferably, the second fuel valve assembly includes a second fuel valve disposed on the second fuel delivery line, and a second switch disposed adjacent the second fuel valve; a second trigger part matched with the second switch is arranged at the second fuel valve, and the second switch is triggered by the trigger part in the opening state or the closing state; one end of the second switch is connected with the second signal input end, and the other end of the second switch is grounded or connected with a high level. The second trigger part triggers a second switch (a microswitch can be selected) by utilizing the opening and closing of the second fuel valve, and a low-level (grounding) or high-level signal is obtained from the second signal input end as a signal of the opening state or the closing state of the second fuel valve component.

Preferably, the first fuel delivery pipeline and/or the second fuel delivery pipeline are provided with a switch valve (which may be an electromagnetic valve), and a control signal input end of the switch valve is in communication connection with the controller. The controller is used for controlling the on-off valve to be opened and closed, so that the fuel remained in the conveying pipeline can be prevented from passively entering the generator engine.

Preferably, the control system further comprises an indicating device connected to the controller for indicating a current generator engine operating state to a user.

A control system for a multi-fuel generator engine, comprising,

a first fuel valve assembly having an open state and a closed state to control a supply of a first fuel;

a second fuel valve assembly having an open state and a closed state to control a supply of a second fuel;

the control system further comprises:

a controller having a first signal input coupled to the first fuel valve assembly for obtaining a signal corresponding to a current state of the valve assembly, a second signal input coupled to the second fuel valve assembly for obtaining a signal corresponding to a current state of the valve assembly, and an output coupled to an ignition device of the generator engine;

the power supply unit is used for taking power from the generator engine or the generator after the generator engine is started and supplying power to the controller;

and when only one port of the first signal input end and the second signal input end of the controller receives a signal corresponding to the opening state of the valve component, the current operation state is maintained. After the generator engine is started, when a first signal input end of the controller receives a signal corresponding to the opening state of a first fuel valve component and a second signal input end of the controller receives a signal corresponding to the closing state of a second fuel valve component, the normal running state of the generator engine is maintained; or when the first signal input end of the controller receives a signal corresponding to the closed state of the first fuel valve component and the second signal input end of the controller receives a signal corresponding to the open state of the second fuel valve component, the normal running state of the engine of the generator is maintained.

Preferably, the first signal input end and the second signal input end of the controller both receive signals corresponding to the opening state of the valve assembly in the same time period, namely, both fuels are in the suppliable state, and at the moment, the controller controls the ignition device to be turned off.

Preferably, the first signal input end and the second signal input end of the controller both receive signals corresponding to the closing state of the valve assembly in the same time period, that is, both fuels are in the non-supply state, and the controller controls the ignition device to be turned off.

Preferably, the first fuel valve assembly comprises a first fuel valve disposed on the first fuel delivery line, and a first switch disposed adjacent the first fuel valve; a first trigger part matched with the first switch is arranged at the first fuel valve, and the first switch is triggered by the trigger part in the opening state or the closing state; one end of the first switch is connected with the first signal input end, and the other end of the first switch is grounded or connected with a high level. The first trigger part triggers a first switch (a microswitch can be selected) by opening and closing the first fuel valve, and the first signal input end obtains a low-level (grounding) or high-level signal as a signal of the opening state or the closing state of the first fuel valve component.

Preferably, the second fuel valve assembly includes a second fuel valve disposed on the second fuel delivery line, and a second switch disposed adjacent the second fuel valve; a second trigger part matched with the second switch is arranged at the second fuel valve, and the second switch is triggered by the trigger part in the opening state or the closing state; one end of the second switch is connected with the second signal input end, and the other end of the second switch is grounded or connected with a high level. The second trigger part triggers a second switch (a microswitch can be selected) by utilizing the opening and closing of the second fuel valve, and a low-level (grounding) or high-level signal is obtained from the second signal input end as a signal of the opening state or the closing state of the second fuel valve component.

Preferably, the power supply unit includes:

a coil generating an alternating current when the generator engine operates; specifically, when the coil is a charging coil, the generator engine generates alternating current when working; when the coil is a generator winding, the generator engine works and drives the generator to work to generate alternating current;

and the input end of the rectifying circuit is connected with the coil, and the output end of the rectifying circuit is connected with the controller and used for rectifying the alternating current generated by the coil into direct current to supply power for the controller.

Preferably, the first fuel delivery pipeline and/or the second fuel delivery pipeline are provided with a switch valve (which may be an electromagnetic valve), and a control signal input end of the switch valve is in communication connection with the controller. The controller is used for controlling the on-off valve to be opened and closed, so that the fuel remained in the conveying pipeline can be prevented from passively entering the generator engine.

Preferably, the control system further comprises an indicating device connected to the controller for indicating a current generator engine operating state to a user.

Preferably, the controller further has a third signal input for receiving a generator engine stop signal for user operation to shut down the generator engine.

The utility model has the advantages that:

1. the controller detects signals corresponding to the states of the two fuel valve assemblies to judge whether the fuel supply is normal or not, so that the instability or the fault caused by the simultaneous supply of the two fuels to the engine of the generator is avoided.

