1. Field of the Invention
The present invention relates to small internal combustion engines of the type used with lawnmowers, lawn and garden tractors, other small implements, or in sport vehicles, for example. In particular, the present invention relates to determining engine cycle recognition, or piston stroke recognition, in such engines for fuel delivery by a fuel injection system.
2. Description of the Related Art
Small internal combustion engines, such as single or two cylinder engines, are supplied with a fuel/air mixture for combustion via either a carburetor or by a fuel injection system in a conventional four cycle operation, including the piston strokes of intake, compression, power, and exhaust. In small engines which include a fuel injection system, it is important to determine the phase or stroke of the cylinder piston(s) in order to ensure that fuel is injected into the cylinders at the optimum point during the intake stroke of the piston(s).
In many known systems for determining piston stroke recognition, electronic sensors are used to sense the position of the engine crankshaft and/or camshaft. Signals generated from these sensors are used to coordinate the position and speed of the crankshaft or camshaft with the position of one or more pistons to determine when to inject fuel into the engine cylinders. Disadvantageously, these systems require separate sensors to be mounted to the engine, which tends to increase the overall cost and complexity of the fuel injection systems for small internal combustion engines.
Additionally, some small engines may experience high inertial loads during running, such as engines which drive a high inertia implement through a belt drive, for example. In these engines, it has been found that the inertia of the driven implement and the elasticity of the belt, for example, may impose a strong load on the engine crankshaft. At certain times during running the engine, this imposed load primarily determines the crankshaft speed, rather than the actual firing of the engine cylinders. Under these circumstances, piston stroke recognition methods which are dependent upon sensing crankshaft or camshaft speed may be prone to failure.
What is needed are piston stroke recognition methods for small internal combustion engines which are an improvement over the foregoing.
The present invention provides piston stroke recognition methods for small internal combustion engines, such as single and two cylinder engines, in which the ignition-related trigger pulses corresponding to the engine cylinders are the only input signal used for stroke recognition. In a first method, the time periods of a plurality of crankshaft revolutions are measured upon engine start-up, from which an average engine speed is obtained. For an exemplary V-twin engine having its cylinders spaced 90° from one another, a time period and corresponding crankshaft speed is also determined between the successive ignition-related trigger pulses of the second and first cylinders, which encompasses 270° of crankshaft revolution. This speed is compared to the average engine speed to determine the stroke or phase of each cylinder.
As an enhancement to the foregoing first method, two running averages of odd and even periods of crankshaft revolution are measured, from which average crankshaft speeds are calculated. By comparing one or both of these two running averages with the average engine speed, stroke recognition can be determined accurately even if variations are present in the average engine speed, for example, if a strong load is imposed from time to time on the engine, such as by a high inertia driven implement, for example. In this manner, the foregoing first method filters or removes inertial load effects on the engine which could potentially lead to inaccurate stroke recognition.
In a second, different method, with reference to an exemplary V-twin engine, a first time period between successive ignition-related trigger pulses for one of the cylinders is measured upon engine start-up, which corresponds to a first crankshaft revolution. Thereafter, a second time period between successive ignition-related trigger pulses for the cylinder is measured, which corresponds to a second, subsequent crankshaft revolution. These two time periods, which have different durations, are then compared with one another to determine the stroke or phase of the piston for that cylinder. In a two cylinder engine, once the stroke or phase of the piston for the one cylinder is determined, the stroke or phase of the piston for the other cylinder is known or readily determined from the known engine timing.
Further, each of the foregoing methods is also operable for determining piston stroke recognition in a single cylinder engine.
Advantageously, each of the present methods allows the determination of the stroke of one or more pistons in an engine using only the ignition-related trigger pulses of the engine's ignition system, corresponding to the engine cylinders, as the only input signal for stroke recognition. Thus, the need for complex and expensive crankshaft and/or camshaft position sensors is obviated. In this manner, the present methods are readily and economically suitable for small internal combustion engines.
