The present invention relates to an engine for an outboard motor having an oil filter.
There have been conventionally known outboard motors which include oil filters for filtering engine oil, such as the one disclosed in Japanese Patent Application Laid-Open Publication No. 2005-343226 (JP 2005-343226 A).
Referring to
The oil filter 103 is replaced either periodically or after a specified amount of use.
According to
It is therefore an object of the present invention to provide an engine for an outboard motor in which the oil filter can be replaced without the oil flowing out to the exterior.
According to the present invention, there is provided an engine for an outboard motor, which engine comprises: an oil pan disposed underneath a crank chamber; an oil pump for pumping up oil in the oil pan; an oil filter for filtering the oil that has been pumped up; and a vertically extending oil passage for leading the filtered oil to parts required by the engine, wherein the oil passage has a communication duct disposed lower than the oil filter and communicating with the crank chamber, the communication duct being closed by a drain valve capable of manual opening and closing.
In this arrangement, opening the drain valve allows the oil accumulated in the oil passage to flow out into the crank chamber. Since the oil that has accumulated inside the oil passage is no longer higher than the oil filter, the oil will not flow out to the exterior when the oil filter is removed. As a result, the operation of replacing the oil filter is improved. Additionally, since the amount of oil in the engine is not reduced and there is no need to refill oil, it is possible to reduce the number of steps in the operation.
Preferably, the oil passage has an air inlet duct positioned higher than the oil filter and designed to let air in from an exterior, the air inlet duct being closed by an air vent bolt capable of manual opening and closing. As a result, air is led into the oil passage when the air vent bolt is opened. When air is led into the oil passage, the flow rate of oil significantly increases. As a result, the oil filter can be removed immediately, and the overall operation time can be reduced.
Desirably, the drain valve has a tapered part at a distal end thereof for closing off the communication duct. As a result, it becomes possible to reduce machining expenses because it is easy to machine a taper in the cylinder block-facing side of the drain valve where the tapered part is formed.
In a preferred form, the drain valve has a small-sectional-area part located farther distally outward than the tapered part and having less sectional surface area than a flow passage surface area of the communication duct, the small-sectional-area part being inserted through the communication duct. Thus, oil can flow out into the crank chamber when the small-sectional-area part has been inserted through the communication duct, the drain valve is easily closed back up, and the number of steps in the operation can therefore be reduced.
A preferred embodiment of the present invention will be described in detail below, by way of example only, with reference to the accompanying drawings, in which:
Referring to
The outboard motor 10 includes an engine cover 12 for covering the top of the engine 11, an under cover 13 provided underneath the engine cover 12, an extension cover 14 provided underneath the under cover 13, and a gear case 15 provided underneath the extension cover 14.
A stern bracket 16 for attaching the outboard motor 10 to the hull is installed on the front of the under cover 13.
An air intake silencer 17 for leading outside air (fresh air) into an engine air intake port is disposed in front of the engine 11, and behind the air intake silencer 17 is disposed an electric component 18 for controlling the ignition of the engine and controlling the fuel injection device.
A crankshaft 21 shown by dashed lines has a flywheel 22 at the bottom. A drive shaft 23 linked to the bottom end of the crankshaft 21 passes through the under cover 13 and the extension cover 14 and links to a power transmission mechanism 24 inside the gear case 15.
The power transmission mechanism 24 transmits drive force from the drive shaft 23 to a horizontal driven shaft 25 oriented rearward from the front. The driven shaft 25 protrudes rearward out of the gear case 15, and a propeller 26 is secured to the rear end. By switching with a pair of dog clutches, the propeller can be switched between forward rotation and reverse rotation, resulting in forward and rearward propulsion force.
The engine cover 12 is attached to the under cover 13 by a hinge 27 on the rear side and a stopper 28 on the front side.
The engine 11 includes a cylinder head cover 31 provided at the rear, a cylinder head 32 and cylinder block 33 provided in the middle, and a crankcase 34 provided in the front, as shown in
The cylinder head 32 has a fuel chamber 35. The cylinder block 33 has a plurality of cylinders 36, and pistons 37 are slidably provided inside the cylinders 36. The crankshaft 21 is rotatably connected to the pistons 37 via connecting rods 38. The reference numeral 41 denotes an air intake valve, 42 denotes an exhaust valve, and 43 denotes an ignition plug.
An oil pan 45 is disposed at the bottom of a crank chamber 44 formed inside the crankcase 34, and the structure allows oil in the crank chamber 44 to flow down into the oil pan 45.
