The present disclosure relates generally to an engine feedback control strategy.
Combustion engines are provided with a fuel mixture that typically includes liquid fuel and air. The air/fuel ratio of the fuel mixture may be calibrated for a particular engine, but different operating characteristics such as type of fuel, altitude, condition of filters or other engine components, and differences among engines and other components in a production run may affect engine operation.
In at least some implementations, an engine control process includes an engine speed test and other steps. The engine speed test includes the steps of a) determining a first engine speed, b) changing the air/fuel ratio of a fuel mixture delivered to the engine, and c) determining a second engine speed after at least some of the air/fuel ratio changing event. Based at least in part on the difference between the first engine speed and the second engine speed it is determined if a change in the air/fuel ratio of the fuel mixture delivered to the engine is needed. If a change to the air/fuel ratio was indicated, the air/fuel ratio of a fuel mixture delivered to the engine is changed.
In at least some implementations, an engine control process includes conducting an engine speed test that includes the steps of: a) determining a first engine speed, h) changing the air/fuel ratio of a fuel mixture delivered to the engine, and c) determining a second engine speed after at least some of the air/fuel ratio changing event. The process further includes providing to the engine a fuel mixture having a desired air/fuel ratio, where the desired air/fuel ratio is determined at least in part as a function of the difference between the first engine speed and the second engine speed.
The following detailed description of preferred embodiments and best mode will be set forth with reference to the accompanying drawings, in which:
Referring in more detail to the drawings.
The engine speed may be determined in a number of ways, one of which uses signals within an ignition system 10 such as may be generated by a magnet on a rotating flywheel 12.
The flywheel 12 rotates about an axis 20 under the power of the engine 2 and includes magnets or magnetic sections 22. As the flywheel 12 rotates, the magnetic sections 22 spin past and electromagnetically interact with components of the control system 14 for sensing engine speed among other things.
The control system 14 includes a ferromagnetic stator core or lamstack 30 having wound thereabout a charge winding 32, a primary ignition winding 34, and a secondary ignition winding 36. The primary and secondary windings 34, 36 basically define a step-up transformer or ignition coil used to fire a spark plug. The control system also includes a circuit 38 (shown in
As the magnetic sections 22 are rotated past the lamstack 30, a magnetic field is introduced into the lamstack 30 that, in turn, induces a voltage in the various windings. For example, the rotating magnetic sections 22 induce a voltage signal in the charge winding 32 that is indicative of the number of revolutions of the engine 2 in the control system. The signal can be used to determine the rotational speed of the flywheel 12 and crankshaft 19 and, hence, the engine 2. Finally, the voltage induced in the charge winding 32 is also used to power the circuit 38 and charge an ignition discharge capacitor 62 in known manner. Upon receipt of a trigger signal, the capacitor 62 discharges through the primary winding 34 of the ignition coil to induce a stepped-up high voltage in the secondary winding 36 of the ignition coil that is sufficient to cause a spark across a spark gap of a spark plug 47 to ignite a fuel and air mixture within a combustion chamber of the engine.
In normal engine operation, downward movement of an engine piston during a power stroke drives a connecting rod (not shown) that, in turn, rotates the crankshaft 19, which rotates the flywheel 12. As the magnetic sections 22 rotate past the lamstack 30, a magnetic field is created which induces a voltage in the nearby charge winding 32 which is used for several purposes. First, the voltage may be used to provide power to the control system 14, including components of the circuit 38. Second, the induced voltage is used to charge the main discharge capacitor 62 that stores the energy until it is instructed to discharge, at which time the capacitor 62 discharges its stored energy across primary ignition winding 34. Lastly, the voltage induced in the charge winding 32 is used to produce an engine speed input signal, which is supplied to a microcontroller 60 of the circuit 38. This engine speed input signal can play a role in the operation of the ignition timing, as well as controlling an air/fuel ratio of a fuel mixture delivered to the engine, as set forth below.