In one form thereof, the present invention provides, in an internal combustion engine including a crankshaft and at least one cylinder having a piston reciprocating therein according to a four-stroke cycle of intake, compression, power, and exhaust, a method for determining the stroke of a piston, including the steps of generating an ignition-related event for each cylinder during each revolution of the crankshaft; obtaining an average engine speed; determining the duration of a plurality of periods between successive ignition-related events, each period corresponding to at least a portion of at least one of an even and odd crankshaft revolution; obtaining an average duration for the plurality of periods; and determining the stroke of a piston by comparing the average duration for the plurality of periods to the average engine speed.
In another form thereof, the present invention provides, in an internal combustion engine including a crankshaft and a pair of cylinders arranged X° from one another, each cylinder including a piston reciprocating therein according to a four-stroke cycle of intake, compression, power, and exhaust, a method for determining the stroke of a piston, including the steps of generating an ignition-related event for each cylinder during each crankshaft revolution; obtaining an average engine speed; determining the duration of at least one (360°−X°) period between successive ignition-related events of the engine cylinders; and determining the stroke of a piston by comparing the duration of the (360°−X°) period to the average engine speed.
In a further form thereof, the present invention provides, in an internal combustion engine including a crankshaft and a pair of cylinders arranged substantially X° from one another, each cylinder including a piston reciprocating therein according to a four-stroke cycle of intake, compression, power, and exhaust, a method for determining the stroke of a piston, including the steps of generating an ignition-related event for each cylinder during each crankshaft rotation; determining the durations of a plurality of 360° periods between successive ignition-related events of one of the cylinders; obtaining an average engine speed from the durations of the 360° periods; determining the durations of even and odd (360°−X°) periods between successive ignition-related events of the engine cylinders; obtaining average speeds from the durations of the even and odd (360°−X°) periods; and determining the stroke of a piston by comparing the average speed from the even and odd (360°−X°) periods to the average engine speed.
Another, different method, the present invention provides, in an internal combustion engine including a crankshaft and a pair of cylinders arranged at an angle with respect to one another, each cylinder including a piston reciprocating therein according to a four-stroke cycle of intake, compression, power, and exhaust, a method for determining the stroke of a piston, including the steps of: generating an ignition-related event for each of the cylinders during each crankshaft revolution; determining the durations of a plurality of first periods between successive ignition-related events of one of the engine cylinders corresponding to odd crankshaft revolutions; obtaining an average duration for the plurality of first periods; determining the durations of a plurality of second periods between successive ignition-related events of the one engine cylinder corresponding to even crankshaft revolutions; obtaining an average duration for the plurality of second periods; and comparing the average duration for the plurality of first periods with the average duration for the plurality of second periods.
The above-mentioned and other features and advantages of this invention, and the manner of attaining them, will become more apparent and the invention itself will be better understood by reference to the following description of embodiments of the invention taken in conjunction with the accompanying drawings, wherein:
Corresponding reference characters indicate corresponding parts throughout the several views. The exemplifications set out herein illustrate preferred embodiments of the inventions, and such exemplifications are not to be construed as limiting the scope of the inventions any manner.
In
First and second cylinders 12 and 14 include first and second spark plugs 20 and 22, respectively. Flywheel 18 includes permanent magnet 24, and first and second cylinders 12 and 14 include first and second trigger coils 26 and 28 electrically connected to first and second spark plugs 20 and 22, respectively. Trigger coils 26 and 28 are disposed on or proximate first and second cylinders 12 and 14, respectively, and are also disposed closely proximate magnet 24, which passes close to trigger coils 26 and 28 as flywheel 18 rotates during running of engine 10.
Generally, engine 10 operates according to a capacitive discharge-type ignition system, in which magnet 24 generates electrical pulses as it rotates past a charge coil (not shown) and trigger coils 26 and 28. These coils are positioned such that when magnet 24 passes the charge coil, a charge pulse is generated which charges a capacitor (not shown) during the compression stroke of each cylinder 12 and 14. When magnet 24 passes each trigger coil 26 and 28, a trigger pulse is generated which discharges the capacitor and fires spark plugs 20 and 22, respectively, near the top of the compression stroke for each cylinder 12 and 14, thereby igniting the compressed fuel/air mixture in each cylinder 12 and 14 to drive engine 10. Further details regarding this type of capacitive discharge ignition system are set forth in U.S. Pat. No. 6,273,065, assigned to the assignee of the present invention, the disclosure of which is incorporated herein by reference.
