1. Field of the Invention
The present invention relates to an outboard motor to be mounted in a boat.
2. Description of the Related Art
In general, an outboard motor mounted in a boat has an upper casing and a lower casing, and an engine is disposed in the upper casing. An exhaust passage connected to a plurality of cylinders in the engine is disposed to extend from the inside of the upper casing to a bottom portion of the lower casing. The exhaust passage is provided with a catalyst that purifies exhaust gas.
In such a construction, exhaust gas flowing out from each cylinder to the exhaust passage is purified in the catalyst, and then discharged into water from the bottom portion of the lower casing.
A lower end portion of the exhaust passage is immersed in water. Therefore, water in the lower end portion of the exhaust passage may flow backward to an engine side as a result of negative pressure or the like that is generated in the engine. Especially, a four-stroke engine is largely affected by exhaust pulsation, so water is sucked into an engine side by strong force in the exhaust passage.
In order to prevent deterioration of the catalyst, water flowing backward in the exhaust passage must be prevented from adhering to the catalyst. To prevent water adhesion to the catalyst, an outboard motor in which a catalyst is disposed in an upper casing has been developed (for example, refer to JP-A-2000-356123).
However, even if a catalyst is simply disposed in the upper casing as indicated in JP-A-2000-356123, water adhesion to the catalyst cannot be sufficiently prevented when water flows backward in the exhaust passage. In addition, with the construction of the outboard motor described in JP-A-2000-356123, the catalyst must be disposed at an even higher position to securely prevent water adhesion to the catalyst. Accordingly, the size of the outboard motor is disadvantageously increased.
In order to overcome the problems described above, preferred embodiments of the present invention provide an outboard motor that can sufficiently prevent water adhesion to a catalyst while avoiding any increase in size.
An outboard motor according to a preferred embodiment of the present invention preferably includes a cowling, an engine body having a plurality of cylinders disposed to be lined vertically in the cowling, a discharge section that is disposed below the cowling and discharges burned gas generated in the plurality of cylinders, a discharge passage that guides burned gas from the plurality cylinders to the discharge section, and a catalyst that purifies the burned gas in the exhaust passage. The exhaust passage includes a plurality of first passages connected to the plurality of cylinders, and disposed to be joined at a flow-joining portion located below the topmost cylinder, a second passage connected to the flow-joining portion and extending above the flow-joining portion, and a third passage that passes above the topmost cylinder from an upper end of the second passage and is connected to the discharge section. The catalyst is disposed in the second passage.
In this outboard motor, the engine body is disposed in the cowling. The discharge section, which discharges burned gas in a plurality of cylinders of the engine body to the outside, is disposed in a lower portion of the cowling. Burned gas discharged from a plurality of cylinders of the engine body is guided to the discharge section through the exhaust passage.
The exhaust passage includes the first passage, the second passage, and the third passage. Burned gas discharged from each cylinder is guided to the discharge section while sequentially passing through the first to third passages. The catalyst, which purifies burned gas, is disposed in the second passage.
In this outboard motor, the third passage is arranged to pass above the topmost cylinder. That is, a portion of the third passage is disposed at a sufficiently high position in the cowling.
In this case, when water intrudes from the discharge section into the third passage, the water can be prevented from passing the third passage and intruding into the second passage. Accordingly, water adhesion to the catalyst can be prevented. As a result, lowering of catalyst purification performance can be prevented.
The second passage is disposed to be connected to a joining portion of the first passage and to extend higher than the flow-joining portion. The flow-joining portion is located lower than the topmost cylinder. In this case, the catalyst can be disposed lower than the topmost cylinder by disposing the catalyst in the second passage. Accordingly, the catalyst can be disposed in the outboard motor while a vertical height of the outboard motor is prevented from being increased.
As a result, water adhesion to the catalyst can be sufficiently prevented while the outboard motor avoids any increase in size.
The second passage preferably has a first straight passage disposed to extend vertically on the side of a plurality of cylinders. The catalyst may be disposed in the first straight passage.
In this case, an increase in the width of the outboard motor can be prevented by disposing the catalyst in the first straight passage.
The third passage may preferably have a second straight passage disposed on the opposite side of the plurality of cylinders from the first straight passage, and a connection passage that is disposed above the topmost cylinder and that connects the second passage and the second straight passage.