Referring now primarily to
The microcontroller 60 as shown in
To summarize the operation of the circuit, the charge winding 32 experiences an induced voltage that charges ignition discharge capacitor 62, and provides the microcontroller 60 with power and an engine speed signal. The microcontroller 60 outputs an ignition signal on pin 7, according to the calculated ignition timing, which turns on the thyristor 64. Once the thyristor 64 is conductive, a current path through the thyristor 64 and the primary winding 34 is formed for the charge stored in the capacitor 62. The current discharged through the primary winding 34 induces a high voltage ignition pulse in the secondary winding 36. This high voltage pulse is then delivered to the spark plug 47 where it arcs across the spark gap thereof, thus igniting an air-fuel charge in the combustion chamber to initiate the combustion process.
As noted above, the microcontroller 60, or another controller, may play a role in altering an air/fuel ratio of a fuel mixture delivered by a carburetor 4 (for example) to the engine 2. In the embodiment of
For a given throttle position, the power output for an engine will vary as a function of the air/fuel ratio. A representative engine power curve 94 is shown in
The characteristics of the engine power curve 94 may be used in an engine control process 84 that determines a desired air/fuel ratio for a fuel mixture delivered to the engine. One example of an engine control process 84 is shown in
The engine control process 84 begins at 86 and includes one or more engine speed tests. Each engine speed test may essentially include three steps. The steps include measuring engine speed at 87, changing the air/fuel ratio of the fuel mixture provided to the engine at 88, and then measuring the engine speed again at 92 after at least a portion of the air/fuel ratio change has occurred.
The first step is to measure the current engine speed before the fuel mixture is enleaned. Engine speed may be determined by the microcontroller 60 as noted above, or in any other suitable way. This is accomplished, in one implementation, by measuring three engine speed parameters with the first being the cyclic engine speed. This is the time difference for one revolution of the engine. In most engines, there is a large amount of repeatable cyclic engine speed variation along with a significant amount of non-repeatable cyclic engine speed variation. This can be seen in
In addition to measuring engine speed, the engine speed test includes changing the air/fuel ratio of the fuel mixture delivered to the engine. This may be accomplished with the mixture control device, e.g. solenoid valve 8 may be actuated thereby changing an air/fuel ratio of a mixture delivered to the engine 2 from the carburetor 4. In at least some implementations, the solenoid valve 8 may be actuated to its closed position to reduce fuel flow to a main fuel port or jet 90, thereby enleaning the fuel and air mixture. The valve 8 may be closed for a specific time period, or a duration dependent upon an operational parameter, such as engine speed. In one form, the valve 8 is closed (or nearly closed) for a certain number or range of engine revolutions, such as 1 to 150 revolutions. This defines an enleanment period wherein the leaner fuel and air mixture is delivered to the engine 2. Near, at or just after the end of the enleanment period, the engine speed is again determined at 92 as noted above.
Because the process as described involves enleaning a fuel mixture, the initial or calibrated air/fuel ratio should be richer than desired. This ensures that at least some enleanment will lead to a desired air/fuel ratio. In at least some implementations, the initial air/fuel ratio may be up to about 30% richer than the fuel mixture corresponding to peak engine power. Instead of or in addition to Meaning, enriching the fuel mixture may be possible in a given carburetor construction, and in that case the engine speed test could include an enriching step if an unduly lean air/fuel ratio where determined to exist. Enriching may be done, for example, by causing additional fuel to be supplied to the engine, or by reducing air flow. The process may be simpler by starting with a richer fuel mixture and enleaning it, as noted herein.