As discussed below, even though the first and second stroke recognition methods operate differently, the first and second stroke recognition methods each use an ignition-related event as the only input signal for sensing engine timing and determining piston stroke recognition. This ignition-related event may be the foregoing ignition-related trigger pulses of the engine cylinders, such as the trigger pulses of spark plugs 20 and 22, but could also be any other ignition-related pulse or voltage change produced by the electronic ignition system of engine 10. Advantageously, sensors associated with crankshaft 16 or the camshaft of engine 10, such as optical or variable reluctance sensors, which measure the speed and/or position of the crankshaft or camshaft, are not needed with the present methods.
With reference to
In
Notably, for each cylinder 12 and 14, the piston in the cylinder will be completing its compression stroke when the trigger pulse is generated on one particular crankshaft revolution, and the piston will be completing its exhaust stroke when the trigger pulse is generated on the preceding or subsequent crankshaft revolution. In order to determine when to inject fuel into each cylinder 12 and 14, it is necessary to determine the position of its piston such that fuel is only injected in each cylinder 12 and 14 during its intake stroke.
Upon engine startup, the trigger pulses of either one of the two engine cylinders 12 and 14 are used to calculate the time durations of a plurality of crankshaft revolutions. For example, as shown in
Thereafter, a time period P2 is determined between the successive trigger pulses TP2 and TP1 of second cylinder 14 and first cylinder 12, respectively, a period which encompasses 270° of crankshaft revolution in engine 10, in which first and second cylinders 12 and 14 are spaced 90° from one another. However, because the spacing between first and second cylinders 12 and 14 may vary, period P2 may be more generally expressed as (360°−X°), where X° corresponds to the angular spacing between first and second cylinders 12 and 14. Once period P2 is measured, a crankshaft speed is determined therefrom.
The crankshaft speed for the 270° portion of period P1 which corresponds to period P2 is calculated as (¾*P1) where ¾ is derived from 270° period being ¾ of the complete 360° crankshaft revolution. One period P2, or an average of a number of periods P2, is then compared with the foregoing calculated value for the average engine speed. Referring to
The deviation of each period P2 from the average engine speed results from the fact that crankshaft 16 rotates slower than the average engine speed when one or both of cylinders 12 and 14 is in a gas exchange stroke, such as the intake and exhaust strokes. Crankshaft 16 rotates faster than the average engine speed when one or both of cylinders 12 and 14 is in its power stroke. Based upon the known timing of engine 10, once the stroke or phase of the piston of second cylinder 14 is determined, the stroke or phase of the piston of first cylinder 12 is also known. In this manner, the stroke of the pistons of both first and second cylinders 12 and 14 can be determined.
Notably, the period corresponding to the angular spacing X° between first cylinder 12 and second cylinder 14 may also be used in the above manner to determine the stroke of the piston of each cylinder. For example, in engine 10, the 90° period between the trigger pulse TP1 of first cylinder 12 and the following trigger pulse TP2 of second cylinder 14 may be used. However, it has been determined from experimentation that use of the above-described longer period P2 (360°−X°), such as 270° between trigger pulses TP2 and TP1 for second and first cylinders 14 and 12 typically results in a more robust piston stroke determination.
The foregoing first method works well for V-twin engines which directly drive a low inertia implement, such as when a small blade is directly attached to crankshaft 16. In these types of engines, the inertial load from the driven implement on crankshaft 16 are typically low during running of engine 10, such that the average speed of engine 10 is relatively constant, and thereby serves as a good comparison point for discriminating the strokes of the pistons of the first and second cylinders 12 and 14.