In this case, the second straight passage is disposed on the opposite side of the plurality of cylinders from the first straight passage. Thus, the plurality of cylinders can be disposed in the center or approximate center of the cowling. Accordingly, stability of the outboard motor can be improved.
The connection passage is disposed above the topmost cylinder. Thus, water can be securely prevented from flowing into the second passage from the second straight passage. Accordingly, water adhesion to the catalyst can be securely prevented.
A plurality of cylinders and the second straight passage preferably may be provided in a common cylinder block.
In this case, the exhaust passage can be integral with the cylinder block. Thus, structure around the engine body can be simplified.
The outboard motor may further include a first oxygen sensor disposed at an upstream side of the catalyst in the exhaust passage.
In this case, water adhesion to the first oxygen sensor can be securely prevented. Accordingly, the first oxygen sensor can be improved in reliability. As a result, an air-fuel ratio of burned gas can be detected in high precision based on a detected value of the first oxygen sensor.
The outboard motor may further include a second oxygen sensor disposed at a downstream side of the catalyst in the second passage.
In this case, the second passage is disposed upstream of the third passage. Thus, water adhesion to the second oxygen sensor can be securely prevented. Accordingly, the second oxygen sensor can be improved in reliability. As a result, an air-fuel ratio of burned gas, which has been purified through the catalyst, can be detected with high precision based on a detected value of the second oxygen sensor. Accordingly, a purification rate of burned gas by the catalyst can be detected in high precision.
The outboard motor preferably may further include a moisture capture member disposed in the third passage above the topmost cylinder.
In this case, when droplets are created by the water intruded from the discharge section into the discharge passage, the droplets can be captured by the moisture capture member. Accordingly, droplet adhesion to the catalyst can be prevented.
In the exhaust passage, when a sensor such as an oxygen sensor is disposed at an upstream side of the moisture capture member, droplet adhesion to the sensor can be prevented. Accordingly, the sensor can be sufficiently improved in reliability.
The outboard motor may preferably further include a first temperature sensor disposed in a downstream side of the catalyst in the second passage.
In this case, the second passage is disposed upstream of the third passage. Thus, water adhesion to the first temperature sensor can be securely prevented. Accordingly, the first temperature sensor can be improved in reliability. As a result, a purification state of burned gas in the catalyst can be detected with high precision based on a detected value of the first temperature sensor. Accordingly, a determination can be easily made whether the catalyst is functioning normally or not.
The outboard motor preferably may further include a second temperature sensor disposed in the third passage further below than the topmost cylinder.
In this case, water intrusion into the exhaust passage can be detected by the second temperature sensor.
The outboard motor may further include a controller arranged to perform water intrusion suppression control to suppress water intrusion from the discharge section into the discharge passage based on a detected value of the second temperature sensor.
In this case, water intrusion suppression control can be performed quickly based on the detected value of the second temperature sensor. Accordingly, water is securely prevented from flowing backward in the exhaust passage.
The outboard motor preferably may further include a cooling water passage disposed to cover the exhaust passage, and an air vent disposed generally at the highest portion of the cooling water passage.
In this case, the exhaust passage can be cooled by cooling water in the cooling water passage. Thus, temperature increases in the catalyst can be prevented. Accordingly, temperature increases in the cowling and components of the engine body can be prevented.
In this outboard motor, the air vent preferably is disposed generally at the highest portion of the cooling water passage. In this case, air collected in an upper portion of the cooling water passage can be efficiently discharged. Thus, cooling water can be efficiently supplied to the entire cooling water passage. As a result, the exhaust passage can be efficiently cooled.
The outboard motor may further include an intake passage that guides air to a plurality of cylinders, and the intake passage may be disposed to pass between the third passage and the cowling. In this case, the intake passage can be provided without any increase in size of the cowling.
The outboard motor preferably may further include a timing belt disposed above the engine body, and a belt tensioner that is disposed above the engine body and applies tension to the timing belt. The third passage may be disposed to pass above the belt tensioner.
In this case, expansion of the timing belt in the width direction can be sufficiently limited by the belt tensioner.
