WO2018104232A2

WO2018104232A2 - Carburetor for an internal combustion engine of a working device and method for controlling a carburetor

Info

Publication number: WO2018104232A2
Application number: PCT/EP2017/081378
Authority: WO
Inventors: Enrico EICHLER; Rafael FREJNO; Johannes GEIST; Christian Kellermann; Jan Fleer
Original assignee: Makita Corporation
Priority date: 2016-12-08
Filing date: 2017-12-04
Publication date: 2018-06-14
Also published as: WO2018104232A3; DE102016123788B3

Abstract

The object of the invention is a carburetor (100) for an internal combustion engine of a working device, comprising an air funnel (10) and a control chamber (16) connected to a fuel tank, wherein the control chamber (16) is connected to the air funnel (10) via a fuel line (15) that opens into an interior space (11) of the air funnel (10), wherein a pump chamber (18) with a membrane element (19) is arranged in the fuel line (15) between the control chamber (16) and the mouth (17) of the fuel line (15) that opens into the interior space (11) of the air funnel (10). According to the invention, the membrane element (19) is movable by means of an actuating element (22), the membrane element (19) forming together with fuel flowing in the fuel line (15) and the pump chamber (18) a spring-mass oscillation system, wherein a voltage and/or frequency of the spring-mass oscillation system are adjustable.

Description

TITLE: Carburetor for an internal combustion engine of a working device and method for driving a carburettor

description

The present invention relates to a carburetor for an internal combustion engine of an implement, which has a venturi and connected to a fuel tank control chamber, wherein the control chamber is connected via an opening into an interior of the air vent fuel line with the venturi, wherein between the control chamber and the mouth of the Fuel line in the interior of the venturi a pumping chamber is arranged with a membrane element in the fuel line, wherein the membrane element is movable by means of an actuating element. Furthermore, the invention relates to a method for driving a corresponding carburetor and a working device with such a carburetor.

State of the art

Such a carburetor is known for example from DE 20 2009 007 558 Ul. In the pumping chamber, a membrane element is arranged, which forms a pumping unit in order to be able to flexibly adapt the flow rate of the fuel flow in the fuel line. The membrane element is movable via an adjusting element, wherein the adjusting element may be a piezoelectric element. In the flow direction in front of and behind the pumping chamber in each case a flow diode is arranged, wherein the flow diodes, the pumping chamber and the membrane element form a regulating unit. By a periodic activation of the membrane element, an overpressure and underpressure is generated in the pumping chamber by an up and down movement of the membrane element. The periodic volume change, in conjunction with the diodes of the flow diodes, leads to a pumping action of the regulating unit. This pumping action is opposite to the flow in the fuel line, whereby the regulating unit acts as a throttling unit. DESCRIPTION OF THE INVENTION: Problem, Solution, Advantages

It is the object of the present invention to provide a carburettor for an internal combustion engine of a working device as well as a method for driving a carburetor and a working device itself, in which the functionality of the carburetor is further improved.

This object is achieved with the features of the independent claims. Advantageous embodiments and further developments of the invention are specified in the dependent claims.

The carburetor according to the invention is characterized in that the membrane element together with a fuel flowing in the fuel line and in the pumping chamber fuel forms a spring-mass-vibration system, wherein a voltage and / or a frequency of the spring-mass vibration - Are adjustable system and the membrane element together with a fuel in the fuel line and in the pumping chamber flowing fuel forms a spring mass-vibration system, wherein a voltage and / or a frequency of the spring-mass-vibration system are adjustable.

The method according to the invention is characterized in that the membrane element together with a fuel flowing in the fuel line and in the pumping chamber fuel forms a spring-mass-vibration system, wherein a voltage and / or a frequency of the spring-mass vibration - Systems are set.

