Information
-
Patent Grant
-
6216650
-
Patent Number
6,216,650
-
Date Filed
Wednesday, April 14, 199925 years ago
-
Date Issued
Tuesday, April 17, 200123 years ago
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Inventors
-
Original Assignees
-
Examiners
- Wolfe; Willis R.
- Huynh; Hai
Agents
-
CPC
-
US Classifications
Field of Search
US
- 123 65 R
- 123 73 A
- 123 73 C
- 123 73 PP
-
International Classifications
-
Abstract
The present invention relates to a stratified scavenging two-cycle engine, in which control of an air flow rate provides favorable acceleration performance and can prevent deterioration of exhaust gas. The stratified scavenging two-cycle engine includes a scavenging flow passage (3) for connection between a cylinder chamber (4a) and a crank chamber (1a), an air flow passage (2) connected to the scavenging flow passage (3), an air flow rate control means (12) for controlling a flow rate of air fed to the scavenging flow passage (3) from the air flow passage (2), and a fuel mixture flow rate controller (11) for controlling a flow rate of a fuel mixture drawn into the crank chamber (1a) from a fuel mixture flow passage (10). The air flow rate controller (12) throttles an air flow rate at the time of acceleration. Alternatively, the air flow rate controller (12) is opened later than the mixture flow rate controller (11) at the time of acceleration.
Description
TECHNICAL FIELD
The present invention relates to a stratified scavenging two-cycle engine, and more particularly to a stratified scavenging two-cycle engine, in which control of an air flow rate provides favorable acceleration performance and can prevent deterioration of exhaust gas.
BACKGROUND ART
As a conventional stratified scavenging two-cycle engine of this kind, a stratified scavenging two-cycle engine that includes a scavenging flow passage for connection between a cylinder chamber and a crank chamber and an air flow passage connected to the scavenging flow passage and that is structured in such a manner that pressure reduction in the crank chamber, with upward movement of a piston, permits a fuel mixture to be drawn into the crank chamber and permits air to be drawn into the crank chamber, through the scavenging flow passage from the air flow passage, is known. In the stratified scavenging two-cycle engine structured as described above, there is an advantage that combustion gas can be pushed out by air from the scavenging flow passage, thus making exhaust gas cleaner by greatly reducing an introduction of a fuel mixture during combustion gas expulsion.
In the aforesaid stratified scavenging two-cycle engine, however, there is a disadvantage that the fuel mixture is rarefied by air, whereby an air-fuel ratio (weight of air/weight of fuel) having a substantial ratio of air to fuel becomes thinner (increases), thus deteriorating acceleration performance. As a measure to improve acceleration performance, it is required that the air-fuel ratio is thickened (decreases) by increasing the supply amount of fuel also at a time of stationary engine speed in accordance with acceleration performance to draw an enriched fuel mixture into the crank chamber. In that case, however, an exhaust gas quality at the time of a stationary engine speed (i.e., other than a time of acceleration) deteriorates.
SUMMARY OF THE INVENTION
In view of the aforesaid disadvantages, an object of the present invention is to provide a stratified scavenging two-cycle engine, in which a fuel mixture and air are separately drawn and that controls a supplied flow rate of air to improve acceleration performance and to prevent deterioration of exhaust gas at a time of stationary engine speed and a time of acceleration.
To attain the aforesaid object, a stratified scavenging two-cycle engine according to the present invention is characterized by including a scavenging flow passage for connection between a cylinder chamber and a crank chamber, an air flow passage connected to the scavenging flow passage, an air flow rate controller for controlling a flow rate of air fed to the scavenging flow passage from the air flow passage, and a fuel mixture flow rate controller for controlling a flow rate of a fuel mixture drawn into the crank chamber from a fuel mixture flow passage, the aforesaid air flow rate controller throttling an air flow rate at the time of acceleration.
According to the aforesaid configuration, when a piston ascends, pressure in the crank chamber lowers so that a fuel mixture flows into the crank chamber, and air flows into the crank chamber through the scavenging flow passage from the air flow passage. Namely, the scavenging flow passage is filled with air, and inside the crank chamber, the fuel mixture is rarefied by air from the scavenging flow passage. Therefore, in the stratified scavenging two-cycle engine, an air-fuel ratio of a fuel mixture drawn from the fuel mixture flow passage is set in a higher range so as to make the air-fuel ratio optimum in combustion after the fuel mixture is rarefied by air.