The third passage is preferably arranged to pass above the belt tensioner. Thus, the third passage can be arranged to pass above a position where the expansion of the timing belt in the width direction is sufficiently squeezed. In this case, when a portion of the third passage is disposed on the opposite side of a plurality of cylinders from the second passage, a portion of the third passage and the second passage can be prevented from being widely separated. Accordingly, an increase in the width of the outboard motor can be prevented.
The outboard motor preferably may further include a flywheel magneto cover disposed above the engine body and the timing belt, and the third passage may be disposed to pass between the timing belt and the flywheel magneto cover.
In this case, the third passage is cooled by an air current generated in the flywheel magneto cover. Accordingly, a temperature increase in the exhaust passage can be prevented. Thus, a temperature increase of the catalyst can be prevented.
The outboard motor preferably may further include the cooling water passage disposed to cover the exhaust passage, and a cooling water supply portion disposed in an area that covers a lower end portion of the first passage of the cooling water passage or a lower end portion of the second passage of the cooling water passage.
In this case, the exhaust passage can be cooled by the cooling water passage. The cooling water supply portion is disposed in an area of the cooling water passage that covers the lower end portion of the first passage or the lower end portion of the second passage. That is, the cooling water supply portion is disposed in a lower end portion of the cooling water passage. In this case, the cooling water supply portion is utilized as a discharge section of cooling water, so that cooling water in the cooling water passage can be efficiently discharged from the cooling water supply portion.
The lower end portion of the first or second passage preferably may be located below the bottommost cylinder.
In this case, when water is collected in the lower end portion of the first or second passage due to condensation or the like, the water flow to the downstream side by burned gas discharged from each cylinder can be prevented. Accordingly, water adhesion to the catalyst can be securely prevented.
According to various preferred embodiments of the present invention, when water intrudes from the discharge section into the third passage, the water can be prevented from passing the third passage and intruding into the second passage. Accordingly, water adhesion to the catalyst can be prevented. As a result, a decrease in the catalyst purification performance can be prevented.
The catalyst can be disposed lower than the topmost cylinder. Accordingly, the catalyst can be disposed in the outboard motor while an increase in a vertical height of the outboard motor is prevented.
As a result, water adhesion to the catalyst can be sufficiently prevented while preventing any increase in size of the outboard motor.
Other features, elements, steps, characteristics and advantages of the present invention will become more apparent from the following detailed description of preferred embodiments of the present invention with reference to the attached drawings.
Hereinafter, an outboard motor according to preferred embodiments of the present invention is described with reference to drawings.
In a preferred embodiment described below, a downstream end opening 7a is an example of discharge section; a flow-joining pipe 134, a first exhaust pipe 71, a second exhaust pipe 72, third exhaust pipe 73, an exhaust passage 70, and an exhaust passage 7 are examples of an exhaust passage; a flow-joining pipe 134 is an example of a first passage; a first exhaust pipe 71 and a second exhaust passage 72 are examples of second passage; a third exhaust pipe 73, an exhaust passage 70, and an exhaust passage 7 are examples of a third passage; a second exhaust pipe 72 is an example of a first straight passage; an exhaust passage 70 is an example of a second straight passage; a third exhaust pipe 73 is an example of a connection passage; a flow path 700 is an example of a cooling water passage; an extension pipe 731 is an example of an air vent; an intake pipe 56 is an example of an intake passage; and an ECU 103 is an example of a controller.
The above description merely provides non-limiting elements of preferred embodiments of the present invention. Other various elements that have the same or similar constitution or function as described herein may be used.
As shown in
The outboard motor 100 is mounted to a hull 901 of a boat 900 through the clamp bracket 3. In
An engine 5 is disposed in the upper casing 1. The engine 5 is fixed to the exhaust guide 4. A propeller 6 is disposed in a lower portion of the lower casing 2. An exhaust passage 7 is disposed in the lower casing 2. The exhaust passage 7 is arranged to extend from the engine 5 through the exhaust guide 4 and the lower casing 2 to a rear end of the propeller 6. An upper end of the exhaust passage 7 is connected to the after-mentioned exhaust passage 70 (refer to
A drive shaft 8 is disposed in the lower casing 2 along a vertical direction. The drive shaft 8 is fixed to a crankshaft 142 (refer to
According to the structure described above, the driving force generated by the engine 5 is transmitted through the drive shaft 8 and the propeller shaft 9 to the propeller 6. Thus, the propeller rotates in a normal direction or a reverse direction. As a result, a propulsive force to propel the boat 900 forward or backward is generated. Exhaust gas (burned gas) discharged from the engine 5 is discharged into the water from a downstream end opening 7a of the exhaust passage 7.
