Claims
- 1. A watercraft comprising a hull defining an engine compartment, an internal combustion engine supported within the engine compartment, a propulsion device driven by the engine, the engine having an engine body defining a plurality of cylinders, an exhaust system configured to guide exhaust gasses from the engine body to the atmosphere, a cooling system comprising a first cooling jacket in thermal communication with the engine body, a second cooling jacket in thermal communication a portion of the exhaust system, and a coolant passage connecting the first coolant jacket with the second coolant jacket, the cooling system configured to urge cooling water from the second cooling jacket to the first cooling jacket during operation, the coolant passage extending to a point lower than portions of both the first and second cooling jackets, and a drain passage communicating with the point in the coolant passage, the drain passage being configured to drain cooling fluid from the first cooling jacket when the engine is off.
- 2. A small watercraft comprising a hull defining an engine compartment, an internal combustion engine supported within the engine compartment, a propulsion device driven by the engine, the engine having an engine body defining a cylinder and a cooling jacket in thermal communication with the cylinder, a cooling system in fluid communication with the cooling jacket, the cooling system supplying cooling fluid to the cooling jacket through a supply passage, a portion of the supply passage being above a portion of the cooling jacket, and a drain passage communicating with a lower portion of the cooling jacket, the drain passage being configured to drain cooling fluid from the cooling jacket, when the engine is off.
- 3. The small watercraft of claim 2, wherein a flow of cooling fluid within the supply passage is in thermal communication with an exhaust manifold of the engine before entering the cooling jacket.
- 4. The small watercraft of claim 3, wherein the drain passage communicates with the supply passage at a location upstream from the exhaust manifold, the drain passage having a restricted orifice, the orifice having a diameter smaller than a diameter of the supply passage.
- 5. The small watercraft of claim 2, wherein the cooling system additionally comprises a pressure actuated valve upstream from the cooling jacket, the valve permitting cooling fluid to bypass the cooling jacket when the cooling fluid within the valve is above a predetermined pressure.
- 6. The small watercraft of claim 5, wherein the cooling system additionally comprises a temperature actuated valve downstream from the cooling jacket, the temperature actuated valve substantially preventing cooling fluid from exiting the engine body when the cooling fluid within the cooling jacket is below a predetermined temperature.
- 7. The small watercraft of claim 6, additionally comprising a lubrication system including a lubricant reservoir, wherein the cooling system supplies cooling fluid to the reservoir independently of the engine.
- 8. A method of draining cooling fluid from a small watercraft engine having a first cooling jacket at least partially surrounding a cylinder of the engine, the method comprising supplying the cooling fluid to the engine through a supply passage, routing the supply passage into thermal communication with an exhaust manifold of the engine at a height above a portion of the first cooling jacket, routing the supply passage into fluid communication with the first cooling jacket to supply the cooling fluid to the first cooling jacket and cool the engine while it is running, and allowing the cooling fluid to drain from a lower portion of the first cooling jacket through a drain passage after the engine has stopped running.
- 9. A method of draining cooling fluid from a small watercraft engine having a first cooling jacket at least partially surrounding a cylinder of the engine, the method comprising supplying the cooling fluid to the engine through a supply passage, routing the supply passage into thermal communication with an exhaust manifold of the engine at a height above a portion of the first cooling jacket, routing the supply passage into fluid communication with the first cooling jacket to supply the cooling fluid to the first cooling jacket and cool the engine while it is running, allowing the cooling fluid to drain from a lower portion of the first cooling jacket through a drain passage after the engine has stopped running, and connecting the drain passage to a portion of the supply passage upstream from the exhaust manifold and allowing the cooling fluid to drain through the supply passage when the engine is not running.
- 10. The method of claim 9, wherein a portion of the cooling fluid flows through the drain passage and into the cooling jacket when the engine is running, additionally comprising permitting less flow through the drain passage than through the supply passage.
- 11. A marine engine comprising an engine body defining a cylinder, a cooling jacket at least partially surrounding the cylinder, a cooling system in fluid communication with the cooling jacket, the cooling system supplying cooling fluid to the cooling jacket through a supply passage, a portion of the supply passage being above a portion of the cooling jacket, and a drain passage communicating with a lower portion of the cooling jacket, the drain passage being configured to drain cooling fluid from the cooling jacket when the engine is off.
- 12. The marine engine of claim 11, wherein a flow of cooling fluid within the supply passage is in thermal communication with an exhaust manifold of the engine before entering the cooling jacket.