Subsequently, when pressure in the cylinder chamber sharply rises by ignition of the fuel mixture in the cylinder chamber and the piston descends, pressure in the crank chamber rises. When the piston descends to a predetermined position, an exhaust port opens, for example, and combustion gas flows out of the exhaust port so that pressure in the cylinder chamber sharply drops, and a scavenging port which is an end portion on the side of the cylinder chamber of the scavenging flow passage opens. Then, air in the scavenging flow passage flows into the cylinder chamber, and subsequently the fuel mixture in the crank chamber flows into the cylinder chamber through the scavenging flow passage.
Specifically, combustion gas can be pushed out of the exhaust port by only air at a point in time when scavenge starts, thus preventing deterioration of exhaust gas due to an introduction of a fuel mixture. Moreover, a proper air-fuel ratio mixture fills the cylinder chamber, thereby also preventing deterioration of exhaust gas. Accordingly, exhaust gas can be cleaned at the time of stationary engine speeds.
Meanwhile, when the flow rate of a fuel mixture fed to the crank chamber is increased by the fuel mixture flow rate controller, engine speed increases. At the time of such engine acceleration, an air flow rate is throttled by the air flow rate controller. Hence, the flow rate of air flowing into the crank chamber is relatively lower than the flow rate of a fuel mixture flowing into the same crank chamber, as compared with stationary engine speeds.
Namely, a thicker air-fuel ratio fuel mixture fills the cylinder chamber, thus improving acceleration performance of the engine. At this time, since the supply amount of fuel is not increased at the time of acceleration as in the prior art, the supply amount of fuel is small even at the time of acceleration, thus preventing deterioration of exhaust gas more than in the prior art. In addition, in the stratified two-cycle engine of the present invention, the supply amount of fuel is not increased at the time of acceleration, whereby deterioration of exhaust gas can be prevented more than in the prior art even at the time of a stationary engine speed.
A stratified scavenging two-cycle engine according to the present invention is characterized by including a scavenging flow passage for connection between a cylinder chamber and a crank chamber, an air flow passage connected to the scavenging flow passage, an air flow rate controller for controlling a flow rate of air fed to the scavenging flow passage from the air flow passage, and a mixture flow rate controller for controlling a flow rate of a fuel mixture drawn into the crank chamber from a fuel mixture flow passage, the aforesaid air flow rate controller being opened later than the mixture flow rate controller at the time of acceleration.
According to the aforesaid configuration, the same effect as that of the aforesaid embodiment can be obtained. In this embodiment, the same effect that is described above is obtained at the time of acceleration, and moreover an air-fuel ratio becomes the same as that at stationary engine speed by eliminating delay when predetermined acceleration is obtained, whereby accelerating performance can be improved and exhaust gas after acceleration can be made cleaner than in the prior art.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1
is a sectional view of a stratified scavenging two-cycle engine according to one embodiment of the present invention, the engine being shown in a state of acceleration;
FIG. 2
is a sectional view of the stratified scavenging two-cycle engine of the one embodiment of the present invention, the engine being shown in a state of a stationary engine speed;
FIG. 3
is a schematic view of a first embodiment of an air supply delay device for the one embodiment of the present invention;
FIG. 4
is a diagram for explaining the relationship between points in time and valve openings in the first embodiment of the air supply delay device;
FIG. 5
is a block diagram of a second embodiment of the air supply delay device for the one embodiment of the present invention;
FIG. 6
is a flowchart of the second embodiment of the air supply delay device for the one embodiment of the present invention;
FIG. 7
is a diagram for explaining the relationship between points in time and valve openings in the second embodiment of the air supply delay device;
FIG. 8
is a block diagram of a third embodiment of the air supply delay device for the one embodiment of the present invention;
FIG. 9
is a flowchart of the third embodiment of the air supply delay device according to the present invention; and
FIG. 10
is a diagram for explaining the relationship between points in time and valve openings in the third embodiment of the air supply delay device.
BEST MODE FOR CARRYING OUT THE INVENTION
One embodiment of the present invention will be described below concerning the case of a crankcase reed valve-type engine with reference to FIG.
1
and FIG.