Hereinafter, the engine 5 and its surrounding structure are described in detail with reference to the drawings.
Hereinafter, an arrangement of peripheral devices of the engine 5 is described with reference to drawings.
As shown in
A drive pulley 52 is disposed above a front portion of the engine body 51. The drive pulley 52 is fixed to the crankshaft 142 (refer to
The exhaust passage 70 is located on a +Y side of the engine body 51. One end of the first exhaust pipe 71 (
One end of the third exhaust pipe 73 in the shape of inverted U is connected to the other end of the second exhaust pipe 72. The other end of the third exhaust pipe 73 is connected to one end of the exhaust passage 70. The third exhaust pipe 73 is disposed to pass above the timing belt 55. The extension pipe 731 is disposed in the third exhaust pipe 73. The extension pipe 731 is described later.
In this way, the first and second exhaust pipes 71, 72 are disposed on one side of the engine body 51, and the exhaust passage 70 is disposed on the other side thereof. The third exhaust pipe 73 is arranged to pass above the engine body 51 to connect the second exhaust pipe 72 and the exhaust passage 70. Accordingly, when water flows backward in the exhaust passage 7 in
As described above, the catalyst 11 (refer to
First ends of a plurality of intake pipes 56 (for example, four pipes in the present preferred embodiment) are connected to a side surface of the engine body 51 on the +Y side. Second ends of the plurality of intake pipes 56 are connected to a surge tank 57 disposed on the +Y side of the engine body 51. A throttle body 58 and a throttle drive motor 59 are disposed on a lower portion of the surge tank 57.
As shown in
As shown in
As shown in
As shown in
As shown in
Now, a construction of the engine 5 is described in detail with reference to the drawings.
As shown in
The intake pipe 56 is connected to each intake port 132. The flow-joining pipe 134 is connected to the four exhaust ports 133. As shown in
The branch portions 91 to 94 are disposed to be lined in the vertical direction. The flow-joining portion 95 is disposed generally at the same height as the branch portion 94, which is the bottommost of the branch portions 91 to 94. The branch portions 91 to 94 are connected to the exhaust port 133, and the flow-joining portion 95 is connected to the first exhaust pipe 71.
As shown in
As shown in
As shown in
As shown in
As shown in
When the engine 5 is not operated, cooling water in the flow path 700 is discharged through the cooling water supply portion 711 and the extension pipe 712. In the present preferred embodiment, the cooling water supply portion 711 is disposed in the lower end portion of the first exhaust pipe 71. Accordingly, cooling water in the flow path 700 can be discharged efficiently and securely. As a result, cooling water is sufficiently prevented from remaining in the flow path 700.
As shown in
As shown in
As the first and second oxygen sensors OS1, OS2, a sensor using a ceramic component can be preferably used, for example. An oxygen sensor including zirconia ceramics can be preferably used, for example.
The first oxygen sensor OS1 detects an oxygen concentration in the first exhaust pipe 71. The second oxygen sensor OS2 detects an oxygen concentration in the second exhaust pipe 72. The first temperature sensor TS1 detects temperature in the second exhaust pipe 72. Detected values of the first oxygen sensor OS1, the second oxygen sensor OS2, and the first temperature sensor TS1 are supplied to the ECU 103 in
The ECU 103 adjusts an air-fuel ratio of mixture in the cylinder 131 (
The ECU 103 determines whether or not exhaust gas is properly purified in the catalyst 11 based on a detected value of the second oxygen sensor OS2.
The ECU 103 drives a fan 226 (
The first oxygen sensor OS1 is preferably disposed above a bottom cowling 303 (
As shown in
The second temperature sensor TS2 is disposed in a lower end portion of the exhaust passage 70. The second temperature sensor TS2 detects temperature in the exhaust passage 70. A detected value of the second temperature sensor TS2 is supplied to the ECU 103. The ECU 103 determines whether or not water is intruded into the exhaust passage 70 based on a detected value of the second temperature sensor TS2.