2. A first signal input end and a second signal input end of the controller both receive signals corresponding to the opening state of the valve assembly in the same time period, namely, both fuels are in a feedable state; or the first signal input end and the second signal input end of the controller both receive signals corresponding to the closing state of the valve assembly in the same time period, namely, the two fuels are in the state of being incapable of being supplied, the controller controls the ignition device to shut down, the abnormal state of fuel supply can be intelligently judged, the ignition device can shut down in time, and the engine of the generator is protected.

3. By arranging an indicating device, under the condition that the fuel supply is normal (only one fuel supply pipeline is connected to the generator engine), the current normal state is prompted; under the condition that the fuel is not supplied normally (both fuels are in a suppliable state or both fuels are in an suppliable state), prompting a user that the fuel is in an abnormal state currently, and timely flameout is required.

4. The fuel valve component has a simple structure and ingenious design, and the action of the fuel valve component can be timely converted into a corresponding signal to be acquired by the controller, so that whether fuel supply is normal or not is judged.

5. The fuel supply system can be protected in multiple ways by arranging the switch valve on the fuel conveying pipeline.

Drawings

FIG. 1 is a block diagram of example 1 (TCI firing pattern).

Fig. 2 is a schematic diagram of a first fuel valve assembly of the present invention.

Fig. 3 is a block diagram of a second fuel valve assembly according to the present invention.

Fig. 4 is a schematic circuit diagram of the controller of the present invention.

FIG. 5 is a control system diagram of the CDI ignition system in accordance with example 1.

FIG. 6 is a structural diagram (TCI ignition mode) of example 2.

FIG. 7 is a control system diagram of the CDI ignition system in the embodiment 2.

Detailed Description

The present invention will be further described with reference to the following examples. The following description of the embodiments is merely provided to aid in understanding the invention. It should be noted that, for those skilled in the art, the present invention can be modified in several ways without departing from the principle of the present invention, and these modifications and modifications also fall into the protection scope of the claims of the present invention.

Example 1

As shown in fig. 1, the present embodiment is a control system for a dual fuel generator engine, including:

a first fuel valve assembly 1 having an open state and a closed state to control the supply of a first fuel;

a second fuel valve assembly 2 having an open state and a closed state to control supply of a second fuel;

a controller 3 having a first signal input coupled to the first fuel valve assembly 1 for acquiring a signal corresponding to a current state of the valve assembly, a second signal input coupled to the second fuel valve assembly 2 for acquiring a signal corresponding to a current state of the valve assembly, a third signal input for receiving a generator engine start and/or stop signal, and an output coupled to an ignition device 5 of the generator engine;

the power supply unit 4 is used for supplying power to the controller 3 and can adopt a mode of a built-in battery or an external storage battery, and in the embodiment, the power supply unit adopts the external storage battery mode to supply power to the controller 3; namely, the controller 3 is in a charged state, and the controller 3 can normally work before the engine of the generator is started;

and when the third signal input end of the controller 3 receives a generator engine starting signal and only one port of the first signal input end and the second signal input end receives a signal corresponding to the opening state of the valve assembly, the controller 3 controls the ignition device 5 to ignite. That is, the third signal input end of the controller 3 receives a generator engine start signal (which may be implemented by a key remote control, a mobile phone APP or an external switch, in this embodiment, the third signal input end is directly connected to an external switch K3, and the other end of the switch is grounded), and when the first signal input end receives a signal corresponding to the open state of the first fuel valve assembly 1 and the second signal input end receives a signal corresponding to the closed state of the second fuel valve assembly 2, the controller 3 controls the ignition device 5 to ignite; or when the third signal input end of the controller 3 receives a generator engine starting signal, the first signal input end receives a signal corresponding to the closed state of the first fuel valve assembly 1, and the second signal input end receives a signal corresponding to the open state of the second fuel valve assembly 2, the controller 3 controls the ignition device 5 to ignite.

