This application claims priority of German patent application no. 10 2005 002 272.3, filed Jan. 18, 2005, the entire content of which is incorporated herein by reference.
The invention relates to a two-stroke engine especially in a handheld work apparatus such as a motor-driven chain saw, cutoff machine or the like.
A two-stroke engine is known from U.S. Pat. No. 6,851,402 to which fuel is supplied via an electronically controlled injection valve. The injection valve opens with an injection nozzle into the transfer channel. The injection takes place in dependence upon the engine speed (rpm) at pregiven positions of the piston. Accordingly, the control of the injection valve is connected to a unit which determines the rpm of the crankshaft.
It is an object of the invention to provide a two-stroke engine which has a simple configuration.
The two-stroke engine of the invention includes: a cylinder; a piston mounted in the cylinder to undergo a reciprocating movement along a stroke path between top dead center and bottom dead center during the operation of the engine; the cylinder and the piston conjointly delimiting a combustion chamber; a crankcase connected to the cylinder; a crankshaft rotatably mounted in the crankcase; the piston being connected to the crankshaft for imparting rotational movement to the crankshaft; a fuel tank; a fuel line for conducting fuel from the fuel tank; an electromagnetic valve mounted in the fuel line; an air channel for supplying combustion air to the engine; a transfer channel for connecting the combustion chamber to the crankcase at pregiven positions of the piston; a spark plug projecting into the combustion chamber; a control unit for controlling the electromagnetic valve; an ignition module for triggering the ignition of the spark plug; and, the control unit and the electromagnetic valve being integrated into the ignition module.
The ignition module triggers the ignition of the spark plug. For this purpose, the ignition module has a coil in which a voltage is induced by the rotation of the crankshaft at pregiven positions of the piston. The rpm of the crankshaft can be determined from the time-dependent course of the induced voltage. Accordingly, the induced voltage can function as an input signal for the control of the electromagnetic valve. A simple configuration of the two-stroke engine can be achieved in that the valve and the control unit of the valve are integrated into the ignition module. In this way, connecting leads between the valve, the control unit and the ignition module are unnecessary. The complexity of assembly, especially the complexity for the wiring of the components is reduced and the potential for a defect in the wiring of the components is considerably reduced.
Preferably, the valve is mounted with the ignition module in a common housing. However, it can also be practical that the ignition module and the valve are cast with each other. It is practical that a CPU, that is, a central processing unit, is integrated into the ignition module. Via the CPU, the ignition time point of the spark plug as well as the time point at which the two-stroke engine is supplied with fuel via the electromagnetic valve can be controlled. With the arrangement of a CPU in the ignition module, the fuel introduction and the ignition can be controlled and can be so matched to each other that an optimal running performance of the two-stroke engine results. Other operations (which are to be controlled) of the apparatus, on which the two-stroke engine is mounted, can also be carried out by the CPU. In a portable handheld work apparatus such as a motor-driven chain saw or the like, this can, for example, be the control of the handle heater or the collection of operating data and preparing these operating data for readout when servicing the work apparatus.
The ignition module is advantageously mounted on the cylinder in the region of a transfer channel. In this region, the valve can introduce the fuel into the transfer channel. The lead to the spark plug can be configured to be short. At the same time, the ignition module can be mounted in the peripheral region of a fan wheel so that a good cooling of the ignition module results. A fuel pump is mounted upstream of the valve. The fuel pump moves fuel from the fuel tank to the valve and ensures that the fuel, which is introduced into the two-stroke engine, is under a certain pressure and is well atomized. The fuel pump is advantageously a membrane pump which is connected via a pulse line to a region of the two-stroke engine wherein a fluctuating pressure is present. No additional energy is needed for operating the membrane pump; instead, the pressure fluctuations present in the two-stroke engine can be used. This is especially advantageous in portable handheld work apparatus wherein no additional energy supply such as a battery or the like is available.
Advantageously, the valve is connected via a pressure controller to the fuel pump. In this way, and in a simple manner, a constant pressure is ensured at the valve. Especially, the pressure controller is connected to the fuel tank via a return line. In this way, the fuel can flow back into the tank when the pressure is too high.
An advantageous arrangement results when the fuel pump is integrated into the ignition module. The pulse line advantageously opens into the transfer channel. In this way, a short path for the pulse line results so that the pressure drop in the pulse line is low and a good pumping result is obtained. The ignition module need only be connected via a fuel line to the fuel tank. Additional line connections for the fuel are not needed so that a simple configuration of the two-stroke engine and a simple assembly result.
