This application claims priority of German patent application no. 10 2008 059 289.7, filed Nov. 27, 2008, the entire content of which is incorporated herein by reference.
The invention relates to a fuel-metering arrangement for the mixture formation unit of an internal combustion engine including an internal combustion engine in a portable handheld work apparatus such as a motor-driven chain saw, cutoff machine, blower apparatus, brushcutter or the like.
U.S. Pat. No. 7,126,449 discloses an electromagnetic fuel valve which functions to meter the fuel quantity to be fed to a mixture-forming unit. The valve member is formed by a valve plate which lies transversely to the flow direction of the fuel. A column of fuel is moved mechanically by a movement of the valve plate whereby the accuracy of a fuel quantity can be affected with this fuel quantity being metered by the valve.
Basically, a liquid column is mechanically moved in each valve with a mechanically moved valve member in the switching operation which, for larger metered quantities, is insignificant in relationship to the metered quantity. However, metering inaccuracies can occur with respect to small quantities in relationship to the metered quantity. This is especially the case with pulsewidth-modulated drive signals with which the valve is driven at a fixed frequency.
It is an object of the invention to configure a fuel-metering system having a fuel-metering valve so that even the smallest fuel quantity can be metered with precision.
The fuel-metering arrangement of the invention is for a mixture-forming unit of an internal combustion engine having an intake region. The fuel-metering arrangement includes: a fuel store; a switchable valve having an inflow port connected to the fuel store; a fuel channel opening into the intake region of the internal combustion engine; the switchable valve having an outflow port connected to the fuel channel; a bypass channel connecting the outflow port to the inflow port and defining a flow direction from the outflow port to the inflow port; and, a flow valve mounted in the bypass channel for opening in the flow direction and closing in a direction opposite to the flow direction.
The outflow port of the valve is connected to the inflow port via a bypass channel. A flow valve is mounted in the bypass channel which opens in flow direction from the outflow port to the inflow port and blocks in the opposite direction. The flow valve is configured similar to a check valve without a valve spring and therefore opens essentially pressureless. The valve member of the flow valve is therefore essentially force free and is opened or closed in correspondence to the volume flow in the bypass channel.
Because of the bypass channel, the mechanically moved fuel column can flow off via the then opening flow valve and is not pressed via the inflow port into the fuel-metering unit. In this way, the metering of even the smallest fuel quantities is possible with precision.
A throttle is formed in the bypass which can be configured by the passthrough cross section of the bypass channel. It can be practical to configure the throttle between the outflow port and the flow valve.
The throttle of the fuel channel, which is connected to the outflow port, is approximately the same as the throttle of the bypass channel and is preferably slightly larger. In this way, the situation is achieved that the mechanically moved fuel column flows off via the bypass channel because of the lower flow resistance therein without the occurrence of an effect on the fuel-metering arrangement.
The fuel-metering arrangement according to the invention is especially provided for small-volume engines, preferably two-stroke engines having a stroke volume of approximately 10 to 200 cm3 and especially approximately 22 to 122 cm3. The fuel quantity, which is metered by the valve, lies in the range of 60 to 300 g/h.
The invention will now be described with reference to the drawings wherein:
In
In the embodiment shown, the engine 10 is a two-stroke engine wherein the intake channel 9 opens into the crankcase 11. The mixture is supplied from the crankcase 11 via transfer channels 12 to a combustion chamber 13 of a cylinder 14. The configuration and operation of the two-stroke engine are of general knowledge.
In the intake channel 9, a throttle flap 15 as well as a choke flap 16 are arranged with the choke flap 16 being mounted upstream of the throttle flap 15 and the flaps influence the underpressure in the intake channel 9 in dependence upon their rotational position in the intake channel 9. The choke flap 16 lies upstream viewed in the flow direction 17 of the combustion air, that is, ahead of the venturi 8; whereas, the throttle flap 15 is arranged downstream of the venturi 8, that is, after the venturi.
The main nozzle 3 opens approximately at the center in the venturi 8 and is connected to the fuel-metering main fuel channel 20 via a flow valve 18 opening in flow direction toward the venturi. Because of the channel cross section, the main nozzle path 19 has a throttling effect which is indicated by the throttle 21.
The idle nozzle path 22 likewise branches off from the main fuel channel 20. A flow valve 23, which opens without pressure, is mounted in the idle nozzle path and this flow valve opens in flow direction from the main fuel channel 20 to the nozzles 5, 6 and 7. The channel cross section of the idle nozzle path 22 has a throttle effect which is indicated by the throttle 24.
The idle nozzle path opens into an idle chamber 25 from which the nozzles 5, 6 and 7 are fed.
The idle nozzle 7 lies downstream of the throttle flap 15 when the throttle flap is in the idle position shown in phantom outline in
The main fuel channel 20 is fed from a fuel store 30 which, in the embodiment shown, is configured as a control chamber of, for example, a membrane carburetor. The membrane 31 of the control chamber controls a feed valve 32 via which fuel is supplied from a fuel tank 34 by means of a fuel pump 33 driven by the changing crankcase pressure. The feed valve 32 is controlled by the membrane 31 of the control chamber 30 so that approximately constant operating pressure can be maintained in the fuel store 30. The main fuel channel 20 branches off from the fuel store 30 and feeds the main nozzle 3 and the idle nozzle system 4.