2
. Incidentally, the same effect as the above can be obtained in the case of a piston valve-type engine. In a stratified scavenging two-cycle engine shown in this embodiment, as shown in
FIGS. 1 and 2
, a fuel mixture flow passage
10
that provides a fuel mixture is connected to a crank chamber
1
a
, and an air flow passage
2
that provides air is connected to a scavenging flow passage
3
. A check valve
20
is provided at the outlet of the air flow passage
2
. The check valve
20
, which is formed by a reed valve, allows a flow from the air flow passage
2
toward the scavenging flow passage
3
, and impedes a flow from the scavenging flow passage
3
toward the air flow passage
2
. A check valve
100
is provided in the fuel mixture flow passage
10
. The check valve
100
is also formed by a reed valve, allowing a flow from the fuel mixture flow passage
10
toward the crank chamber
1
a
, and impeding flow from the crank chamber
1
a
toward the fuel mixture flow passage
10
.
Meanwhile, the scavenging flow passage
3
is provided in a crankcase
1
and a cylinder block
4
in order to lead from the crank chamber
1
a
into a cylinder chamber
4
a
. In a cylinder inner face
4
b
, scavenging ports
3
a
leading to the scavenging flow passage
3
are opened, and an exhaust port
4
c
for exhausting combustion gas is also opened.
A crankshaft
5
is provided in the crankcase
1
, and a piston
7
is coupled to the crankshaft
5
via a connecting rod
6
. The piston
7
is put into the cylinder chamber
4
a
and movable along the axial direction of the cylinder chamber
4
a
. In addition, a cylinder head
8
is provided on the cylinder block
4
, and an ignition plug
9
is provided on the cylinder head
8
.
A fuel mixture flow rate controller
11
for controlling a flow rate of a fuel mixture drawn into the crank chamber
1
a
is provided upstream of the fuel mixture flow passage
10
. Moreover, an air flow rate control means
12
for controlling a flow rate of air drawn into the scavenging flow passage
3
from the air flow passage
2
is provided upstream of the air flow passage
2
.
The fuel mixture flow rate controller
11
controls the flow rate of a fuel mixture with a throttle valve
11
a
. Specifically, by opening the throttle valve
11
a
, the flow rate of a fuel mixture drawn into the crank chamber
1
a
increases, whereby engine speed increases. In addition, in the fuel mixture flow rate controller
11
, a carburetor
11
b
is integrally provided upstream of the throttle valve
11
a.
The air flow rate controller
12
controls the flow rate of air with an on-off valve
12
a
. The on-off valve
12
a
throttles an opening when the flow rate of a fuel mixture fed to the crank chamber
1
a
is increased by the throttle valve
11
a
and engine speed is increased, that is, at the time of engine acceleration. Specifically, the on-off valve
12
a
detects that the throttle valve
11
a
is changing in an opening direction and throttles an air flow rate.
In the stratified two-cycle engine structured as described above, as shown in
FIG. 2
, when the piston
7
ascends, pressure in the crank chamber
1
a
lowers so that a fuel mixture flows into the crank chamber
1
a
from the mixture flow passage
10
, and air flows into the crank chamber
1
a
through the scavenging flow passage
3
from the air flow passage
2
. Namely, the scavenging flow passage
3
is filled with air, and inside the crank chamber
1
a
, the supplied mixture is rarefied by air. Therefore, an air-fuel ratio of a fuel mixture drawn from the fuel mixture flow passage
10
is set in a lower range so as to make the air-fuel ratio optimum in combustion after the fuel mixture is rarefied by air.
Subsequently, when pressure in the cylinder chamber
4
a
sharply rises by ignition of a fuel mixture in the cylinder chamber
4
a
, the piston
7
descends, and pressure in the crank chamber
1
a
rises. When the piston
7
descends to a predetermined position, the exhaust port
4
c
opens, and combustion gas flows out of the exhaust port
4
c
so that pressure in the cylinder chamber
4
a
sharply drops and the scavenging ports
3
a
open. Then, air in the scavenging flow passage
3
flows into the cylinder chamber
4
a
, and subsequently the fuel mixture in the crank chamber
1
a
flows into the cylinder chamber
4
a
through the scavenging flow passage
3
.
Specifically, combustion gas can be pushed out of the exhaust port
4
c
by only air at a point in time when scavenge starts, thus preventing deterioration of exhaust gas due to an introduction of uncombusted fuel mixture. Moreover, a proper air-fuel ratio mixture can fill the cylinder chamber
4
a
, thereby also preventing deterioration of exhaust gas. Accordingly, exhaust gas can be cleaned at the time of stationary travel shown in FIG.
2
.
