The present invention relates to a spark ignition type engine.
In the conventional engine, in a case where the base lower limit value of the valve opening degree is corrected to increase by the atmospheric pressure, when the base lower limit value is large, the lower limit value becomes too large by the increase correction, and excessive engine rotation may occur. In this case, engine noise or gear noise during gear shift may occur.
An object of the present invention is to provide a spark ignition type engine capable of adjusting a base lower limit value of a valve opening degree of an ISC valve capable of avoiding excessive engine rotation that may occur when an increase correction by atmospheric pressure is performed.
The main configuration of the present invention is as follows.
The spark ignition type engine is configured such that
as a detected engine temperature becomes lower, a base lower limit value (4b) of an ISC valve opening degree is increased (4ba) to the fully open side, and
the base lower limit value (4b) is corrected to increase (4ca) to the fully open side with an increase correction value (4c) on the basis of a detected atmospheric pressure in an engine middle-high temperature range where the engine temperature exceeds a predetermined value, and in the increase correction (4ca), the increase correction value (4c) is increased (4cb) to the fully open side as the detected atmospheric pressure becomes lower, and
an increase correction (4ca) is prohibited (4cc) in an engine low temperature range where the engine temperature is equal to or lower than the predetermined value.
The present invention has the following effects.
<<Effect 1>> Adjustments can be made to avoid excessive engine rotation.
In the engine low temperature range where the base lower limit value (4b) is relatively large, the increase correction (4ca) of the base lower limit value (4b) is prohibited (4cc), and adjustment for avoiding excessive engine rotation can be performed. Therefore, engine noise and gear noise at the time of gear shift can be prevented.
The reason why the base lower limit value (4b) is increased in the engine low temperature range is to avoid an engine stall due to insufficient output because the internal load of the engine is increased by increasing the viscosity of the engine oil.
<<Effect 2>> An engine stall during high altitude driving is avoided.
In the engine middle-high temperature range where the base lower limit value (4b) is relatively small, the base lower limit value (4b) is corrected to increase (4ca) on the basis of the atmospheric pressure during the high altitude operation to compensate for the decrease in the intake-air density, and the engine stall due to the incomplete combustion is avoided.
The reason why the base lower limit value (4b) can be reduced in the engine middle-high temperature range is that the internal load of the engine is small, and an engine stall due to insufficient output hardly occurs.
As shown in
A cylinder is housed in an upper portion of the cylinder block (11), and a crankshaft (16) is housed in a lower crankcase (11a). As shown in
As shown in
The engine includes an air-intake device, a fuel supply device, an ignition device, an exhaust device, a starting device, and an engine coolant device.
The air-intake device is a device that supplies intake-air to a cylinder, and includes an air cleaner (not illustrated), an intake-air duct (not illustrated), a throttle body (18) illustrated in
The air-intake manifold (19) is assembled to the cylinder head (12) and also serves as a surge tank.
As illustrated in
The throttle body (18) includes a main intake-air passage (1), a throttle valve (2) of the main intake-air passage (1), a bypass intake-air passage (3) bypassing the throttle valve (2), and an ISC valve (4) of the bypass intake-air passage (3).
The ISC valve is an abbreviation of an idling speed control valve, and hereinafter, an abbreviation of an ISC valve is used in the same manner.
In this engine, the opening degree of the ISC valve (4) is adjusted by the control of the electronic control device (5) illustrated in
The throttle valve (2) is interlocked with an accelerator pedal (21) via a mechanical governor (20).
The electronic control device (5) electronically controls each component of the engine, and uses an engine ECU. The ECU is an abbreviation of an electronic control unit.
As shown in
A fuel supply device is a device that injects fuel into intake-air to form an air-fuel mixture, and includes an injector (22) as illustrated in
The fuel injection timing and the fuel injection amount are determined by calculation of the electronic control device (5) on the basis of the fuel injection map from the engine speed, the engine temperature, the atmospheric pressure, the intake-air pressure, and the intake-air temperature, and an air-fuel mixture having an appropriate air-fuel ratio is formed.
The fuel injection map is stored in a storage unit of the electronic control device (5).