As shown in
As shown in
An upper end portion of the drive shaft 8 is connected to a lower end portion of the crankshaft 142. Accordingly, the torque of the crankshaft 142 is transmitted to the drive shaft 8.
As shown in
A fin 146 is attached to an upper end portion of the crankshaft 142. The fin 146 is rotated with the rotation of the crankshaft 142. Accordingly, heat in the upper casing 1 is discharged to the outside. A heat discharge pathway in the upper casing 1 is described later.
The flywheel magneto cover 200 is disposed above the crankcase 141 so as to cover the flywheel magneto 144 and the fin 146. The flywheel magneto cover 200 is described in detail in later paragraph.
As shown in
As shown in
As shown in
In the space 312, an inlet opening 314 is disposed in an upper surface of the top cowling 302. In the space 313, a ventilation opening 315 is disposed in an upper surface of the top cowling 302.
In the present preferred embodiment, air in the outside of the upper casing 1 is supplied through the space 312, the inlet opening 314, and the flywheel magneto cover 200 to the communication pipe 104 (
Construction of the flywheel magneto cover 200 is described in detail with reference to the drawings.
As shown in
As shown in
As shown in
As shown in
As shown in
As shown in
As shown in
As shown in
As shown in
As shown in
As shown in
Hereinafter, an intake passage from the inlet opening 314 to the engine 5 is described.
As described above, in the present preferred embodiment, the elastic member 213 (
As indicated by the arrows in
A ventilation passage in the top cowling 302 (
The fin 146 (
As indicated by the arrows in
On the other hand, when the engine 5 stops, the fan 226 (
The air discharged into the space 313 is discharged to the outside of the top cover 301 from a discharge section provided in the space 313 or from a gap between the top cover 301 and the top cowling 302.
As described above, ventilation is performed in the top cowling 302. The ECU 103 stops the drive of the fan 226, if the temperature in the second exhaust pipe 72 (
As described above, in the present preferred embodiment, the catalyst cover 137 is disposed to cover the first and second exhaust pipes 71, 72 (
(a) Effects Caused by Positional Arrangement of the Catalyst 11 and the First and Second Oxygen Sensors OS1, OS2
As shown in
In the present preferred embodiment, the third exhaust pipe 73 is arranged to pass above the cylinder block 101. That is, the third exhaust pipe 73 is disposed sufficiently high in the upper casing 1.
In this case, in a case where water flows in reverse in the exhaust passage 7 (
(b) Effects of Flow-Joining Pipe 134
As shown in
As shown in
The first and second exhaust pipes 71, 72 and the exhaust passage 70 face each other while interposing the plurality of cylinders 131. In this case, the plurality of cylinders 131 can be disposed in the center of the upper casing 1. Accordingly, stability of the outboard motor 100 can be improved.
(d) Effect of Shape of Exhaust Passage 70
As shown in
(e) Effects of Positional Arrangement of Third Exhaust Pipe 73
As shown in
As shown in
(f) Effects of Positional Arrangement of Belt Tensioner 551
As shown in
(g) Effects of Positional Arrangement of First Exhaust Pipe 71
As shown in
(a) Effects of Fan 226
As shown in
(b) Effects of Ventilation Passage
In the present preferred embodiment, when the engine 5 is operates, ventilation in the top cowling 302 is performed by the fin 146. When the engine 5 stops operation, ventilation in the top cowling 302 is performed by the fan 226.
As shown in
In this case, the number of passages used for ventilation can be reduced. Thus, the flywheel magneto cover 200 can be downsized.
(c) Effects of Elastic Member 213
As shown in
In this case, when water flows into the ventilation opening 315 together with air, the water can be prevented from flowing into the intake duct 105. Accordingly, reliability of the engine 5 can be improved.
(d) Effect of Shape of Inflow Opening 231
As shown in
In the above preferred embodiment, as shown in
The first oxygen sensor OS1 is preferably disposed upstream of the catalyst 11 and downstream of the branch portion 94 of the flow-joining pipe 134. In this case, an average value of air-fuel ratio of exhaust gas discharged from each cylinder 131 can be detected with high precision.
In the above preferred embodiment, the second oxygen sensor OS2 is preferably disposed in the second exhaust pipe 72. However, the second oxygen sensor OS2 may not be disposed necessarily. In this case, the ECU 103 may determine whether or not exhaust gas is properly purified in the catalyst 11 based on a detected value of the first temperature sensor TS1.