Meanwhile, when the flow rate of a fuel mixture fed to the crank chamber
1
a
increases by the mixture flow rate controller
11
, engine speed increases. At the time of such acceleration, an air flow rate is throttled by the air flow rate controller
12
, as shown in FIG.
1
. Hence, the flow rate of air flowing into the crank chamber
1
a
is relatively lower than the flow rate of a fuel mixture flowing into the same crank chamber
1
a
at stationary engine speeds, e.g., idle. Namely, a lower air-fuel ratio fuel mixture fills the cylinder chamber
4
a
, thus improving acceleration performance of the engine. Since the total amount of fed fuel is smaller than in the prior art, with delay of a supplied quantity, exhaust gas at the time of acceleration can be made cleaner than in the prior art. Moreover, since the supply amount of fuel no longer needs to be determined in view of an air-fuel ratio at the time of acceleration, the supply amount of fuel can be set in a lower range at a stationary engine speed, and exhaust gas can be made cleaner than in the prior art.
Next, a case will be explained where an air flow rate is throttled by the aforesaid air flow rate controller
12
and the air flow rate flows into the crank chamber
1
a
later than a fuel mixture flow rate.
FIG. 3
shows a schematic view of a first embodiment of an air supply delay device
20
, which is controlled by a mechanism, to supply a later air flow rate. A fuel mixture link
21
is linked to the throttle valve
11
a
of the fuel mixture flow rate controller
11
(shown in
FIG. 1
) via a fuel mixture spring
22
and linked to a throttle lever
23
for accelerating or decelerating engine speed. A first air link
24
is linked to the on-off valve
12
a
of the air flow rate controller
12
(shown in
FIG. 1
) via a first air spring
25
and linked to the throttle lever
23
for accelerating or decelerating engine speed by a second air link
26
via a shock absorber
30
, together with the fuel mixture link
21
. In the shock absorber
30
, in an example shown, a second air spring
27
is inserted between the first air link
24
and the second air link
26
, and a spring constant Ka of the second air spring
27
is set in a lower range than a spring constant Kb of the first air spring
25
. Although a spring is used for the shock absorber
30
in the aforesaid embodiment, an assistant cylinder, an accumulator, or the like can be also used.
Next, operation will be described with reference to FIG.
3
and FIG.
4
. When an operator wants to accelerate the engine, the throttle lever
23
is manipulated in an accelerating direction. A movement of the throttle lever
23
in the accelerating direction is transmitted to the throttle valve
11
a
via the fuel mixture link
21
and the fuel mixture spring
22
, whereby the throttle valve
11
a
of the fuel mixture flow rate controller
11
is rotated to be opened further. Thus, the flow rate of a fuel mixture drawn into the crank chamber
1
a
is further increased and drawn in accordance with the amount of throttle lever
23
manipulation, as shown in a full line Zb in FIG.
4
. At the same time, the movement of the throttle lever
23
in the accelerating direction rotates the on-off valve
12
a
of the air flow rate controller
12
to be opened via the second air link
26
, the shock absorber
30
, and the first air link
24
, in sequence. At this time, in the shock absorber
30
, the second air spring
27
having the lower spring constant Ka is bent responsive to a movement of the second air link
26
, and the air first link
24
is moved after the second air spring
27
is bent by a predetermined amount. Accordingly, after receiving movement of the second air link
26
, the shock absorber
50
moves the first air link
24
with delay. Thus, in the opening amount of the on-off valve
12
a
of the air flow rate controller
12
, delay is brought about by the shock absorber
30
as shown in a dotted line Za in
FIG. 4
, and the on-off valve
12
a
is opened to a predetermined position which is set by the throttle lever
23
later than the throttle valve
11
a
at all times. By delay of the air quantity to be supplied, a lower air-fuel ratio fuel mixture fills the cylinder chamber
4
a
, thus improving acceleration performance of the engine. At this time, with the delay of the air to be supplied, the total amount of fuel fed to the fuel mixture is smaller than in the prior art, whereby exhaust gas at the time of acceleration can be made cleaner than in the prior art. Moreover, since the supply amount of fuel no longer needs to be determined in view of an air-fuel ratio at the time of acceleration, the supply amount of fuel can be set in a lower range at a stationary engine speed, and exhaust gas can be made cleaner than in the prior art.
Referring now to FIG.