The opening/closing timing of the electromagnetic valve of the injector (22) is specified by a crank angle.
The injector (22) shown in
The crank angle is detected by a crank position sensor (23) illustrated in
The engine speed is calculated by the electronic control device (5) on the basis of a change rate of a crank angle detected by the crank position sensor (23).
An engine temperature is detected by an engine temperature sensor (6) illustrated in
Although the engine coolant temperature sensor (6a) is used as the engine temperature sensor (6) that detects the engine temperature, an engine oil temperature sensor or a cylinder wall temperature sensor may be used instead of the engine coolant temperature sensor (6a).
Although the atmospheric pressure sensor (8a) disposed outside the intake-air path is used in the atmospheric pressure detector (8), an intake-air pressure sensor (24) disposed in the intake-air path may be used instead. That is, if the intake-air pressure in the intake-air path is detected by the intake-air pressure sensor (24) when a key switch (29) illustrated in
This engine is a 4-cycle engine. An air-intake stroke and an expansion stroke of each cylinder cannot be identified, and a compression stroke and an exhaust stroke cannot be identified only by detecting a crank angle. Therefore, a cam angle of a valve cam is detected by a cam position sensor (31) illustrated in
As shown in
The ignition device is a device that ignites an air-fuel mixture, and as shown in
The ignition timing is determined by calculation of the electronic control device (5) on the basis of the ignition timing map from the engine speed, the engine coolant temperature, the atmospheric pressure, the intake-air pressure, and the intake-air temperature.
The ignition plug (27) is attached to a cylinder head in a cylinder head cover and is fitted to a plug cap (not shown), and the ignition coil (26) shown in
Since this engine is a two-cylinder engine, two ignition plugs (27) are disposed, and two ignition coils (26) are also disposed as illustrated in
The exhaust device is a device that discharges exhaust of a cylinder, and includes an exhaust port in the cylinder head (12), an exhaust manifold, an exhaust pipe, a three-way catalyst, and an exhaust muffler from an exhaust upstream. These components are not shown in the drawings.
The engine coolant device is a device that cools an engine with engine coolant, and is configured such that engine coolant in the cylinder jacket in the cylinder block (11) circulates back to the cylinder jacket via the head jacket in the cylinder head (12), a radiator (not shown), and a water pump (28) in order.
As shown in
The starting device is a device for starting an engine, and includes the key switch (29) and a starter (30) as illustrated in
When the key switch (29) is turned on from the OFF position (29a) to the start position (29c), the starter (30) is energized from a battery (not illustrated), and the crankshaft (16) is driven by cranking. When the engine speed reaches a predetermined cranking end determination value, the pinion gear (not shown) of the starter (30) is disengaged from the ring gear (shown) of the crankshaft (16), the energization from the battery to the starter (30) is also released, and the cranking ends. The cranking end determination value is set to a complete explosion rotation speed (about 1300 rotations per minute).
As shown in
Therefore, the intake-air negative pressure promotes fuel vaporization and enables fuel and air mixing to be favorable, and improved combustion results in better engine startability.
In the engine starting test of the embodiment of the present invention shown in
On the other hand, as shown in
Thereafter, in the restart processing similarly performed, since the stable idling operation was maintained for a long period (10 seconds or more) after cranking for a short period (about 2 seconds), it was determined that restart was successful. It is considered that the restart was successful because the engine temperature was increased in the first engine start processing.
As described above, in the comparative example, the initial engine start has failed, whereas in the embodiment, there is no failure even in the initial engine start, and it can be seen that the startability of the engine of the embodiment is favorable.
As shown in
Therefore, as the engine temperature becomes lower, the intake-air negative pressure becomes larger, and the cold startability of the engine becomes more favorable.
As shown in
Therefore, as the intake-air temperature becomes lower, the intake-air negative pressure becomes larger, and the cold startability of the engine becomes more favorable.
The cranking opening degree is determined by calculation of the electronic control device (5) on the basis of the cranking opening degree map from the engine coolant temperature and the intake-air temperature.
The cranking opening degree map is stored in the storage unit of the electronic control device (5).
The engine is configured such that the intake-air amount at the time of cranking is 30% to 70% of the intake-air amount when the ISC valve (4) is fully opened by setting the cranking opening degree of the ISC valve (4).