However, in V-twin engines which drive high inertial loads, such as a high inertia implement through a belt drive, for example, it has been found that the inertia of the driven implement and/or the elasticity of the belt may impose a strong load on crankshaft 16. At certain times during running of engine 10, this strong, imposed load effects the engine speed. Under these circumstances, the calculated average engine speed is not constant, and the foregoing first method of cycle of recognition may be inaccurate.
In order to compensate for this phenomenon, the first piston stroke recognition method may be enhanced, as described below. In the enhanced methodology, the average crankshaft speed is calculated in the same manner as above.
However, in the enhancement of the first method, two running averages of “odd” and “even” periods P2 are used. In other words, the time duration of every other period P2 (i.e., the “odd” periods) are measured and an average crankshaft speed for those periods P2 is calculated. At the same time, the other (“even”) periods, shown in
By comparing one or both of these average crankshaft speeds for odd periods P2 and even periods P3 with the average engine speed, stroke recognition can be determined accurately even if a strong load is imposed from time to time on the engine by the implement and/or belt drive. In this manner, potential errors due to the implement inertia and belt elasticity effect are filtered out.
Referring to
In steps 30 and 32, TP2 and TP1 trigger events are detected, respectively, with the method initiated by a TP2 trigger event. Optionally, the method may begin upon a detection of acceleration or deceleration of crankshaft 16 of engine 10. In step 34, the time of an initial TP2 is saved, and an initial period P1 is calculated from subtracting a second, subsequently detected TP2 from the initial TP2. In this manner, a number of periods P1 may be calculated in step 34. Concurrently, in step 36, the time of an initial TP1 following the initial TP2 is saved, and an arbitrary determination is made in step 38 whether an odd or even revolution of crankshaft 16 of engine 10 is occurring. In subsequent steps 40 and 42, a number of odd and even periods P2 and P3 are calculated by subtracting detected TP1 events from previously detected TP2 events, and several such periods P2 and P3 are added to one another in steps 44 and 46.
In step 48, a determination is made whether a predetermined number of crankshaft revolutions, corresponding to a predetermined averaging period, has been completed for periods P1, P2, and P3 by detecting from the total number of elapsed detected TP2 (or optionally, TP1) events. The number of crankshaft revolutions corresponding to the averaging period may vary as desired. Generally, the lesser number of crankshaft revolutions used for the averaging period allows the method to make a piston stroke recognition determination faster. However, the larger number of crankshaft revolutions used for the averaging period generally increases the accuracy of the method. One exemplary number of revolutions is 100, which provides 100 individual periods P1 from which to obtain the average period P1 (AveP1), and 50 individual periods for each of periods P2 and P3 from which to obtain the average periods P2 and P3 (AveP2 and AveP3). In step 50, the averages of periods P1, P2, and P3 are calculated by dividing each of totals for the added periods P1, P2, and P3 by the number of predetermined crankshaft revolutions in the averaging period to obtain AveP1, AveP2, and AveP3, respectively.
In step 52, the average engine speed over the 270° period between TP2 and TP1 is calculated as P1(270)=(¾*AveP1). In step 54, the deviations of AveP2 and AveP3 from the average engine speed over the 270° period between TP2 and TP1 are determined as DevP2 and DevP3, respectively, by subtraction of AveP2 and AveP3 from the foregoing average engine speed over the 270° period from TP2 and TP1.
In step 56, the change in deviation, ΔDev, is calculated by subtracting DevP3 from DevP2. In step 58, ΔDev is compared to a time threshold, which in the present method is 25 microseconds (μsec). However, the threshold may vary as desired. If ΔDev is greater than the threshold, then cylinder 14 was on its intake stroke in period P2. If ΔDev is not greater than the threshold, a determination is made in step 60 whether negative ΔDev (−ΔDev) is greater than the threshold. If negative ΔDev (−ΔDev) is greater than the threshold, then cylinder 14 was on its intake stroke in period P3. The foregoing determinations may be compared with the initial assumption to determine whether the initial assumption was correct, and thereby determine whether the timing of fuel injection into cylinders 12 and 14 of engine 10 need be modified.