1
and
FIG. 5
, which show a schematic diagram of a second embodiment of an air supply delay device
20
A which supplies a later air flow rate. Incidentally, the second embodiment is electronically controlled, which shows an example in which the opening amount of the on-off valve
12
a
of the air flow rate controller
12
is throttled more than that of the throttle valve
11
a
of the mixture flow rate controller
11
. A fuel mixture servo-motor
31
is attached to the throttle valve
11
a
of the fuel mixture flow rate controller
11
. The fuel mixture servo-motor
31
is connected to a control element
34
, such as a digit controller, via a fuel mixture position control servo amplifier
32
and a fuel mixture D/A converter
33
and operates in accordance with commands from the control element
34
. An air servo-motor
35
is attached to the on-off valve
12
a
of the air flow rate controller
12
, the air servo-motor
35
being connected to the control element
34
, such as a digital controller, via an air position control servo amplifier
36
and an air D/A converter
37
and operates in accordance with commands from the control element
34
. Provided in the throttle lever
23
is a movement sensor
38
for detecting the amount of movement (or the amount of rotation) of the throttle lever
23
. A signal from the movement sensor
38
is inputted to the control element
34
via an A/D converter
39
. A CPU
43
a
, a ROM
43
b
, a RAM
43
c
, and a timer
43
d
are provided in the control element
34
. Although an example in which the servo-motors
31
,
35
are used for opening and closing the throttle valve
11
a
and the on-off valve
12
a
is shown above, an electromagnetic proportional control valve which controls a flow rate with a solenoid, a step motor, or the like may be used.
Next, operation will be described, based on a flowchart shown in
FIG. 6
with reference to
FIGS. 1 and 5
.
At START in step
1
, when the engine starts, the control element
34
executes control operations at regular intervals, for example, at 10 msec intervals by interrupt of a timer
43
d.
In step
2
, input processing of throttle openings is executed. A voltage value according to the amount of movement from the movement sensor
38
is converted to a digital value through the A/D converter
39
to be inputted to the CPU
43
a
. In the control element
34
, address data corresponding to a throttle opening, which is already stored in the RAM
43
c
, are moved to data stored in an address corresponding to the preceding throttle opening, and data corresponding to a throttle opening which is inputted to the CPU
43
a
from the A/D converter
39
this time is stored in an address corresponding to a throttle opening which is already stored. In addition, the control element
34
converts a voltage value according to the amount of movement from the movement sensor
38
to a digital value through the A/D converter
39
and receives it in the CPU
43
a
, and subsequently outputs an opening command to the mixture servo-motor
31
so that the flow rate of a fuel mixture is in accord with the amount of movement stored in the ROM
43
b
flows.
In step
3
, data of an address corresponding to an air flow rate map stored in the ROM
43
c
are read out from the present throttle opening, which is obtained in step
2
.
In step
4
, data of a throttle opening obtained last time and data of a throttle opening obtained this time are compared, and whether the engine is in acceleration or not is determined from whether the throttle opening obtained this time is increased more than the throttle opening obtained last time or not.
When the throttle opening obtained this time is the same as or is smaller than the throttle opening obtained last time in step
4
, the procedure advances to step
5
.
In step
5
, when the throttle opening obtained this time is the same as the throttle opening obtained last time, the same command value as that of the throttle opening obtained last time is outputted to the on-off valve
12
a
of the air flow rate controller
12
as an opening command, and when the throttle opening obtained this time is smaller than the throttle opening obtained last time, a command value for letting the flow rate of air according to the amount of movement of the throttle lever
23
, which is stored in the ROM
43
c
flow, is outputted to the on-off valve
12
a
of the air flow rate controller
12
as an opening command, respectively. The control element
34
outputs an opening command to the fuel mixture servo-motor
31
so that a flow rate of a fuel mixture is in accord with an amount of movement of the throttle lever
23
stored in the ROM
43
c
. Further in the above, the mixture flow rate controller
11
may be a mechanical control means, which uses the mixture link
21
shown in
FIG. 3
, without being electronically controlled.
When the throttle opening obtained this time is larger than the throttle opening obtained last time in step
4
, the procedure advances to step
6
after the amount of acceleration is obtained.
In step
6
, predetermined throttle amount data X, according to the amount of acceleration stored in the ROM
43
c
are subtracted from air quantity data D, found from the air flow rate map obtained in step
3
, to find throttle air flow rate data Dx.
In step
7
, whether the throttle air flow rate data Dx obtained in step
6
are larger than minimum air flow rate data Do of the engine or not is determined.