It can, however, also be practical that the fuel pump is mounted in the fuel tank. This facilitates the starting of the pump. The fuel pump can, however, also be mounted on the crankcase. The pulse line opens especially into the crankcase. It is practical to integrate the pulse line in a connecting flange of the fuel pump mounted on the crankcase. In this way, a high pressure is achieved in the pulse line so that a good pumping result is obtained.
A throttle flap is pivotally journalled in the intake channel and the fuel pump is mounted in the throttle flap housing. The pulse line is configured in the connecting stub for the air channel. In this way, no separate lines for the pulse line are needed and the pulse line can be configured to be short. During operation of the two-stroke engine, lower temperatures are present in the region of the throttle flap housing so that an improved cooling of the fuel pump is achieved. In this way, vapor bubbles, which form in the fuel, are reduced.
To ensure that the two-stroke engine can be easily started, it is provided that the valve is open in the deenergized state. At first, no voltage is applied to the valve when starting the two-stroke engine. The voltage must be induced at the ignition module by the manual start-up. No starting of the two-stroke engine is possible before the voltage is not sufficient to open a currentless closed valve. For a valve open in the currentless state, the fuel can, in contrast, be drawn by suction into the combustion chamber by the applied underpressure so that an ignitable mixture can be made ready sooner. Advantageously, the valve projects into the transfer channel. For this reason, the ignition module, which is mounted at the transfer channel, can be configured to be compact. At the same time, the position of the valve in the transfer channel is favorable in order to generate a combustible mixture and to introduce fuel into the crankcase for lubrication. An injection nozzle is mounted downstream of the valve and this injection nozzle projects into the transfer channel. The arrangement of an injection nozzle can improve the atomization of the fuel and therefore the mixture preparation. The valve is especially integrated into the injection nozzle so that the number of components is reduced.
The invention will now be described with reference to the drawings wherein:
The two-stroke engine 1 shown in
A spark plug 8 projects into the combustion chamber 5 and is connected to an ignition module 20 via a lead 19. The ignition module 20 is fixed on the cylinder 2 in the region of the transfer channel 12. The ignition module 20 includes a sheet metal packet 26 having a winding (not shown). The sheet metal packet 26 is mounted at the periphery of the fan wheel 11 (shown in phantom outline in
An electromagnetic valve 18 is integrated into the ignition module 20. The electromagnetic valve 18 is especially mounted in the housing 35 of the ignition module 20. The valve 18 can, however, also be cast with the ignition module 20. The electromagnetic valve 18 is driven by a control unit which is likewise integrated into the ignition module 20 and this control unit is advantageously the CPU which controls also the ignition time point. The valve 18 opens into the transfer channel 12. The valve 18 is fed by a fuel line 14 which is connected via a fuel store 17 to the fuel pump 16 mounted in the fuel tank 13. The fuel store 17 advantageously has a pressure controller 39 which is connected via a return line 15 to the fuel tank 13. The fuel pump 16 is connected via a pulse line 22 to the crankcase interior space. The fuel pump 16 is configured as a membrane pump and is driven by the fluctuating pressure in the crankcase 3. However, a pump having a different configuration can be utilized as the fuel pump 16. The fuel pump 16 pumps the fuel from the fuel tank 13 into the fuel store 17 from where it reaches the transfer channel 12 via the fuel line 14 and the valve 18. The fuel pump 16 can also be connected directly to the valve 18 without a fuel store being connected therebetween. A decompression valve 9 projects into the combustion chamber 5. The combustion chamber 5 is vented via the decompression valve 9 so that, when starting the engine, the piston 7 in the cylinder 2 need not be moved against the pressure in the combustion chamber 5.
The ignition module 20 is mounted at the outer periphery of the fan wheel 11 in the region of the transfer channel 12. In this region, the ignition module 20 is well cooled by the cooling air flow. The cylinder 2 has cooling ribs 24 for providing an excellent dissipation of heat.
As shown in
The two-stroke engine 41 shown in
In the two-stroke engine 51 shown in
Parts subjected to wear of the electromagnetic valve 18 can be exchanged. Also, the parts subject to wear on the fuel pump, such as the membrane of the fuel pump, are exchangeable. In this way, a long service life of the two-stroke engine is ensured. The air channel 27 can also be connected via valves, for example, check valves, to the transfer channel(s) 12.
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.
Number | Date | Country | Kind |
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10 2005 002 272 | Jan 2005 | DE | national |
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Number | Date | Country | |
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20060157005 A1 | Jul 2006 | US |