In an exemplary embodiment of the invention, the first fuel is gasoline and the second fuel is liquefied petroleum gas. Of course, the first fuel and/or the second fuel may be other types of fuel, including natural gas, biogas, etc., within the purview of one skilled in the art. Accordingly, as shown in FIG. 2, the first fuel valve assembly 1 includes a first fuel valve 1-1 disposed on a first fuel delivery line, and a first switch 1-2 disposed adjacent to the first fuel valve; a first trigger part 1-3 matched with the first switch 1-2 is arranged at the first fuel valve 1-1, and the trigger part triggers the first switch 1-2 in the opening state or the closing state; one end of the first switch 1-2 is connected to the first signal input end, and the other end is grounded or connected to a high level (in this embodiment, a grounding manner is adopted). Specifically, the first fuel valve 1-1 adopts a rotary switch structure, the first trigger part 1-3 is positioned on a knob of the rotary switch, the first switch 1-2 adopts a microswitch, and the microswitch is positioned on a rotating path of the knob of the rotary switch of the first fuel valve 1-1; in the open state or the closed state, the first triggering part 1-3 triggers the first switch 1-2, and the first signal input terminal obtains a low level (ground) signal as a signal of the open state or the closed state of the first fuel valve assembly. Accordingly, as shown in FIG. 3, the second fuel valve assembly 2 comprises a second fuel valve 2-1 disposed on the second fuel delivery line, and a second switch 2-2 disposed adjacent to the second fuel valve; a second trigger part 2-3 matched with the second switch 2-2 is arranged at the second fuel valve 2-1, and the second switch 2-2 is triggered by the trigger part in the opening state or the closing state; one end of the second switch 2-2 is connected to the second signal input terminal, and the other end is grounded or grounded at a high level (in this example). Specifically, the second fuel valve 2-1 comprises a switch male end 2-1-1 and a switch female end 2-1-2 which are matched with each other, the second switch 2-2 is a microswitch and is arranged adjacent to the switch female end 2-1-2, and the second trigger part 2-3 is arranged on the switch male end 2-1-1; when the male end 2-1-1 of the switch is inserted into the female end 2-1-2 of the switch, the second trigger part 2-3 triggers the second switch 2-2, and the second signal input end obtains a low-level (grounding) signal as a signal of the opening state of the second fuel valve component. On the contrary, when the male switch end 2-1-1 is pulled out from the female switch end 2-1-2, the second trigger part 2-3 is separated from the second switch 2-2, the second switch 2-2 is reset, and the second signal input end obtains a signal of the closing state of the second fuel valve assembly. Of course, in practical applications, the second switch 2-2 may be disposed adjacent to the switch male terminal 2-1-1, and the second trigger portion 2-3 is disposed on the switch female terminal 2-1-2.

As a more preferable mode of the present embodiment, the first fuel delivery pipeline and/or the second fuel delivery pipeline is provided with a switch valve 6 (in this case, an electromagnetic valve), and a control signal input end of the electromagnetic valve is connected to the controller 3 in a communication manner; the controller 3 is used for controlling the electromagnetic valve to be closed, so that the fuel remained in the conveying pipeline can be prevented from passively entering the generator engine.

The control system further comprises an indicating device 7 (optionally an indicator light or an alarm, etc.) connected to the controller 3 for indicating to a user whether the current generator engine operating state is normal.

As shown in fig. 4, the controller 3 includes an MCU 3-1(U1, in this example, a single chip microcomputer of model STM8S 003), a voltage regulator circuit 3-2, a signal detection circuit 3-3, an ignition system control circuit 3-4, and an electromagnetic valve control circuit 3-5; wherein,

the input end of the voltage stabilizing circuit 3-2 is connected with the power supply unit 4, and the output end of the voltage stabilizing circuit outputs stable 5V direct current to provide a working power supply for the MCU 3-1 and other circuits on the controller 3;

the signal detection circuit 3-3 comprises a resistor R12, a resistor R30 and a capacitor C9 which are sequentially connected in series, a resistor R3, a resistor R29 and a capacitor C1 which are sequentially connected in series, a resistor R1, a resistor R28 and a capacitor C16 which are sequentially connected in series, and the three circuits connected in series are connected in parallel; pin 1 of the MCU (U1) is connected to a contact I _ GasoloneSeSW between a resistor R30 and a capacitor C9, and a first switch 1-2 is connected to a contact LI _ GasoloneSeSW between a resistor R12 and a resistor R30; pin 2 of the MCU (U1) is connected to a contact I _ LPGSW between a resistor R29 and a capacitor C1, and a second switch 2-2 is connected to a contact LI _ LPGSW between a resistor R3 and a resistor R29; the pin 13 of the MCU (U1) is connected to a contact I _ POWER SW between the resistor R28 and the capacitor C16, one end of the switch K3 is connected to the contact LI _ POWER SW between the resistor R1 and the resistor R28, and the other end of the switch K3 is grounded.

An input end O _ Stop of the ignition system control circuit 3-4 is connected with a pin 20 of an MCU (U1), and a contact LI _ POWER is connected with an ignition device 5; the signal output through the MCU (U1) pin 20 controls whether the contact LI _ POWER in the circuit is grounded, if the contact LI _ POWER is grounded, the generator engine is not started even if the start signal is received, otherwise, if the contact LI _ POWER is not grounded, the generator engine is started when the start signal is received.

And an input end O _ Gasoline of the electromagnetic valve control circuit 3-5 is connected with a pin 17 of the MCU (U1), and an output end of the electromagnetic valve control circuit is connected with the electromagnetic valve and is used for controlling the on-off of the electromagnetic valve.

Pins 14 and 15 of the MCU (U1) are connected to an indicator 7 (e.g., an indicator) via a resistor R8 and a resistor R17, respectively, to control the status of the indicator 7 (e.g., green or red).

The ignition device 5 adopts a tci (train Coil ignition) ignition mode, but the ignition device 5 can also adopt a cdi (train Diode ignition) ignition mode shown in fig. 5 within the optional range of the skilled person.