When the throttle air flow rate data Dx are smaller than the minimum air flow rata data Do, the procedure advances to step
8
.
In step
8
, the CPU
43
a
outputs the minimum air flow rate data Do to the air D/A converter
37
, and the air D/A converter
37
converts the data to a predetermined voltage value to be outputted to the air position control servo amplifier
36
. The air position control servo amplifier
36
rotates the air servo-motor
35
to a position proportional to the voltage value. The control element
34
outputs an opening command to the mixture servo-motor
31
so that the flow rate of a fuel mixture is in accord with the amount of movement of the throttle lever
23
stored in the ROM
43
c
. Further in the above, the fuel mixture flow rate controller
11
may be a mechanical control means which uses the mixture link
21
shown in
FIG. 3
without being electronically controlled.
When the throttle air flow rate data Dx is larger than the minimum air flow rate data Do in step
7
, the procedure advances to step
9
.
In step
9
, the CPU
43
a
outputs the throttle air flow rate data Dx to the air D/A converter
37
, and the air D/A converter
37
converts the data to a predetermined voltage value to be outputted to the air position control servo amplifier
36
. The air position control servo amplifier
36
rotates the air servo-motor
35
to a position proportional to the voltage value so that the on-off valve
12
a
of the air flow rate controller
12
is throttled. The control element
34
outputs an opening command to the fuel mixture servo-motor
31
so that the flow rate of a fuel mixture is in accord with the amount of movement of the throttle lever
23
stored in the ROM
43
c
. Further in the above, the mixture flow rate controller
11
may be a mechanical control means which uses the fuel mixture link
21
shown in
FIG. 3
without being electronically controlled.
As shown with a dotted line Va in
FIG. 7
with reference to
FIGS. 1 and 5
, the on-off valve
12
a
of the air flow rate controller
12
is throttled more than the throttle valve
11
a
of the fuel mixture flow rate controller
11
by the throttle amount data X, and the air servo-motor
35
operates while being throttled more than the fuel mixture servo-motor
31
. Therefore, a supplied air quantity is decreased, and a fuel mixture having a lower air-fuel ratio fills the cylinder chamber
4
a
, thus improving acceleration performance of the engine. In
FIG. 7
, the horizontal axis represents time, the vertical axis represents the opening amount of a valve, the dotted line Va shows the case of the on-off valve
12
a
of the air flow rate controller
12
, and a full line Vb shows the case of the throttle valve
11
a
of the mixture flow rate controller
11
. When a valve opening amount Qa is changed to an acceleration valve opening amount Qb in the drawing, the opening amount of the throttle valve
11
a
of the fuel mixture flow rate controller
11
increases as shown with the full line Vb, and the opening amount of the on-off valve
12
a
of the air flow rate controller
12
remains in a position where it is for a predetermined period of time as shown with a dotted line Va. As a result, the opening amount of the on-off valve
12
a
of the air flow rate controller
12
increases later than the opening amount of the throttle valve
11
a
of the fuel mixture flow rate controller
11
while being throttled more than the opening amount of the throttle valve
11
a
of the fuel mixture flow rate controller
11
. Thus, similar to the above, with delay in an air quantity to be supplied, the total amount of fuel fed to the fuel mixture is smaller than in the prior art, whereby exhaust gas at the time of acceleration can be made cleaner than in the prior art. Moreover, since the supply amount of fuel no longer needs to be determined in view of an air-fuel ratio at the time of acceleration, the supply amount of fuel can be set in a lower range at a stationary engine speed, and exhaust gas can be made cleaner than in the prior art.
Referring now to
FIG. 8
, a third embodiment of an air supply delay device
20
B is described, with reference also to
FIGS. 3 and 5
. The configuration of parts of the third embodiment is different from that of the second embodiment shown in
FIG. 5
in that: two timers
41
and
42
are provided in a control element
34
A; the mixture D/A converter
33
, the mixture position control servo amplifier
32
, and the mixture servo-motor
31
are omitted; and the throttle valve
11
a
in the fuel mixture flow rate controller
11
is connected to the throttle lever
23
via the fuel mixture link
21
. A controlling method of the third embodiment is an example in which the opening of the on-off valve
12
a
of the air flow rate controller
12
is made later than the throttle valve
11
a
of the fuel mixture flow rate controller
11
. Incidentally, the same parts as those in
FIG. 5
are denoted by the same numerals and symbols and the explanation thereof is omitted.