In the above-described preferred embodiment, the cooling water supply portion 711 and the extension pipe 712 are disposed in the lower end portion of the first exhaust pipe 71. However, the cooling water supply portion 711 and the extension pipe 712 may be disposed in the lower end portion of the flow-joining pipe 134.
In the above-described preferred embodiment, the communication passage 713 is disposed in the lower end portion of the first exhaust pipe 71. However, the communication passage 713 may be disposed in the lower end portion of the flow-joining portion 95.
The third exhaust pipe 73 does not have to pass above the topmost cylinder 131. It is acceptable as long as a portion of the third exhaust pipe 73 is located above the cylinder 131.
The number of the cylinders 131 does not have to be four, but may be less than or more than four, for example.
Two or more of the flow-joining pipe 134, the first exhaust pipe 71, the second exhaust pipe 72, the third exhaust pipe 73, and the exhaust passage 70 may be integrally formed.
In the above-described preferred embodiment, when the temperature in the second exhaust pipe 72 reaches a certain degree or more, the fan 226 is driven by the ECU 103. However, the condition for driving the fan 226 is not limited to the above example. For example, a temperature sensor may be disposed in the engine body 51, and the fan 226 may be driven by the ECU 103 when the temperature detected by the temperature sensor reaches a certain degree or more.
The outboard motor according to the present preferred embodiment differs from the outboard motor 100 according to the first preferred embodiment in the following points.
As shown in
In the present preferred embodiment, since the moisture capture member 400 is disposed in the third exhaust pipe 73, moisture in the third exhaust pipe 73 can be surely removed in the moisture capture member 400. Accordingly, droplets, which are created by water flown into the exhaust passage 70, can be securely prevented from flowing into the second exhaust pipe 72 and the first exhaust pipe 71 through the third exhaust pipe 73. As a result, the catalyst 11, the first oxygen sensor OS1, and the second oxygen sensor 0S2 can be sufficiently improved in reliability.
The outboard motor according to the present preferred embodiment differs from the outboard motor 100 according to the first preferred embodiment in the following points.
As shown in
A first cylinder head 1021 and a second cylinder head 1022 are disposed on the −X side of the first branch portion 1011 and that of the second branch portion 1012, respectively. In the same way as in
Idler pulleys 561, 562 and the belt tensioner 563 are disposed in a center portion of a top surface of the cylinder block 101. The outer peripheral surface of the timing belt 55 is abutted on the idler pulley 561 in a position between the drive pulley 52 and the driven pulley 54 on the first cylinder head 1021. The outer peripheral surface of the timing belt 55 is abutted on the idler pulley 562 in a position between the driven pulley 53 on the first cylinder head 1021 and the driven pulley 53 on the second cylinder head 1022. The outer peripheral surface of the timing belt 55 is abutted on the belt tensioner 563 in a position between the driven pulley 54 on the second cylinder head 1022 and the driven pulley 52.
The surge tank 57 is disposed on the −X side of the first and second cylinder heads 1021, 1022. The surge tank 57 is provided with the throttle body 58 and the plurality of intake pipes 56.
In the same way as in
The flow-joining pipe 134 similar to that of
The flow-joining pipes 134 are connected with the first and second exhaust pipes 71, 72 respectively in the same way as in
Two exhaust passages 70 are provided in the cylinder block 101 between the first cylinder head 1021 and the second cylinder head 1022 in the same way as in
In the same way as in
The outboard motor according to the present preferred embodiment differs from the outboard motor according to the third preferred embodiment in the following points.
As shown in
The flow-joining pipes 134 similar to the one in
The exhaust passages 70 similar to the one in
According to the control system described below, problems pertaining to general outboard motors can be solved. First, problems pertaining to general outboard motors are described.
In a case where opening of a throttle valve of an outboard motor engine is reduced quickly when a boat is traveling at high speed, a hull has a large braking force applied thereto and the boat speed is reduced suddenly. This causes, water in the vicinity of a rear portion of the hull to pass the hull (hereinafter, referred to as the following wave effect).