The working principle of the present embodiment is explained as follows:

when the first fuel valve 1-1 is in an open state, the first switch 1-2 is triggered to be closed; under the closing state of the second fuel valve 2-1, the second switch 2-2 is not triggered and maintains the disconnection state; when the first fuel delivery pipeline is connected, gasoline (first fuel) flows from the oil storage tank to a mixer of fuel and air along an oil pipe (first fuel delivery pipeline), such as a dual-fuel carburetor and the like, and the second fuel delivery pipeline is kept in a disconnected state; a generator engine starting signal is given to the controller 3 (realized by operating the switch K3 or by mobile phone APP control or key remote control), and when the controller 3 detects that the first signal input end of the controller receives a signal corresponding to the open state of the first fuel valve assembly 1, and the second signal input end of the controller receives a signal corresponding to the closed state of the second fuel valve assembly 2, the controller 3 controls the ignition device 5 (such as a high-voltage packet, a spark plug and the like) to normally ignite, and the generator engine is started to enter a normal operation state. For better human-computer interaction, the controller 3 can also control the indicating device 7 to display a normal operation signal, such as an indicator light turning on green.

Under the closing state of the first fuel valve 1-1, the first switch 1-2 is not triggered and maintains the disconnection state; when the second fuel valve 2-1 is in an open state, the second switch 2-2 is triggered to be closed; at the moment, the first fuel conveying pipeline is kept in an off state, the second fuel conveying pipeline is connected, and liquefied petroleum gas (second fuel) flows to a mixer of fuel and air from the gas storage cylinder along a gas pipe (second fuel conveying pipeline), such as a dual-fuel carburetor and the like; a generator engine starting signal is given to the controller 3 (realized by operating the switch K3 or by mobile phone APP control or key remote control), and when the controller 3 detects that the first signal input end of the controller receives a signal corresponding to the closed state of the first fuel valve assembly 1, and the second signal input end of the controller receives a signal corresponding to the open state of the second fuel valve assembly 2, the controller 3 drives the switch valve 6 (in this case, an electromagnetic valve) to cut off the oil path, so as to prevent the residual fuel in the first fuel delivery pipeline from passively entering the generator engine, and control the ignition device 5 (such as a high-pressure packet, a spark plug and the like) to normally ignite, so that the generator engine is started to enter a normal operation state. For better human-computer interaction, the controller 3 can also control the indicating device 7 to display a normal operation signal, such as an indicator light turning on green. Of course, when the first fuel valve assembly 1 and/or the second fuel valve assembly 2 controls the fuel path to be short, the switching valve 6 does not need to be installed, and the fuel supply does not need to be actively cut off.

Before the generator engine is started, the first fuel valve 1-1 and the second fuel valve 2-1 are both in an open state due to misoperation, and the first switch 1-2 and the second switch 2-2 are both triggered to be closed, namely, both fuels are in a suppliable state. Giving a generator engine starting signal to the controller 3 (realized by operating the switch K3 or by mobile phone APP control or key remote control), when the controller 3 detects that the first signal input end of the controller receives a signal corresponding to the open state of the first fuel valve assembly 1, and the second signal input end receives a signal corresponding to the open state of the second fuel valve assembly 2, the control indicating device 7 displays an abnormal operation signal, such as a red light is turned on by an indicator lamp, so as to remind an operator to turn off the generator engine starting signal (for example, turn off the switch K3) in time, and check the current states of the first fuel valve 1-1 and the second fuel valve 2-1. If the generator engine is successfully started due to the fact that an operator cannot timely turn off the generator engine starting signal (for example, turn off the switch K3), the controller 3 controls the ignition device 5 to automatically shut off within a set short time (for example, 0 to 3 seconds) after the generator engine is successfully started. For better human-computer interaction, the controller 3 may also control the indicating device 7 to issue an abnormal operation warning, such as a red light flashing of an indicator light.

In the state that the two fuels are both in the suppliable state, the following scheme can be adopted: A. a generator engine starting signal is given to the controller 3 (through the operation switch K3 or through the mobile phone APP control or the key remote control), the controller 3 detects that the first signal input end of the controller 3 receives a signal corresponding to the open state of the first fuel valve assembly 1, and when the second signal input end receives a signal corresponding to the open state of the second fuel valve assembly 2, the controller 3 controls the ignition device 5 not to perform the ignition operation. For better man-machine interaction, the indicating device 7 can also be controlled to display an abnormal operation signal, such as a red light on an indicator light, to remind an operator to timely turn off the engine start signal of the generator (for example, turn off the switch K3), and to check the current states of the first fuel valve 1-1 and the second fuel valve 2-1. B. A generator engine starting signal is given to the controller 3 (realized by operating a switch K3 or through mobile phone APP control or key remote control), the controller 3 controls the ignition device 5 to ignite, and the generator engine is started; after the controller 3 detects that the first signal input end of the controller receives the signal corresponding to the opening state of the first fuel valve assembly 1, and the second signal input end of the controller receives the signal corresponding to the opening state of the second fuel valve assembly 2, the controller 3 controls the ignition device 5 to automatically turn off within a set short time (e.g., 0 to 3 seconds) after the successful start. For better man-machine interaction, the indicating device 7 can also be controlled to give an abnormal operation warning, such as flashing of a red light of an indicator light, reminding an operator to turn off a generator engine starting signal (for example, the switch K3) in time, and checking the current states of the first fuel valve 1-1 and the second fuel valve 2-1.