The membrane element and the fuel flowing in the fuel line and the pumping chamber together form a so-called spring-mass-oscillating system. Due to the up and down movement of the membrane element, the membrane element has spring properties, so that the membrane element forms the spring of the spring-mass-vibration system. The mass of the spring mass-vibration system is formed by the fuel flowing in the fuel line and the pumping chamber. According to the invention, it is provided that the voltage and / or frequency of the spring-mass-vibration Systems or the voltage and / or the frequency by means of which the spring-mass-vibration system is operated, are adjustable. This can be done, for example, by setting and / or adjustable an excitation voltage and / or excitation frequency applied to the actuating element, wherein the movement of the diaphragm element of the spring-mass sensor can be adjusted by setting or changing the excitation voltage and / or excitation frequency applied to the actuating element. Oscillating system can be influenced. In particular, it may be provided that in a throttle operation of the carburetor, the voltage and / or frequency of the spring mass vibration system is selected or adjusted according to an operating point. By adjusting the voltage and / or the frequency of the spring-mass-vibration system, an improved function of the carburetor can be achieved.

Preferably, it is provided that during a throttle operation of the carburetor, the spring-mass-vibration system is operated at a resonant frequency of the spring-mass-vibration system. The resonant frequency is the frequency at which the amplitude of the oscillatory spring-mass-vibration system is greater than when the spring-mass-vibration system is excited by adjacent frequencies. The resonance frequency thus corresponds to the natural frequency of the spring-mass-vibration system. If the spring-mass vibration system is operated during the throttle operation of the carburetor at the resonance frequency of the spring-mass-vibration system, the throttle effect of the regulating unit and thus the carburetor can be significantly improved or increased. In addition, the operation of the spring mass-vibration system with its resonant frequency during throttle operation of the carburetor allows a very good adjustability and efficient control of the diaphragm element via the actuator and thus the carburettor by an efficient use of the electrical energy of the spring mass-vibration system. By exploiting the resonance range of the spring-mass-vibration system, the achievable throttle power can be significantly increased, whereby the size of the membrane element compared to conventionally used membrane elements can be reduced. As a result, both the membrane element and the pump chamber and thus the entire carburetor can be dimensioned to be smaller.

Preferably, the actuator for moving the membrane element is operated at a constant voltage and at a varying excitation frequency. In this case, the actuator is operated frequency-controlled, wherein the voltage applied to the actuator voltage is not changed. In throttle operation, the excitation frequency of the actuating element is then set such that the spring-mass-vibration system is operated at its resonance frequency. By means of a control element operated in this way, the function of the membrane element can be substantially increased, and in particular a particularly efficient use of the electrical energy can take place.

Furthermore, it can be provided that the actuating element for moving the membrane element is operated at a constant frequency and a varying excitation voltage. In this case, the actuator is operated voltage-controlled, wherein the voltage applied to the actuator frequency is not changed, but is kept at a constant level. This allows a particularly good adjustability and energy-efficient control of the actuating element for moving the membrane element.

If the adjusting element is controlled such that the voltage is changed and the frequency remains constant, it is preferably provided that the constant frequency corresponds to the resonance frequency of the spring-mass-vibration system. If the set constant frequency is equal to or equal to the resonance frequency of the spring-mass-vibration system, a particularly good throttle performance or throttle effect can be achieved in throttle operation of the carburetor.

Further, it is preferably provided that the membrane element not only serves to form a pump unit, but the membrane element can also be designed as an information transmitter. In the transmission of information preferably both simple information and more complex information is output from the membrane element. Due to the fact that the membrane element undertakes the transmission of information, it is no longer necessary to arrange additional electrical components in the carburetor, which usually undertake an information transmission. The number of parts to be installed in a carburetor, in particular electronic components, can thereby be reduced, as a result of which the carburetor as a whole can have a more compact design or design. The information output by the membrane element can be used, for example, to diagnose the function of the carburettor.

For information transmission, the membrane element may preferably output a sound signal and / or a voice signal. For example, to output simple, less complex information, a sound signal may be output from the membrane element. In this case, a single tone can be output, or it can also be a tone sequence of several tones are output. The output of more complex information can be done for example by the output of a speech signal. The speech signal may be in the form of voice messages, in particular the output of single or multiple juxtaposed, previously stored words.