When the intake-air amount at the time of cranking is less than 30% of the amount of intake-air when the ISC valve (4) is fully open, intake-air is insufficient. When the amount of intake-air exceeds 70%, the intake-air negative pressure is insufficient, and failure of engine start easily occurs in any case. However, failure is less likely to occur within the above range.
As shown in
Therefore, the intake-air amount increases in the idling operation immediately after the cranking ends, and the idling operation is stabilized.
As shown in
As illustrated in
As shown in
As illustrated in
As shown in
The reason why the base lower limit value (4b) is increased in the engine low temperature range is to avoid an engine stall due to insufficient output because the internal load of the engine is increased by increasing the viscosity of the engine oil.
As shown in
The reason why the base lower limit value (4b) can be reduced in the engine middle-high temperature range is that the internal load of the engine is small, and an engine stall due to insufficient output hardly occurs.
As illustrated in
Therefore, as illustrated in
As shown in
As illustrated in
Therefore, in the intake-air middle-high temperature range where the intake-air density is relatively low, the base lower limit value (4b) increases (4bb), a decrease in the intake-air density is compensated for, and an engine stall due to incomplete combustion is avoided.
As shown in
In the sudden acceleration processing, the advance angle of the ignition timing is set to be larger than that in the normal driving processing, and as illustrated in
For this reason, when the processing shifts from the sudden acceleration processing at the large advance angle with favorable acceleration responsiveness to the normal driving processing at the small advance angle with favorable knocking prevention, a rapid decrease in the output due to a rapid decrease in the advance angle is avoided, and the torque shock is reduced.
The advance angle, the duration time, the retarded angular velocity, and the angle to retard the ignition timing in the sudden acceleration processing are determined by calculation of the electronic control device (5) on the basis of a sudden acceleration ignition timing map.
The sudden acceleration ignition timing map is stored in the storage unit of the electronic control device (5).
A throttle position sensor is used as the sudden acceleration operation detection sensor (10) illustrated in
A flow of control by the electronic control device (5) will be described.
As shown in
As shown in
When the determination in step (S9) is negative, it is determined in step (S11) whether the determination time of the start failure has elapsed. When the determination is affirmative, cranking is ended in step (S12), and the processing returns to step (S1) which is a start step of the start preparation processing for restart. When the determination in step (S11) is negative, the processing returns to step (S7).
As shown in
As shown in
In the fully closed operation processing, the engine speed feedback control for bringing the engine speed close to the idling target speed is performed under the control of the electronic control device (5).
As shown in
As shown in
As shown in
In a case where the determination in step (S26) is negative, that is, in a case where the ignition is the second or subsequent ignition in the sudden acceleration processing, it is determined in step (S29) whether or not a predetermined retard standby time has elapsed from the immediately preceding ignition, and if affirmative, the immediately preceding ignition timing stored in step (S30) is read and the angle to be retarded from the immediately preceding ignition timing is read, and the ignition timing is determined and the ignition timing is stored in step (S31). The advance angle of the ignition timing to be determined is a value obtained by subtracting the angle to be retarded from the advance angle of the immediately preceding ignition timing, and approaches the advance angle of the ignition timing of the normal driving processing to be shifted. A limit is imposed on the determination in step (S31), and retarding the ignition timing to an advance angle smaller than the ignition timing of the normal driving processing to be shifted is prohibited. Following step (S31), fuel is injected and the air-fuel mixture is ignited in step (S32). In step (S33), it is determined whether the required duration time of the sudden acceleration processing has elapsed. If negative, the processing returns to step (S23).
When the determination in step (S29) is negative, that is, when the retard waiting time has not elapsed from the immediately preceding ignition, the processing proceeds to step (S27), and the ignition timing to be determined is the same advance angle as the immediately preceding ignition timing.
When the determination in step (S33) is affirmative, the measurement of the duration time of the sudden acceleration processing is ended in step (S34), the measurement value is reset, and the processing returns to step (S20) which is the start step of the normal driving processing.
Number | Date | Country | Kind |
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2021-210224 | Dec 2021 | JP | national |