- 13. A marine engine comprising an engine body defining a cylinder, a cooling jacket at least partially surrounding the cylinder, a cooling system in fluid communication with the cooling jacket, the cooling system supplying cooling fluid to the cooling jacket through a supply passage, a portion of the supply passage being above a portion of the cooling jacket, and a drain passage communicating with a lower portion of the cooling jacket, the drain passage being configured to drain cooling fluid from the cooling jacket, wherein a flow of cooling fluid within the supply passage is in thermal communication with an exhaust manifold of the engine before entering the cooling jacket, and wherein the drain passage communicates with the supply passage at a location upstream from the exhaust manifold, the drain passage having a restricted orifice, the orifice having a diameter smaller than a diameter of the supply passage.
- 14. The marine engine of claim 11, wherein the cooling system additionally comprises a pressure actuated valve upstream from the cooling jacket, the valve permitting cooling fluid to bypass the cooling jacket when the cooling fluid within the valve is above a predetermined pressure.
- 15. The marine engine of claim 14, wherein the cooling system additionally comprises a temperature actuated valve downstream from the cooling jacket, the temperature actuated valve substantially preventing cooling fluid from exiting the engine body when the cooling fluid within the cooling jacket is below a predetermined temperature.
- 16. The marine engine of claim 15, additionally comprising a lubrication system including a lubricant reservoir, wherein the cooling system supplies cooling fluid to the reservoir independently of the engine.
- 17. A small watercraft comprising a hull defining an engine compartment, an internal combustion engine supported within the engine compartment, a propulsion device driven by the engine, the engine having an engine body defining a cylinder and a first cooling jacket in thermal communication with the cylinder of the engine, a supply passage that supplies cooling fluid to the engine, the supply passage being routed in thermal communication with an exhaust manifold of the engine at a height above a portion of the first cooling jacket and communicating with the first cooling jacket to supply the cooling fluid to the first cooling jacket to cool the engine while running, a drain passage which configured to allow the cooling fluid to drain from a lower portion of the first cooling jacket after the engine has stopped running, wherein the drain passage is connected to a portion of the supply passage upstream from the exhaust manifold and allows the cooling fluid to drain through the supply passage when the engine is not running.
- 18. A small watercraft in accordance with claim 17, wherein a portion of the cooling fluid flows through the drain passage and into the cooling jacket when the engine is running, additionally comprising permitting less flow through the drain passage than through the supply passage.
- 19. The watercraft of claim 1, wherein the point is positioned below the exhaust manifold.
- 20. The watercraft of claim 19, wherein the point is positioned below the cylinder block.
- 21. The watercraft of claim 1, wherein other portions of the exhaust system are lower than the point.
- 22. The watercraft of claim 1, wherein the cooling system does not comprise a pressure actuated valve upstream from the cooling jacket that permits cooling fluid to exit the cooling jacket when the cooling fluid within the valve is above a predetermined pressure.
- 23. The watercraft of claim 1, wherein the cooling system is configured to freely drain coolant from the cooling jackets when the engine is off.
- 24. The watercraft of claim 1, wherein the cooling system is configured to permit cooling fluid at atmospheric pressure to drain from the first and second cooling jackets through the drain passage.
- 25. The small watercraft of claim 2, wherein the drain passage communicates with a lower portion of the cooling jacket at a point below the exhaust manifold.
- 26. The small watercraft of claim 2, wherein the drain passage communicates with a lower portion of the cooling jacket at a point below the cylinder block.
- 27. The small watercraft of claim 2, wherein the cooling system is configured to permit cooling fluid at atmospheric pressure to drain from the first and second cooling jackets through the drain passage.
- 28. The small watercraft of claim 2, wherein the cooling system permits draining at atmospheric pressure.
- 29. The marine engine of claim 11, wherein the coolant drains freely when the engine is not running.
- 30. The marine engine of claim 11, wherein coolant drains from the cooling jackets without a pressure actuated valve upstream from the cooling jacket that permits cooling system to expel the cooling fluid when the cooling fluid within the cooling jacket is above a predetermined pressure.
Priority Claims (1)
Number |
Date |
Country |
Kind |
2001-238303 |
Aug 2001 |
JP |
|
PRIORITY INFORMATION
This application is based on, and claims priority to, Japanese Patent Application No. 2001-238303, filed Aug. 6, 2001, the entire contents of which are expressly incorporated by reference herein.
US Referenced Citations (11)
Foreign Referenced Citations (1)
Number |
Date |
Country |
10-238358 |
Sep 1998 |
JP |
Non-Patent Literature Citations (1)
Entry |
Copy of Copending application; Application No. 10/060,866; Filed Jan. 29, 2002 (Our Reference: FS.17465US0A). |