In order to move the membrane element up and down, the adjusting element is provided, wherein the adjusting element may preferably have a capacitor as an energy source. The capacitance of the capacitor is usually greater than the capacitance of the membrane element. However, the large capacitance of the capacitor prevents a voltage drop while the membrane element is driven. However, this means that if the voltage needs to be quickly reduced or dropped, the capacitor must be discharged. Usually, the discharge takes place by means of a switch for grounding by means of a resistor. However, it can now be provided according to the invention that no switch is used for discharging the capacitor, but that the capacitor is replaced by means of a capacitor Sound signal of the Mennbranelennents is dischargeable. The fact that now the membrane element can also be used for discharging the capacitor, it is no longer necessary to install a switch and other electronic components in the carburetor, so that the number of electronic components in the carburetor can be further reduced, thereby In turn, costs can be saved.

In order to achieve a rapid and effective discharge of the capacitor, it is preferably provided that the sound signal of the membrane element for discharging the capacitor has a frequency which is higher than the resonance frequency of the spring-mass-vibration system. The sound signal generated by the high frequency of the membrane element is preferably short, so that the high frequency has no influence on the flow or the flow movement of the fuel.

The length of the sound signal of the membrane element for discharging the capacitor is preferably controllable by means of a microprocessor. By means of the microprocessor, the duration of the sound signal can be controlled in a simple manner.

The object of the invention is further achieved by means of a working device which has an internal combustion engine which has a carburetor which is designed and developed as described above. An implement may be, for example, a chainsaw, a circular saw or a cut-off grinder.

Brief description of the drawings

Further measures which improve the invention are described in more detail below together with the description of preferred embodiments of the invention with reference to the figures. Show it:

1 is a schematic representation of a carburetor according to the invention, 2 is a graphical representation of a control of a frequency-controlled actuator for moving a membrane element,

3 shows a graphical representation of a regulation of a voltage-controlled actuating element for moving a membrane element,

Fig. 4 is a schematic representation of the function of a membrane element, and

Fig. 5 is a schematic representation of a procedure for discharging a serving as an energy source for an actuator capacitor.

Preferred embodiments of the invention

Fig. 1 shows schematically a carburetor 100 for an internal combustion engine of a working device.

The carburetor 100 has an air funnel 10, in whose interior 11 a throttle valve 12 is arranged. According to the arrow 13, air flows through the venturi 10, wherein the throttle valve 12 is arranged in the flow direction of the air behind a cross-sectional constriction 14 of the inner space 11 of the venturi 10. By the cross-sectional constriction 14, a Venturi effect or a Venturi nozzle is formed.

In the region of the cross-sectional constriction 14 opens a fuel line 15 into the interior 11 of the air duct 10. The fuel line 15 connects a connected to a fuel tank, not shown, control chamber 16 with the venturi 10. Between the control chamber 16 and the mouth 17 of the fuel line 15 in the Interior 11 of the air funnel 10, a pumping chamber 18 is arranged in the fuel line 15, wherein the arranged in the pumping chamber 18 membrane element 19 shown here by dashed lines is. The membrane element 19 forms a pumping unit. The membrane element 19 is moved via an adjusting element 22, which may be a piezoelectric element, for example.

In shown with the arrows 20 flow direction of the fuel through the fuel line 15 is arranged in front of and behind the pumping chamber 18 each have a flow diode 21. The flow diodes 21, the pumping chamber 18 and arranged therein membrane element 19 together form a regulating unit, which can adjust the flow of fuel in the fuel line 15 of the control chamber 16 to the mouth 17 in the venturi 10 efficiently and flexibly. By a periodic activation of the membrane element 19 by means of the adjusting element 22, an overpressure and underpressure are periodically generated in the pumping chamber 18 by an up and down movement of the membrane element 19. The periodic volume change generated thereby, in conjunction with the diodeicity of the flow diodes 21, results in a pumping action of the regulating unit. This pumping action is opposite to the arrow 20 of the fuel in the fuel line 15, whereby the regulating unit can act as a throttling unit.

The membrane element 19 forms together with the flowing in the fuel line 15 and in the pumping chamber 18 fuel from a spring-mass vibration system in which by the spring action of the diaphragm member 19, the membrane element 19 acts as a spring and in the fuel line 15 and the pumping chamber 18 flowing fuel acts as a mass. In order to increase the throttle power or the throttle effect, this spring-mass-vibration system is operated in throttle operation of the carburetor 100 at the resonant frequency and thus the natural frequency of the spring-mass-vibration system.