Before the engine of the generator is started, the first fuel valve 1-1 and the second fuel valve 2-1 are in a closed state due to misoperation, and the first switch 1-2 and the second switch 2-2 are not triggered and are in an off state, namely, the two fuels are in a non-supply state. A generator engine starting signal is given to the controller 3 (realized by operating the switch K3 or by mobile phone APP control or key remote control), when the controller 3 detects that the first signal input end of the controller receives a signal corresponding to the closed state of the first fuel valve assembly 1, and the second signal input end of the controller receives a signal corresponding to the closed state of the second fuel valve assembly 2, the control indicating device 7 displays an abnormal operation signal, such as an indicator light which is not bright, so as to remind an operator to timely turn off the generator engine starting signal (for example, turn off the switch K3), and check the current states of the first fuel valve 1-1 and the second fuel valve 2-1. If a small amount of fuel capable of operating the generator engine exists in the fuel supply system (the first fuel delivery pipeline and the second fuel delivery pipeline), which results in the generator engine being successfully started under the driving of the ignition device 5 (such as a high-pressure bag, a spark plug, etc.), the controller 3 controls the ignition device 5 to automatically shut down within a set short time (such as 0-3 seconds) after the successful start. For better human-computer interaction, the controller 3 may also control the indicating device 7 to issue an abnormal operation warning, such as a red light flashing of an indicator light.

In the state that the two fuels are not supplied, the following scheme can be adopted: A. a generator engine starting signal is given to the controller 3 (through the operation switch K3 or through the mobile phone APP control or the key remote control), the controller 3 detects that the first signal input end of the controller 3 receives a signal corresponding to the closed state of the first fuel valve assembly 1, and when the second signal input end receives a signal corresponding to the closed state of the second fuel valve assembly 2, the controller 3 controls the ignition device 5 not to perform the ignition operation. For better man-machine interaction, the indicating device 7 can also be controlled to display an abnormal operation signal, such as a non-illuminated indicator light, to remind the operator to turn off the engine start signal (e.g., the switch K3) in time and check the current states of the first fuel valve 1-1 and the second fuel valve 2-1. B. A generator engine starting signal is given to the controller 3 (realized by operating a switch K3 or through mobile phone APP control or key remote control), the ignition device 5 is controlled by the controller 3 to ignite, and the generator engine is started due to the fact that a small amount of fuel capable of enabling the generator engine to run exists in the fuel supply system; after the controller 3 detects that the first signal input end of the controller receives the signal corresponding to the closed state of the first fuel valve assembly 1, and the second signal input end of the controller receives the signal corresponding to the closed state of the second fuel valve assembly 2, the controller 3 controls the ignition device 5 to automatically turn off within a set short time (e.g., 0 to 3 seconds) after the successful start. For better man-machine interaction, the indicating device 7 can also be controlled to give an abnormal operation warning, such as flashing of a red light of an indicator light, reminding an operator to turn off a generator engine starting signal (for example, the switch K3) in time, and checking the current states of the first fuel valve 1-1 and the second fuel valve 2-1. The abnormal states of the two fuels can be intelligently judged, the fuel is actively extinguished or does not work, and a user is intelligently reminded of correctly controlling the engine.

It is within the purview of one skilled in the art to configure three or more fuel valve assemblies, with each fuel valve assembly being connected to controller 3 for control of the multi-fuel generator engine.

Example 2

As shown in fig. 6, this embodiment is substantially the same as embodiment 1, except that the power supply unit 4 takes power from the generator engine to supply power to the controller 3 after the generator engine is started.

Specifically, the control system for the dual-fuel generator engine comprises,

a first fuel valve assembly 1 having an open state and a closed state to control the supply of a first fuel; the specific structure is the same as that of embodiment 1, and is not described herein again;

a second fuel valve assembly 2 having an open state and a closed state to control supply of a second fuel; the specific structure is the same as that of embodiment 1, and is not described herein again;

a controller 3 having a first signal input connected to the first fuel valve assembly 1 for obtaining a signal corresponding to the current state of the valve assembly, a second signal input connected to the second fuel valve assembly 2 for obtaining a signal corresponding to the current state of the valve assembly, and an output connected to the ignition device 5 of the generator engine;

the power supply unit 4 is used for taking power from the generator engine or the generator after the generator engine is started and supplying power to the controller 3;

when only one of the first signal input end and the second signal input end of the controller 3 receives a signal corresponding to the opening state of the valve assembly, the current operation state is maintained. That is, after the engine of the generator is started (in this embodiment, when the hand-pull recoil starter is started), the first signal input end of the controller 3 receives a signal corresponding to the open state of the first fuel valve assembly 1, and the second signal input end receives a signal corresponding to the closed state of the second fuel valve assembly 2, the normal running state of the engine of the generator is maintained; or when the first signal input end of the controller 3 receives a signal corresponding to the closed state of the first fuel valve assembly 1 and the second signal input end receives a signal corresponding to the open state of the second fuel valve assembly 2, the normal running state of the generator engine is maintained.