In step 60, if negative ΔDev (−ΔDev) is not greater than the threshold, then the value obtained for ΔDev during running of the present method is considered not to deviate from the threshold enough for an accurate determination of stroke recognition to be made. In this instance, the timing of the injection of fuel into cylinders 12 and 14 of engine 10 continues to operate based upon the initial assumption, and the foregoing method repeats until ΔDev differs from the threshold to the extend that an accurate determination of stroke recognition can be made.
The foregoing first method may also be used to discriminate the stroke of the piston in a single cylinder engine, in which a single trigger pulse is generated for the cylinder during each crankshaft revolution. First, an average engine speed is determined from measuring a plurality of periods between successive trigger pulses, each period corresponding to one crankshaft revolution. Thereafter, one period between successive trigger pulses is measured, a crankshaft speed is determined therefrom, and this crankshaft speed is then compared to the average engine speed. If the crankshaft speed is less than the average engine speed, then the piston was in its intake stroke during that period. If the crankshaft speed is greater than the average engine speed, then the piston was in its power stroke during that period. Further, the average of a number of “odd” or “even” periods between trigger pulses may be compared to the average engine speed to filter out variations in engine speed based upon engine load or other factors.
With reference to
In
Notably, for each cylinder 12 and 14, the piston in the cylinder will be completing its compression stroke when the trigger pulse is generated on one particular crankshaft revolution, and the piston will be completing its exhaust stroke when the trigger pulse is generated on the preceding or subsequent crankshaft revolution. In order to determine when to inject fuel into each cylinder 12 and 14, it is necessary to determine the position of its piston such that fuel is only injected in each cylinder 12 and 14 during its intake stroke and not during its exhaust stroke.
Upon engine startup, the trigger pulses of either one of the two engine cylinders 12 and 14 are used to calculate the time durations of two or more successive crankshaft revolutions. For example, as shown in
As discussed further below, in V-twin engines such as engine 10, the durations of periods P1 and P2 are not equal, and may be compared to one another to determine the stroke or phase of the pistons of the engine cylinders. For the exemplary V-twin engine 10 having the timing shown in
Once the stroke or phase of the piston of second cylinder 14 is determined in this manner, the stroke or phase of the piston of first cylinder 12 may be extrapolated from the known timing of engine 10. From this data, the fuel injection system of engine 10 is controlled to inject fuel into first and second cylinders 12 and 14 only during their respective intake strokes.
The difference in the duration of periods P1 and P2 is due the variation in the instantaneous speed of crankshaft 16 of engine 10. Referring to
Alternatively, as shown in
However, it has been determined from experiment that with respect to the exemplary engine 10, the difference between the durations of periods P1 and P2, measured using the ignition trigger pulses TP2 of second cylinder 14, is greater than the difference between the durations of periods P3 and P4, measured using the ignition trigger pulses TP1 of first cylinder 12. Due to the foregoing, comparing periods P1 and P2 typically yields a more robust determination of the stroke or phase of the pistons of first and second cylinders 12 and 14 than comparing periods P3 and P4.
The foregoing second method works well for V-twin engines which directly drive a low inertia implement, such as when a small blade is directly attached to crankshaft 16. In these types of engines, the inertial load from the driven implement on crankshaft 16 is low during running of engine 10, such that the average instantaneous speed of crankshaft 16 is relatively constant for each period P1 and P2 and therefore, these periods may be readily compared for discriminating the cycles of first and second cylinders 12 and 14.