If a position of a gear (hereinafter, referred to as a shift gear), which switches between forward travel and backward travel, is switched from a forward traveling position to a backward traveling position in a state where the hull speed is reduced due to the above braking force, a propeller of the outboard motor rotates so as to push water from the rear to the front.
Under such a state, water, which is pushed to the front by the following wave effect and the propeller, may intrude into an exhaust passage from an outlet of exhaust gas. However, in a state where the engine is operated, due to exhaust pressure from the engine, water intruded from the outlet is prevented from reaching a top portion of the outboard motor.
On the other hand, when the hull is suddenly reduced in speed, water flows from the front to the rear with respect to the propeller since the hull travels forward through inertia. This water flow applies torque to the propeller. If the shift gear is set in a forward traveling position in such a state, engine speed is determined by the torque applied from the engine to the crankshaft and by the torque applied from water flow to the propeller.
In a case where the throttle valve is fully closed when the hull is traveling through inertia, the torque applied from water flow to the propeller becomes larger than the torque applied from the engine to the crankshaft. When the shift gear is changed to a backward position in such a state, the propeller is applied with the torque what is in an opposite direction of the torque applied from the engine to the crankshaft and that is larger than the torque applied from the engine to the crankshaft. Accordingly, the engine is caused to miss and stop.
In this case, the crankshaft rotates in reverse by the torque provided from the propeller, and exhaust gas in the exhaust passage flows backward. Accordingly, water intruded from the outlet into the exhaust passage may be sucked further.
As shown in
The throttle sensor 601 is disposed in the throttle drive motor 59 (
The fuel injection device 501 is disposed in the intake port 132, for example, and injects fuel into the intake port 132. The informing lamp 502 is disposed in a position where it can be visually recognized by an operator of the hull 901 (
In the construction described above, if a change amount of a detected value of the second temperature sensor TS2 exceeds a certain threshold values per unit time (if temperature is decreased suddenly), the ECU 103 executes a water intrusion suppression control described below.
In the water intrusion suppression control, when the throttle opening is a certain threshold value or lower, when the speed of the hull 901 is a certain threshold value or higher, and when a shift position is in a forward position, the ECU 103 sets the shortest overlap period of an intake valve (not shown) and an exhaust valve (not shown) by increasing the throttle opening of the electronic throttle 504 to a certain target value and by adjusting an oil amount of the OCV 126.
Accordingly, torque generated in the engine 5 can be increased. At the same time, an amount of burned gas (EGR gas) that flows backward into the engine 5 can be reduced by shortening the overlap period. As a result, when any of the problems as described above occurs to the outboard motor 100, engine misfire can be prevented. Accordingly, backflow of water to an upper portion of the outboard motor 100 can be prevented.
The certain target value of throttle opening described above is set larger than the certain threshold value of throttle opening described above. The certain target value of throttle opening is a variable set in accordance with a load of the engine 5 that is calculated based on the hull speed and a detected value of the intake pressure sensor 604.
In addition to the control described above, the ECU 103 may control the ignition device 503 to advance an ignition timing of fuel-air mixture in the engine 5 to the proximity of engine knock.
The certain target value of throttle opening may be calculated by the ECU 103 in accordance with hull speed, so that the engine speed can be reduced as much as possible while misfire is avoided.
In the present preferred embodiment, the ECU 103 preferably sets the appropriate target value of throttle opening in accordance with the hull speed, and adjusts an injection amount of fuel injected by the fuel injection device 501 to adjust an air-fuel ratio to an appropriate value.
The ECU 103 determines whether or not exhaust gas is properly purified in the catalyst 11 (
The ECU 103 controls the fan 226 based on a detected value of the engine speed sensor 603. In detail, the ECU 103 actuates the fan 226 when the engine 5 stops. Accordingly, a temperature increase in the top cowling 302 (
The ECU 103 may control the fan 226 based on a detected value of the first temperature sensor TS1. Accordingly, a temperature increase in the top cowling 302 (
The present invention can be effectively utilized in an outboard motor mounted in a boat.
While preferred embodiments of the present invention have been described above, it is to be understood that variations and modifications will be apparent to those skilled in the art without departing the scope and spirit of the present invention. The scope of the present invention, therefore, is to be determined solely by the following claims.
Number | Date | Country | Kind |
---|---|---|---|
2008-042374 | Feb 2008 | JP | national |