A switching valve 40, especially an electromagnetic switching valve, is mounted in the main fuel channel 20. The fuel flow in the main channel 20 is controllable via the switching valve 40. For metering a desired fuel quantity, the valve 40 is opened and closed in rapid sequence, that is, the valve 40 is clocked whereby an average fuel flow is adjusted. When the open phases are longer than the closing phases, then a large fuel quantity is permitted and, if the closed phases are longer than the open phases, a low fuel quantity is adjusted. A desired fuel flow in the fuel channel 20 is adjusted by varying the opening and closing times and, in this way, a desired fuel quantity is metered. This type of digital drive of the valve 40 takes place, preferably, at a fixed frequency so that the fuel quantity can be adjusted by controlling the pulsewidth (pulsewidth modulation of switching valve 40).
The electromagnetic valve 40 has a fuel inflow port 41 and a fuel outflow port 42. In the embodiment shown, the valve member 43, which switches the throughflow, is a valve plate which moves in flow direction or opposite to the flow direction 44 of the fuel for closing or opening the valve. Because of the valve stroke (u), the valve member 43 displaces the fuel column which loads the same with a switch movement in flow direction 44 of the fuel or opposite thereto. This can lead to the situation that, when opening the valve 40, fuel is pushed mechanically into the fuel channel 20 and therefore into the main nozzle system and/or idle nozzle system whereby irregularities in the mixture formation can occur.
As shown in
As shown in phantom outline, the valve 40 together with the return-conducting bypass channel 45 is, conjointly, preferably a component 48.
The operation of the system shown in
The engine is at idle when the choke flap 16 is in the opened position as shown in phantom outline and the throttle flap 15 is in the closed position shown in phantom outline. The metering of fuel at idle takes place by clocking the switching valve 40. The fuel quantity, which is supplied at idle, is low. In the embodiment, a fuel flow in the volume range of approximately 60 to 300 g/h is assumed.
In the intake channel of the engine 10, which is configured as a two-stroke engine, a corresponding underpressure is present at the idle nozzle 7 so that the idle system 4 draws a corresponding fuel quantity from the main fuel channel 20. This fuel quantity is metered by the valve 40. The fuel quantity V2, which flows off via the idle nozzle path 22, is very low at idle. For this reason, only a slight underpressure is present at the throttle 35 formed by the channel cross section of the main fuel channel 20. In the opening operation of the switching valve 40, a fuel quantity V1 is moved by the mechanically moved fuel column in addition to the adjusted delivered quantity with V1>V2. This surge-like increasing fuel quantity V1 cannot flow out via the throttle 35 because the suction underpressure of the idle fuel system 4 is only low at throttle 35. The throttle 35 is dynamically slightly greater than the throttle 47 of the bypass channel 45 so that the fuel surge ΔV, which is caused by the switching operation, flows off or is displaced to the inflow port 41 via the flow valve 46 opening in the flow direction. The throttling action of the throttle 47 (channel cross section of the bypass channel 45) and the throttle action of the throttle 35 (channel cross section of the main fuel channel 20) are designed to be approximately equal; preferably, the throttle 35 of the fuel channel 20 has, statically, a slightly greater value than the throttle 47 of the bypass channel 45. The throttle action at the throttle 35 can become less than the throttle 47 of the bypass channel 45 when considering the dynamic underpressure at the throttle 35 of the main fuel channel.
When the throttle flap 15 as well as the choke flap 16 are completely open, then the fuel quantity, which is needed for full-load case of the engine 10, passes via the main nozzle 3 whereby a correspondingly high suction underpressure is present in the main fuel channel 20. Because of the higher underpressure, the effect of the throttle 35 lowers. The throttling action of the throttle 35 is then composed of the geometric dimensions and the suction underpressure of the mixture-forming unit 2 acting at the throttle 35. The fuel column, which is moved mechanically by valve 40, is drawn off by suction via the main nozzle path 19.
The fuel quantity V1, which is metered in the full-load case, is approximately equal to the outflowing fuel quantities V2 and V3. The total metered fuel quantity V1 is drawn by suction into the intake channel 9. In the switching operation of the valve 40, the surge quantity ΔV of the valve 40 is low relative to the outflowing quantities V2 and V3. The high suction underpressure and the large fuel flow through the throttle 35 causes the dynamic throttle action of the throttle 35 to be considerably less than the throttle action of the throttle 47 in the bypass channel. For this reason, the surge quantity ΔV in the mixture-forming unit 2 is drawn off by suction. A fuel flow opposite the arrow direction 49 in the bypass channel 45 cannot occur notwithstanding the high suction underpressure in the main fuel channel 20 because the flow valve 46 closes.
In idle, the influence of the mechanically moved fuel column on the mixture-forming unit 2 is minimized and in the optimal case made irrelevant by the feature of the bypass channel 45 of the invention with the flow valve 46 operating as a check valve. In the full-load case, the flow valve 46 closes and the bypass channel 45 is essentially without effect.
An electromagnetic fuel valve 40 is shown in
It is understood that the foregoing description is that of the preferred embodiments of the invention and that various changes and modifications may be made thereto without departing from the spirit and scope of the invention as defined in the appended claims.
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10 2008 059 289 | Nov 2008 | DE | national |
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English translation and first Office action of the Chinese Patent Office dated Jan. 29, 2013 in the corresponding Chinese patent application 200910246608.1. |
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20100126467 A1 | May 2010 | US |