As a preferred embodiment of this embodiment, the first signal input terminal and the second signal input terminal of the controller 3 both receive the signal corresponding to the open state of the valve assembly within the same time period, and the controller 3 controls the ignition device 5 to be turned off; or the first signal input end and the second signal input end of the controller 3 both receive signals corresponding to the closing state of the valve assembly in the same time period, and the controller 3 controls the ignition device 5 to be switched off.

As a more preferred embodiment of this embodiment, the power supply unit 4 includes:

coil 4-1, coupled to the generator or engine, which may be a generator winding, a charging coil, etc.; when the coil 4-1 is a generator winding, alternating current is generated when a generator works (driven by a generator engine to work); when the coil 4-1 is a charging coil, the generator engine generates alternating current when working;

and the input end of the rectifying circuit 4-2 is connected with the coil 4-1, and the output end of the rectifying circuit is connected with the controller 3, and is used for rectifying alternating current generated by the coil 4-1 into direct current to supply power to the controller 3. In this embodiment, the rectifying circuit is a rectifier, and outputs 5V or 12V dc after rectification.

As a more preferable embodiment of the present embodiment, the first fuel delivery pipeline and/or the second fuel delivery pipeline is provided with a switch valve 6 (in the present embodiment, an electromagnetic valve), and a control signal input end of the electromagnetic valve is in communication connection with the controller 3; the controller 3 is used for controlling the electromagnetic valve to be closed, so that the fuel remained in the conveying pipeline can be prevented from passively entering the generator engine.

The controller 3 also has a third signal input for receiving a generator engine stop signal. In this example, the third signal input terminal is grounded via a switch K3.

The control system further comprises an indicating device 7 (which may optionally be an indicator light or an alarm) connected to the controller 3 for indicating to a user whether the current generator engine operating state is normal.

The ignition device 5 adopts a tci (train Coil ignition) ignition mode, but the ignition device 5 can also adopt a cdi (train Diode ignition) ignition mode shown in fig. 7 within the optional range of the skilled person.

The working principle of the present embodiment is explained as follows:

when the first fuel valve 1-1 is in an open state, the first switch 1-2 is triggered to be closed; under the closing state of the second fuel valve 2-1, the second switch 2-2 is not triggered and maintains the disconnection state; when the first fuel delivery line is connected, the gasoline (first fuel) flows from the oil tank along the oil pipe (first fuel delivery line) to a fuel and air mixer, such as a dual fuel carburetor, and the second fuel delivery line is kept disconnected. The generator engine is started by pulling a recoil starter (or other methods such as a reverse-pulling type), a coil 4-1 (such as a charging coil or a generator winding) generates alternating current, the alternating current is rectified into 5V or 12V direct current through a rectifying circuit 4-2 and then supplies power to a controller 3, after the controller 3 is electrified, a signal corresponding to the opening state of a first fuel valve component 1 is received by a first signal input end of the controller, a signal corresponding to the closing state of a second fuel valve component 2 is received by a second signal input end of the controller, and the generator engine maintains the current starting state and enters the normal operation state. For better human-computer interaction, the controller 3 can also control the indicating device 7 to display a normal operation signal, such as an indicator light turning on green.

Under the closing state of the first fuel valve 1-1, the first switch 1-2 is not triggered and maintains the disconnection state; when the second fuel valve 2-1 is in an open state, the second switch 2-2 is triggered to be closed; at this time, the first fuel delivery line is kept in an off state, the second fuel delivery line is connected, and the liquefied petroleum gas (second fuel) flows from the gas storage cylinder to a fuel and air mixer, such as a dual-fuel carburetor, along the gas pipe (second fuel delivery line). The generator engine is started by pulling a recoil starter (or other modes such as a reverse-pulling mode), a coil 4-1 (such as a charging coil or a generator winding) generates alternating current, the alternating current is rectified into 5V or 12V direct current through a rectifying circuit 4-2 and then supplies power to a controller 3, after the controller 3 is electrified, a signal corresponding to the closing state of a first fuel valve component 1 is received by a first signal input end of the controller, when a signal corresponding to the opening state of a second fuel valve component 2 is received by a second signal input end of the controller, the controller 3 drives a switch valve 6 (an electromagnetic valve in the embodiment) to cut off an oil circuit, so that residual fuel oil in a first fuel conveying pipeline is prevented from passively entering the generator engine, and the generator engine maintains the current starting state and enters the normal running state. For better human-computer interaction, the controller 3 can also control the indicating device 7 to display a normal operation signal, such as an indicator light turning on green. Of course, when the first fuel valve assembly 1 and/or the second fuel valve assembly 2 controls the fuel path to be short, the switching valve 6 does not need to be installed, and the fuel supply does not need to be actively cut off.