Referring again to the engine control process shown in
To determine whether the fuel mixture delivered to the engine before the engine speed tests were performed was within a desired range of air/fuel ratios, the engine speed differences determined at 93 are compared against one or more thresholds at 95. Minimum and maximum threshold values may be used for the engine speed difference that occurs as a result of enleaning the fuel mixture provided to the engine. An engine speed difference that is below the minimum threshold (which could be a certain number of rpm's) likely indicates that the air/fuel ratio before that enleanment was richer than a mixture corresponding to peak engine power. Conversely, an engine speed difference that is above the maximum threshold (which could be a certain number of rpm's) indicates that the air/fuel ratio became too lean (indicating the fuel mixture started leaner than a peak power fuel mixture, as noted above). In at least some implementations, the minimum threshold is 15 rpm, and the maximum threshold is 500 rpm or higher. These values are intended to be illustrative and not limiting—different engines and conditions may permit use of different thresholds.
In the process 84 shown in
If a threshold number of engine speed differences (determined at 93) are not within the thresholds, the air/fuel ratio of the mixture may be altered at 103 to a new air/fuel ratio and the engine speed tests repeated using the new air/fuel ratio. At 95, if an undesired number of engine speed differences were less than the minimum threshold, the air/fuel ratio of the fuel mixture may be enleaned at 103 before the engine speed tests are repeated. This is because an engine speed difference less than the minimum threshold indicates the fuel mixture at 87 was too rich. Hence, the new air fuel ratio from 103 is leaner than when the prior engine speed tests were performed. This can be repeated until a threshold number of engine speed differences are within the thresholds, which indicates that the fuel mixture provided to the engine before the engine speed tests were conducted (e.g. at 87) is a desired air/fuel ratio. Likewise, at 95, if an undesired number of engine speed differences were greater than the maximum threshold, the air/fuel ratio of the fuel mixture may be enriched, at 103 before the engine speed tests are repeated. This is because an engine speed difference greater than the maximum threshold indicates the fuel mixture at 87 was too lean. Hence, the new air fuel ratio from 103, in this instance, is richer than when the prior engine speed tests were performed. This also can be repeated until a threshold number of engine speed differences are within the thresholds, with a different starting air/fuel ratio for each iteration of the process.
When a desired number of satisfactory engine speed differences (i.e. between the thresholds) occur at a given air/fuel ratio, that air/fuel ratio may be maintained for further operation of the engine. That is, the solenoid valve 8 may be actuated during normal engine operation generally in the same manner it was for the engine speed tests that provided the satisfactory results.
As noted above, instead of trying to find an engine speed difference (after changing the air/fuel ratio) that is as small as possible to indicate the engine peak power fuel mixture, the process may look for a relatively large engine speed difference, which may be greater than a minimum threshold. This may be beneficial because it can sometimes be difficult to determine a small engine speed difference during real world engine usage, when the engine is under load and the load may vary during the air/fuel ratio testing process. For example, the engine may be used with a tool used to cut grass (e.g. weed trimmer) or wood (e.g. chainsaw). Of course, the engine could be used in a wide range of applications. By using a larger speed difference in the process, the “noise” of the real world engine load conditions have less of an impact on the results. In addition, as noted above, there can be significant variances in cyclic speed during normal operation of at least some small engines making determination of smaller engine speed differences very difficult.
As noted above, the engine load may change as a tool or device powered by the engine is in use. Such engine operating changes may occur while the engine speed test is being conducted. To facilitate determining if an engine operating condition (e.g. load) has changed during the engine speed test, the engine speed may be measured a third time, a sufficient period of time after the air/fuel ratio is changed during an engine speed test to allow the engine to recover after the air/fuel ratio change. If the first engine speed (taken before the fuel mixture change) and the third engine speed (taken after the fuel mixture change and after a recovery period) are significantly different, this may indicate a change in engine load occurred during the test cycle. In that situation, the engine speed change may not have been solely due to the fuel mixture change enleanment) during the engine speed test. That test data may either be ignored (i.e. not used in further calculation) or a correction factor may be applied to account for the changed engine condition and ensure a more accurate air/fuel ratio determination.