The adjusting element for moving the membrane element 19 can be operated frequency-controlled or voltage-controlled.

FIG. 2 graphically shows a frequency-controlled regulation of the actuating element for moving the membrane element 19. The excitation frequency of the Adjusting element 22 is variable or variable, whereas the voltage at which the actuating element 22 is driven, remains constant. As can be seen from the graph in FIG. 2, the fuel flow is the lowest and thus the throttling effect highest, when the excitation frequency of the actuating element 22 of the resonance frequency, shown here in dashed lines, corresponds to the spring-mass-vibration system. In throttle operation of the carburetor 100, the control element 22 is therefore operated at an excitation frequency which corresponds to the resonant frequency of the spring-mass-vibration system.

FIG. 3 graphically shows a voltage-controlled regulation of the actuating element 22. The actuating element 22 is thereby controlled with a constant, unchanging frequency and a variable excitation voltage. As can be seen from the graph in FIG. 2, the fuel flow is the lowest, and thus the throttle effect highest, when the excitation voltage of the control element 22 increases. The throttle effect is approximately linear to the excitation voltage. This allows a well adjustable and efficient way to control the actuator 22. In order to achieve a particularly good throttling effect, the constant frequency of the adjusting element 22 for moving the membrane element 19 corresponds to the resonant frequency of the spring-mass-vibration system.

In Fig. 3, the possibilities of the function of the membrane element 19 are shown. The membrane element 19 is driven by the control element 22 via a control. There are two modes for the control.

In mode 1, the membrane element 19 has only the function of a pump unit in order to be able to realize a pressure generation in the pumping chamber 18 by an up and down movement of the membrane element 19. The adjusting element 22 for moving the membrane element 19 is driven in a frequency-driven control of the actuating element 22 preferably at a frequency less than 100 Hz. As an alternative to mode 1, the Mennbranelennent 19 can also be operated in mode 2, wherein in the mode 2, the membrane element 19 in addition to its function as a pumping unit also has a function as an information transmitter. The adjusting element 22 for moving the membrane element 19 is driven at a frequency-driven control of the actuating element 22 preferably at a frequency between 500 and 1000 Hz. Depending on the type of information transmission can be selected between two output options of the information. If a simple, less complex information about the membrane element 19 is output, the membrane element 19 outputs a sound signal. If, on the other hand, more complex information about the membrane element 19 is to be output, the membrane element 19 emits a speech signal.

As can be seen in FIG. 5, the output of a sound signal through the membrane element 19 can be used to discharge a capacitor 23 serving as an energy source for the control element 22 of the membrane element 19. During operation of the carburetor 100, this capacitor 23 is first charged, in which case a high voltage is applied to the adjusting element 22. At the same time, the speed of the combustion engine of the implement increases. As a result, from a certain speed enrichment of the fuel mixture in the engine is necessary. This requires a rapid reduction of the applied voltage to the actuator 22, wherein the reduction of the voltage is achieved by a discharge of the capacitor 23. By means of a microprocessor 24, the membrane element 19 is driven in such a way that it generates a sound signal, by means of which the capacitor 23 is discharged at a high speed due to the high energy necessary for generating the sound signal. The tone signal has a frequency which is higher, preferably more than twice, as the resonance frequency of the spring-mass-vibration system. By means of the microprocessor 24 and the length of this sound signal is controlled in order to ensure the most complete discharge of the capacitor 23 can. The invention is not limited in its execution to the above-mentioned preferred embodiments. Rather, a number of variants is conceivable, which makes use of the solutions shown even in fundamentally different versions. All features and / or advantages resulting from the claims, the description or the drawings, including design details, spatial arrangements and method steps, can be essential to the invention, both individually and in the most diverse combinations.