Before the generator engine is started, the first fuel valve 1-1 and the second fuel valve 2-1 are both in an open state due to misoperation, and the first switch 1-2 and the second switch 2-2 are both triggered to be closed, namely, both fuels are in a suppliable state. The generator engine is started by pulling a recoil starter (or other methods such as a reverse-pulling type), a coil 4-1 (such as a charging coil or a generator winding) generates alternating current, the alternating current is rectified into 5V or 12V direct current by a rectifying circuit 4-2 and then supplies power to a controller 3, after the controller 3 is electrified, a signal corresponding to the opening state of a first fuel valve component 1 is received by a first signal input end of the controller, when a signal corresponding to the opening state of a second fuel valve component 2 is received by a second signal input end of the controller, an abnormal operation signal is displayed by a control indicating device 7, such as an indicator lamp which is lighted by red light, so as to remind an operator of timely triggering a stop (flameout) signal (such as a disconnecting switch K3) of the generator engine, and the current states of the first fuel valve 1-1 and the second fuel valve 2-1 are checked. If the operator fails to trigger the stop (flame-out) signal of the generator engine (for example, turns off the switch K3), the controller 3 will control the ignition device 5 to automatically flame out within a set short time (for example, 0 to 3 seconds) after receiving the signal corresponding to the above state. For better human-computer interaction, the controller 3 may also control the indicating device 7 to issue an abnormal operation warning, such as a red light flashing of an indicator light.

In the state that the two fuels are both in the suppliable state, the following scheme can be adopted: after the controller 3 is powered on, it detects that the first signal input end of the controller receives the signal corresponding to the open state of the first fuel valve assembly 1, and after the second signal input end receives the signal corresponding to the open state of the second fuel valve assembly 2, the controller 3 will control the ignition device 5 to automatically turn off within a set short time (e.g. 0-3 seconds) after receiving the signal corresponding to the above state. For better man-machine interaction, the indicating device 7 can also be controlled to give an abnormal operation warning, such as flashing red light of an indicator light, reminding an operator to trigger a generator engine stop (flameout) signal (such as the switch K3) in time, and checking the current states of the first fuel valve 1-1 and the second fuel valve 2-1.

Before the engine of the generator is started, the first fuel valve 1-1 and the second fuel valve 2-1 are in a closed state due to misoperation, and the first switch 1-2 and the second switch 2-2 are not triggered and are in an off state, namely, the two fuels are in a non-supply state. Starting the generator engine by pulling the recoil starter (or other means, such as reverse drag) in hand, and in most cases the generator engine will not start; if a small amount of fuel capable of operating the generator engine exists in the fuel supply system (the first fuel delivery pipeline and the second fuel delivery pipeline), which causes the generator engine to start, the coil 4-1 (such as a charging coil or a generator winding) generates alternating current, and the alternating current is rectified into 5V or 12V direct current by the rectifying circuit 4-2, and then the power is supplied to the controller 3, after the controller 3 is electrified, it is detected that the first signal input end of the controller receives a signal corresponding to the closing state of the first fuel valve assembly 1, and after the second signal input end receives a signal corresponding to the closing state of the second fuel valve assembly 2, the controller 3 controls the ignition device 5 to automatically extinguish within a set short time (such as 0-3 seconds) after receiving the signal corresponding to the state. For better man-machine interaction, the indicating device 7 can also be controlled to give an abnormal operation warning, such as flashing red light of an indicator light, reminding an operator to trigger a generator engine stop (flameout) signal (such as the switch K3) in time, and checking the current states of the first fuel valve 1-1 and the second fuel valve 2-1.

In the state that the two fuels are not supplied, the following scheme can be adopted: after the controller 3 is powered on, when it is detected that the first signal input end of the controller receives a signal corresponding to the closed state of the first fuel valve assembly 1, and the second signal input end receives a signal corresponding to the closed state of the second fuel valve assembly 2, the control indicating device 7 displays an abnormal operation signal, such as a red light on an indicator light, to remind an operator to trigger a generator engine stop (flameout) signal (for example, an off switch K3) in time, and to check the current states of the first fuel valve 1-1 and the second fuel valve 2-1. If the operator fails to trigger the stop (flame-out) signal of the generator engine (for example, turns off the switch K3), the controller 3 will control the ignition device 5 to automatically flame out within a set short time (for example, 0 to 3 seconds) after receiving the signal corresponding to the above state. For better human-computer interaction, the controller 3 may also control the indicating device 7 to issue an abnormal operation warning, such as a red light flashing of an indicator light. The abnormal states of the two fuels can be intelligently judged, the fuel is actively extinguished or does not work, and a user is intelligently reminded of correctly controlling the engine.

It is within the purview of one skilled in the art to configure three or more fuel valve assemblies, with each fuel valve assembly being connected to controller 3 for control of the multi-fuel generator engine.