In one form, and as noted above, the mixture control device that is used to change the air/fuel ratio as noted above includes a valve 8 that interrupts or inhibits a fluid flow within the carburetor 4. In at least one implementation, the valve 8 affects a liquid fuel flow to reduce the fuel flow rate from the carburetor 4 and thereby enlean the fuel and air mixture delivered from the carburetor to the engine. The valve may be electrically controlled and actuated. An example of such a valve is a solenoid valve. The valve 8 may be reciprocated between open and closed positions when the solenoid is actuated. In one form, the valve prevents or at least inhibits fuel flow through a passage 120 (
In some engine systems, an ignition circuit 38 may provide the power necessary to actuate the solenoid valve 8. A controller 60 associated with or part of the ignition circuit 38 may also be used to actuate the solenoid valve 8, although a separate controller may be used. As shown in
The timing of the solenoid valve, when it is energized during the portion of the time when fuel is flowing into the fuel and air mixing passage, may be controlled as a calibrated state in order to determine the normal air/fuel ratio curve. To reduce power consumption by the solenoid, the fuel mixture control process may be implemented (that is, the solenoid may be actuated) during the later portion of the time when fuel flows to the fuel and air mixing passage (and fuel generally flows to the filet metering chamber during the engine intake stroke). This reduces the duration that the solenoid must be energized to achieve a desired enleanment. Within a given window, energizing the solenoid earlier within the fuel flow time results in greater enleanment and energizing the solenoid later results in less enleanment. In one example of an enleanment test, the solenoid may be energized during a brief number of revolutions, such as 30. The resultant engine speed would be measured around the end of this 30 revolution enleanment period, and thereafter compared with the engine speed before the enleanment period.
With a 4-stroke engine, the solenoid actuated enleanment may occur every other engine revolution or only during the intake stroke. This same concept of operating the solenoid every other revolution could work on a 2-stroke engine with the main difference being the solenoid energized time would increase slightly. At slower engine speeds on a 2-stroke engine the solenoid control could then switch to every revolution which may improve both engine performance and system accuracy.
It is also believed possible to utilize the system to provide a richer air/fuel mixture to support engine acceleration. This may be accomplished by altering the ignition timing (e.g. advancing ignition timing) and/or by reducing the duration that the solenoid is energized so that less enleanment, and hence a richer fuel mixture, is provided. When the initial carburetor calibration is rich (e.g. approximately 20-25% rich), no solenoid actuation or less solenoid actuation will result in a richer fuel mixture being delivered to the engine. Further, if the amount of acceleration or acceleration rate can be sensed or determined, a desired enrichment amount could be mapped or determined based on the acceleration rate. Combining both the ignition timing advance and the fuel enrichment during transient conditions, both acceleration and deceleration can be controlled for improved engine performance. Ignition timing may be controlled, in at least some implementations, as disclosed in U.S. Pat. No. 7,000,595, the disclosure of which is incorporated by reference herein, in its entirety.
Idle engine speed can be controlled using ignition spark timing. While not wishing to be held to any particular theory, it is currently believed that using a similar concept, fuel control could be used to improve the idle engine speed control and stability. This could be particularly useful during the end of transient engine conditions such as come-down. The combination of ignition and fuel control during idle could improve engine performance.
Finally, when the basic carburetor calibration is rich (for example, but not limited to, 20-25% rich), it is possible to use a combination of a thermistor in an ignition module and a run clock event, such as revolutions from start up or a straight running clock time, to determine a desired enrichment amount to provide to facilitate engine warm-up and improve the stability of engine operation during warm-up.
While the forms of the invention herein disclosed constitute presently preferred embodiments, many others are possible. It is not intended herein to mention all the possible equivalent forms or ramifications of the invention. It is understood that the terms used herein are merely descriptive, rather than limiting, and that various changes may be made without departing from the spirit or scope of the invention.
This application claims the benefit of PCT/US2015/059376 application filed on Nov. 6, 2015; PCT/US2014/024121 application filed on Mar. 14, 2014; U.S. Provisional Application No. 62/075,945 filed on Nov. 6, 2014 and U.S. provisional Application No. 61/794,389 filed Mar. 15, 2013 each of which is incorporated herein by reference in its entirety.
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