The controlling method by the control element
34
A will be described, based on a flowchart shown in
FIG. 9
with reference to
FIGS. 1 and 8
.
At START in step
21
, when the engine starts, the control element
34
A executes control operations at regular intervals, for example, at 10 msec intervals by interrupt of a timer
41
.
In step
22
, input processing of throttle openings is executed. A voltage value according to the amount of movement from the movement sensor
38
is converted to a digital value through the A/D converter
39
to be inputted to the CPU. In the control element
34
A, data of an address corresponding to a throttle opening, which is already stored in the RAM
43
c
, are moved to data stored in an address corresponding to the preceding throttle opening, and data corresponding to a throttle opening, which is inputted to the CPU
43
a
from the A/D converter
39
at this time, are stored in an address corresponding to a throttle opening which is already stored.
In step
23
, data of an address corresponding to an air flow rate map stored in the ROM
43
c
are read out from the present throttle opening, which is obtained in step
22
.
In step
24
, data of an address corresponding to the air flow rate map stored in the ROM
43
b
from the present throttle opening which is obtained in step
23
is outputted to the air D/A converter
37
, and the air D/A converter
37
converts the data to a predetermined voltage value to be outputted to the air position control servo amplifier
36
. The air position control servo amplifier
36
rotates the air servo-motor
35
to a position proportional to the voltage value.
In step
25
, data of the throttle opening obtained last time and data of a throttle opening obtained this time are compared, and whether the engine is in acceleration or not is determined from whether the throttle opening obtained this time is increased more than the throttle opening obtained last time or not.
When the throttle opening obtained this time is the same as or is smaller than the throttle opening obtained last time in step
25
, the air servo-motor
35
is rotated to a position at which output is conducted to the air D/A converter
37
in step
24
.
When the throttle opening obtained this time is larger than the throttle opening obtained last time in step
25
, the procedure advances to step
26
.
In step
26
, a delay time t
o
is counted by a timer
42
, during which interrupt for executing control operations by the timer
41
is prevented. After the delay time t
o
is counted by the timer
42
interrupt is resumed. Thus, the air servo-motor
35
starts to operate later than the throttle valve
11
a
in the fuel mixture flow rate controller
11
. Consequently, as shown with a dotted line Ya in
FIG. 10
, the on-off valve
12
a
of the air flow rate controller
12
starts to operate later than the throttle valve
11
a
of the fuel mixture flow rate controller
11
by the delay time t
o
, whereby delay in an air quantity to be supplied occurs and a thicker air-fuel ratio fuel mixture fills the cylinder chamber
4
a
, thus improving acceleration performance of the engine. In
FIG. 10
, the horizontal axis represents time, the vertical axis represents the opening amount of a valve, a dotted line Ya shows the case of the on-off valve
12
a
of the air flow rate controller
12
, and a full line Yb shows the case of the throttle valve
11
a
of the fuel mixture flow rate controller
11
. When a valve opening amount Qa is changed to an acceleration valve opening amount Qb (in the drawing), the opening amount of the throttle valve
11
a
of the fuel mixture flow rate controller
11
increases, as shown with the full line Yb, and the opening amount of the on-off valve
12
a
of the air flow rate control means
12
increases after the delay time t
o
as shown with the dotted line Ya, and subsequently increases similarly to that of the throttle valve
11
a
of the fuel mixture flow rate controller
11
. As a result, the same effect that is described above can be obtained at the time of acceleration, and moreover since an air quantity increases when predetermined acceleration is obtained, the air-fuel ratio becomes the same as that at a stationary engine speed, whereby acceleration performance can be improved, and exhaust gas after acceleration can be made cleaner than in the prior art.
In the aforesaid embodiment, the on-off valve
12
a
is structured to be throttled by detecting that the throttle valve
11
a
is changing in an opening direction. Specifically, when the throttle valve
11
a
is changing in an opening direction, the engine is regarded as being then subject to acceleration, whereby the on-off valve
12
a
is throttled. However, the engine may be also regarded as being subject to acceleration by an increase in engine speed, and thereby the on-off valve
12
a
is structured to be throttled. Namely, the on-off valve
12
a
may be structured to throttle an opening by detecting that the rotational frequency of the crankshaft
5
is changing in an increasing direction, for example.
INDUSTRIAL AVAILABILITY
The present invention is useful as a stratified scavenging two-cycle engine, in which control of an air flow rate provides favorable accelerating performance and can prevent deterioration of exhaust gas.