A mount case 46 is disposed at the bottom of the engine 11 and is used to support the engine 11. The oil pan 45 is provided in an oil case formed on the bottom surface of the mount case 46.
The crankshaft 21 is rotatably supported by a bearing 47. A power generator 51 and a recoil starter 52 are connected to the top end of the crankshaft 21.
A camshaft 53 is rotatably supported by a bearing 54 in the cylinder head 32. An oil pump 55 is connected to the bottom end of the camshaft 53 and is actuated by the rotational force of the camshaft 53.
A first oil passage (gallery) 56 is disposed in proximity to the cylinder block 33.
When the engine 11 is operating, the oil in the oil pan 45 is pumped up by the oil pump 55 and filtered by an oil filter 57, and the oil then flows through the vertically extending first oil passage 56. When the engine 11 stops, the oil pump 55 also stops and oil remains in the first oil passage 56.
The oil passage will be described referring back to
The oil passage includes a first oil passage 56, a second oil passage 65, and a pumping oil passage 61 for pumping up oil from the oil pan. The oil filter 57 is provided between the first oil passage 56 and the pumping oil passage 61.
The oil pump 55 is provided in the path of the pumping oil passage 61. Oil in the oil pan 45 is pumped up from a strainer 58 held in the oil pan 45 and is pumped up by the oil pump 55 via the oil passage 61. The pumped oil is fed to and filtered by the oil filter 57 provided on the side surface of the cylinder block 33. The filtered oil is diverted and fed to the first oil passage 56 and the second oil passage 65 which diverges from the first oil passage.
The oil in the first oil passage 56 is supplied to the bearing 47 of the crankshaft 21, which is an engine component that requires the oil. The oil fed to the second oil passage 65 diverging from the first oil passage 56 is supplied via a spool valve 64 to the bearing 54 of the camshaft 53, which is another component of the engine.
The oil sent out from the oil pump 55 (
A communication duct 67 for joining the main gallery 56 to the crank chamber 44 via a through-hole 66 is provided at a position lower than the oil filter 57. The communication duct 67 is closed by a drain valve 68 that can be opened and closed manually.
Furthermore, an air inlet duct 71 that allows air to enter from the exterior is provided to the first oil passage 56 at a position higher than the oil filter 57. The air inlet duct 71 is closed by an air vent bolt 72 that can be opened and closed manually.
According to
Referring to
Next, the operation for removing the oil that has accumulated in the first oil passage 56 will be described based on
The oil in the first oil passage 56 accumulates up to a position higher than the position of the oil filter 57, as shown in
A gap is then formed between the drain valve 68 and the communication duct 67 as shown in
When the drain valve 68 is closed after the operation of replacing the oil filter 57 has ended, the threaded part formed on the small-sectional-area part 77 engages with a threaded part 79 of the communication duct 67, and the drain valve 68 can therefore be closed in a simple manner even through the distal end of the drain valve 68 is not visible. When the drain valve 68 is opened, the small-sectional-area part 77 may be removed from the communication duct 67.
In
The drain valve 68 and the air vent bolt 72 are closed back up and a new oil filter 57 is attached as shown in
An example was presented in which the engine for an outboard motor according to the present invention was applied to a longitudinal engine in an embodiment, but the engine can also be applied to a so-called transverse engine, and the engine may be applied to other engines for outboard motors as long as the oil filter is installed in a midway position in the oil passage.
Obviously, various minor changes and modifications of the present invention are possible in light of the above teaching. It is therefore to be understood that within the scope of the appended claims the invention may be practiced otherwise than as specifically described.
Number | Date | Country | Kind |
---|---|---|---|
P2009-099140 | Apr 2009 | JP | national |
Number | Name | Date | Kind |
---|---|---|---|
4101000 | Scully | Jul 1978 | A |
6129058 | Muth | Oct 2000 | A |
6960296 | Morita | Nov 2005 | B2 |
7086915 | Hikosaka et al. | Aug 2006 | B2 |
Number | Date | Country |
---|---|---|
08-068335 | Mar 1996 | JP |
2000-110537 | Apr 2000 | JP |
2005-343226 | Dec 2005 | JP |
Entry |
---|
Notification of Reasons for Refusal mailed Oct. 2, 2012, (Patent Application No. P2008-080263) with Partial English Translation. |
Number | Date | Country | |
---|---|---|---|
20100267298 A1 | Oct 2010 | US |