Claims (10)

1. A control system for a multi-fuel generator engine, comprising,

a first fuel valve assembly (1) having an open state and a closed state to control the supply of a first fuel;

a second fuel valve assembly (2) having an open state and a closed state to control the supply of a second fuel;

characterized in that the control system further comprises:

a controller (3) having a first signal input coupled to the first fuel valve assembly (1) to obtain a signal corresponding to the current state of the valve assembly, a second signal input coupled to the second fuel valve assembly (2) to obtain a signal corresponding to the current state of the valve assembly, a third signal input for receiving a generator engine start and/or stop signal, and an output coupled to an ignition device (5) of the generator engine;

the power supply unit (4) is used for supplying power to the controller (3);

and when the third signal input end of the controller (3) receives a generator engine starting signal and only one port of the first signal input end and the second signal input end receives a signal corresponding to the opening state of the valve assembly, the controller (3) controls the ignition device (5) to ignite.

2. The control system for a multi-fuel generator engine of claim 1, wherein: said first fuel valve assembly (1) comprising a first fuel valve (1-1) arranged in a first fuel delivery line, and a first switch (1-2) arranged adjacent to the first fuel valve; a first trigger part (1-3) matched with the first switch (1-2) is arranged at the first fuel valve (1-1); one end of the first switch (1-2) is connected with the first signal input end, and the other end of the first switch is grounded or connected with a high level.

3. The control system for a multi-fuel generator engine of claim 1, wherein: the second fuel valve component (2) comprises a second fuel valve (2-1) arranged on the second fuel conveying pipeline and a second switch (2-2) arranged adjacent to the second fuel valve; a second trigger part (2-3) matched with the second switch (2-2) is arranged at the second fuel valve (2-1); one end of the second switch (2-2) is connected with the second signal input end, and the other end of the second switch is grounded or connected with a high level.

4. The control system for a multi-fuel generator engine of claim 1, wherein: a switch valve (6) is arranged on the first fuel conveying pipeline and/or the second fuel conveying pipeline, and the control signal input end of the switch valve is in communication connection with the controller (3); the control system further comprises an indication device (7) connected to the controller (3).

5. A control system for a multi-fuel generator engine, comprising,

a first fuel valve assembly (1) having an open state and a closed state to control the supply of a first fuel;

a second fuel valve assembly (2) having an open state and a closed state to control the supply of a second fuel;

characterized in that the control system further comprises:

a controller (3) having a first signal input connected to the first fuel valve assembly (1) for obtaining a signal corresponding to the current state of the valve assembly, a second signal input connected to the second fuel valve assembly (2) for obtaining a signal corresponding to the current state of the valve assembly, and an output connected to the ignition device (5) of the generator engine;

the power supply unit (4) is used for taking power from the generator engine or the generator after the generator engine is started and supplying power to the controller (3);

and when only one port of the first signal input end and the second signal input end of the controller (3) receives a signal corresponding to the opening state of the valve assembly, the current running state of the generator engine is maintained.

6. The control system for a multi-fuel generator engine of claim 5, wherein: a first signal input end and a second signal input end of the controller (3) both receive signals corresponding to the opening state of the valve assembly in the same time period, and the controller (3) controls the ignition device (5) to extinguish;

or the first signal input end and the second signal input end of the controller (3) both receive signals corresponding to the closing state of the valve assembly in the same time period, and the controller (3) controls the ignition device (5) to extinguish.

7. The control system for a multi-fuel generator engine of claim 5, wherein: said first fuel valve assembly (1) comprising a first fuel valve (1-1) arranged in a first fuel delivery line, and a first switch (1-2) arranged adjacent to the first fuel valve; a first trigger part (1-3) matched with the first switch (1-2) is arranged at the first fuel valve (1-1); one end of the first switch (1-2) is connected with the first signal input end, and the other end of the first switch is grounded or connected with a high level.

8. The control system for a multi-fuel generator engine of claim 5, wherein: the second fuel valve component (2) comprises a second fuel valve (2-1) arranged on the second fuel conveying pipeline and a second switch (2-2) arranged adjacent to the second fuel valve; a second trigger part (2-3) matched with the second switch (2-2) is arranged at the second fuel valve (2-1); one end of the second switch (2-2) is connected with the second signal input end, and the other end of the second switch is grounded or connected with a high level.

9. The control system for a multi-fuel generator engine according to claim 5, characterized in that the power supply unit (4) comprises:

a coil (4-1) for generating an alternating current when the generator engine is operated;

and the input end of the rectifying circuit (4-2) is connected with the coil (4-1), and the output end of the rectifying circuit is connected with the controller (3) and used for rectifying alternating current generated by the coil (4-1) into direct current to supply power to the controller (3).

10. The control system for a multi-fuel generator engine of claim 5, wherein: a switch valve (6) is arranged on the first fuel conveying pipeline and/or the second fuel conveying pipeline, and the control signal input end of the switch valve is in communication connection with the controller (3); the control system also comprises an indicating device (7) connected with the controller (3); the controller (3) further has a third signal input for receiving a generator engine stop signal.

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