Claims
- 1. A stratified, scavenging, two-cycle engine having a cylinder chamber and a crank chamber, the engine comprising:a fluid flow passage extending between the cylinder chamber and the crank chamber; an air flow passage, in fluid communication with the fluid flow passage, to introduce air to the fluid flow passage; an air flow controller to control a quantity of air introduced from the air flow passage to the fluid flow passage; and a fuel mixture controller to control a quantity of a fuel mixture provided to the crank chamber from a coupled fuel mixture flow passage, wherein the engine effects a reduction of air introduced from the air flow passage to the fluid flow passage at engine acceleration.
- 2. An engine in accordance with claim 1, wherein the air flow controller throttles the quantity of air introduced from the air flow passage to the fluid flow passage at engine acceleration.
- 3. An engine in accordance with claim 1, wherein the air flow controller delays introduction of a conventional air flow to the fluid flow passage a prescribed time after the quantity of a fuel mixture is provided to the crank chamber.
- 4. An engine in accordance with claim 1, further comprising an engine acceleration mechanism, coupled to the air flow controller, to determine an engine acceleration.
- 5. An engine in accordance with claim 4, wherein the engine acceleration mechanism monitors variations in user inputs.
- 6. An engine in accordance with claim 1, wherein the air flow controller includes a first mechanism to open and close the air flow passage and a second mechanism, connected to the first mechanism, to control actuation of the first mechanism in response to a user input.
- 7. A stratified, scavenging, two-cycle engine having a cylinder chamber and a crank chamber, the engine comprising:a fluid flow passage extending between the cylinder chamber and the crank chamber; an air flow passage, in fluid communication with the fluid flow passage, to introduce air to the fluid flow passage; an air flow controller to control a quantity of air introduced from the air flow passage to the fluid flow passage; and a fuel mixture controller to control a quantity of a fuel mixture provided to the crank chamber from a coupled fuel mixture flow passage, wherein at engine acceleration, the air flow controller controls the quantity of air introduced from the air flow passage to the fluid flow passage after delaying such introduction a prescribed time after a fuel mixture is drawn into the crank chamber.
- 8. An engine in accordance with claim 7, further comprising a controller, coupled to the fuel mixture controller and the air flow controller, to manage cooperative operations of the fuel mixture controller and the air flow controller.
- 9. An engine in accordance with claim 7, further comprising an engine acceleration mechanism, coupled to the air flow controller, to determine an engine acceleration.
- 10. An engine in accordance with claim 9, wherein the engine acceleration mechanism monitors variations in user inputs.
- 11. An engine in accordance with claim 7, wherein the air flow controller includes a first mechanism to open and close the air flow passage and a second mechanism, connected to the first mechanism, to control actuation of the first mechanism in response to a user input.
- 12. A method for controlling an introduction of a fuel mixture and an introduction of air to a stratified, scavenging, two-cycle engine, the method comprising the steps of:providing an engine having a fluid flow passage extending between a cylinder chamber and a crank chamber, and an air flow passage, in fluid communication with the fluid flow passage, to introduce air to the fluid flow passage; controlling a flow rate of a fuel mixture drawn into the crank chamber; controlling a flow rate of air introduced to the fluid flow passage; and detecting an engine acceleration, wherein upon detecting an engine acceleration, reducing the flow rate of air introduced to the fluid flow passage for a prescribed time.
- 13. A method in accordance with claim 12, wherein the step of reducing the flow rate of air includes throttling the flow rate of air introduced to the fluid flow passage.
- 14. A method in accordance with claim 12, wherein the step of reducing the flow rate of air includes delaying introduction of a conventional air flow to the fluid flow passage by a prescribed time after a fuel mixture flow is drawn into the crank chamber.
Priority Claims (1)
Number |
Date |
Country |
Kind |
8-274989 |
Oct 1996 |
JP |
|
PCT Information
Filing Document |
Filing Date |
Country |
Kind |
102e Date |
371c Date |
PCT/JP97/03714 |
|
WO |
00 |
4/14/1999 |
4/14/1999 |
Publishing Document |
Publishing Date |
Country |
Kind |
WO98/17902 |
4/30/1998 |
WO |
A |
US Referenced Citations (8)
Foreign Referenced Citations (3)
Number |
Date |
Country |
52-170913 |
Dec 1977 |
JP |
58-19304 |
Apr 1983 |
JP |
7-139358 |
May 1995 |
JP |