However, in V-twin engines which drive high inertial loads, such as a high inertia implement through a belt drive, for example, it has been found that the inertia of the driven implement and/or the elasticity of the belt may impose a strong load on crankshaft 16. At certain times during running of engine 10, this strong, imposed load primarily determines the engine speed, rather than the actual firing of first and second cylinders 12 and 14. Under these circumstances, the instantaneous speed of crankshaft 16 within each period between successive ignition trigger pulses may vary from that shown in
In order to compensate for this phenomenon, the piston stroke recognition method of
Referring to
In step 70, a TP2 trigger event is detected to initiate the second method. Optionally, the method may also be initiated upon detection of a TP1 trigger event, as noted above, and/or may begin upon a detection of acceleration or deceleration of crankshaft 16 of engine 10. In step 72, the time of an initial TP2 is saved, and an arbitrary determination is made in step 74 as to whether an odd or even revolution of crankshaft 16 of engine 10 is occurring. In steps 76 and 78, a number of odd and even periods P1 and P2 are calculated by subtracting odd and even detected TP2 events from previously detected TP2 events, and several such periods P1 and P2 are added to one another in steps 80 and 82.
In step 84, a determination is made whether a predetermined number of crankshaft revolutions, corresponding to a predetermined averaging period, has been completed for periods P1 and P2 by detecting the total number of elapsed detected TP2 events. Generally, the lesser number of crankshaft revolutions used for the averaging period allows the method to make a piston stroke recognition determination faster. However, the larger number of crankshaft revolutions used to the averaging period generally increases the accuracy of the method. One exemplary number of revolutions is 100, which provides 50 individual periods P1 from which to obtain the average period P1 (AveP1), and 50 individual periods P2 from which to obtain the average period P2 (AveP2). In step 86, the averages of each of the accumulated periods P1 and P2 are calculated by dividing each of the totals for the added periods P1 and P2 by the number of predetermined crankshaft revolutions in the averaging period to obtain AveP1 and AveP2, and the P1 and P2 accumulators and average count are reset.
In step 88, a determination is made as to whether AveP1 is greater than AveP2. If AveP1 is greater than AveP2, then AveP2 is subtracted from AveP1 in step 90 to obtain Δ1, a positive value. If AveP1 is less than AveP2, then AveP1 is subtracted from AveP2 in step 92 to obtain Δ2, again a positive value. In steps 94 or 96, Δ1 or Δ2 is compared to a threshold, which in the present method is 25 microseconds (μsec). However, the threshold may vary as desired. If Δ1 or Δ2 is greater than the threshold, then an accurate determination can be made of the stroke of the pistons in cylinders 12 and 14. Specifically, if Δ1 is greater than the threshold, then the piston in cylinder 14 was in its intake stroke during periods P1, and if Δ2 is greater than the threshold, then the piston in cylinder 14 was in its power stroke during periods P1. If Δ1 or Δ2 is not greater than the threshold, then an accurate determination cannot be made of the stroke of the pistons in cylinders 12 and 14, and the method is repeated until a value for Δ1 or Δ2 is obtained which is greater than the threshold.
The foregoing second method may also be used to discriminate the stroke of the piston in a single cylinder engine, in which a single ignition trigger pulse is generated for each crankshaft revolution. A first period is measured between successive trigger pulses corresponding to one crankshaft revolution. A second period is then measured between successive trigger pulses corresponding to a subsequent crankshaft revolution. Thereafter, the durations of the periods are compared with one another, with the shorter period corresponding to the power stroke of the piston and the longer period corresponding to the intake stroke of the piston. Further, the average of a number of “odd” or “even” periods between trigger pulses may be compared with one another to filter out variations in engine speed based upon engine load or other factors.
While this invention has been described as having a preferred design, the present invention can be further modified within the spirit and scope of this disclosure. This application is therefore intended to cover any variations, uses, or adaptations of the invention using its general principals. Further, this application is intended to cover such departures from the present disclosure as come within known or customary practice in the art to which this invention pertains and which fall within the limits of the appended claims.
This application claims the benefit under Title 35, U.S.C. § 119(e) of U.S. Provisional Patent Application Ser. No. 60/494,136, entitled ENGINE CYCLE RECOGNITION FOR FUEL DELIVERY, filed on Aug. 11, 2003, as well as U.S. Provisional Patent Application Ser. No. 60/495,162, entitled ENGINE CYCLE RECOGNITION FOR FUEL DELIVERY, filed on Aug. 14, 2003.
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