LIST OF REFERENCE NUMBERS

100 carburetors

10 air funnel

11 interior

12 throttle

13 flow direction of the air

14 cross-sectional constriction

15 fuel line

16 control chamber

17 estuary

18 pumping chamber

19 membrane element

20 flow direction

21 flow diode

22 control element

23 capacitor

24 microprocessor

Claims

claims

1. carburetor (100) for an internal combustion engine of a working device, with a venturi (10), and

a control chamber (16) connected to a fuel tank, the control chamber (16) being connected to the venturi (10) via a fuel line (15) opening into an interior space (11) of the venturi (10),

wherein between the control chamber (16) and the mouth (17) of the fuel line (15) in the interior (11) of the venturi (10) a pumping chamber (18) with a membrane element (19) in the fuel line (15) is arranged,

wherein the membrane element (19) is movable by means of an adjusting element (22),

characterized in that the membrane element (19) together with a in the fuel line (15) and in the pumping chamber (18) flowing fuel forms a spring-mass-oscillating system, wherein a voltage and / or a frequency of the spring-mass Oscillating systems are adjustable.

2. carburetor (100) according to claim 1, characterized in that during a throttle operation of the carburetor (100), the spring-mass vibration system is operated at a resonant frequency of the spring-mass vibration system.

3. carburetor (100) according to claim 1 or 2, characterized in that the adjusting element (22) is operated at a constant voltage and with a varying excitation frequency.

4. carburetor (100) according to claim 1 or 2, characterized in that the adjusting element (22) is operated at a constant frequency and a varying excitation voltage.

5. carburetor (100) according to claim 4, characterized in that the constant frequency corresponds to the resonant frequency of the spring-mass-vibration system.

6. carburetor (100) according to one of claims 1 to 5, characterized in that the membrane element (19) is designed as an information transmitter.

7. carburetor (100) according to claim 6, characterized in that

Membrane element (19) for transmitting information outputs a sound signal and / or a voice signal.

8. carburetor (100) according to claim 7, characterized in that the adjusting element (22) as a power source, a capacitor (23) wherein the capacitor (23) by means of a sound signal of the membrane element (19) is dischargeable.

9. carburetor (100) according to claim 8, characterized in that the sound signal of the membrane element (19) for discharging the capacitor (23) has a frequency which is higher than the resonant frequency of the spring-mass-vibration system.

10. carburetor (100) according to claim 8 or 9, characterized in that the length of the sound signal of the membrane element (19) for discharging the capacitor (23) by means of a microprocessor (24) is controllable.

11. A method for driving a carburetor (100) having a venturi (10) and connected to a fuel tank control chamber (16), wherein the control chamber (16) via a in an interior (11) of the venturi (10) emptying the fuel line (15) is connected to the air funnel (10), wherein between the control chamber (16) and the mouth (17) of the fuel line (15) in the interior (11) of the air funnel (10) has a pumping chamber (18) Membrane element (19) in the fuel line (15) is arranged, wherein the membrane element (19) by means of an adjusting element (22) is moved, characterized in that the membrane element (19) together with one in the fuel line (15) and in the pumping chamber (18) flowing fuel forms a spring-mass-oscillating system, wherein a voltage and / or a frequency of the spring-mass-vibration system are adjusted.

12. The method according to claim 11, characterized in that during a throttle operation of the carburetor (100), the spring-mass vibration system is operated at a resonant frequency of the spring-mass vibration system.

13. The method according to claim 11 or 12, characterized in that the adjusting element (22) is operated at a constant voltage and with a varying excitation frequency.

14. The method according to claim 11 or 12, characterized in that the adjusting element (22) is operated at a constant frequency and a varying excitation voltage.

15. The method according to any one of claims 11 to 14, characterized in that the membrane element (19) transmits information.

16. The method according to claim 15, characterized in that the membrane element (19) for transmitting information outputs a sound signal and / or a voice signal.

17. The method according to claim 16, characterized in that the adjusting element (22) as a power source has a capacitor (23), wherein the capacitor (23) by means of a sound signal of the membrane element (19) is discharged.

18. The method according to claim 11, characterized in that the length of the sound signal of the membrane element (19) for discharging the capacitor (23) by means of a microprocessor (24) is controlled.

19. Tool with an internal combustion engine, which has a carburetor (100) which is designed according to one of claims 1 to 10.

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