1. Field of the Invention
The present invention relates to a dry-sump lubrication type four-stroke cycle engine suitable for a vehicle, such as a straddle type all-terrain four-wheel vehicle or a motorcycle, and, more specifically to improvements in an oil holding and circulating system.
2. Description of the Related Art
A conventional dry-sump lubrication four-stroke cycle engine usually has an oil tank separated from a crankcase of the engine, an oil feed pump and an oil return pump (scavenging pump). The oil tank holds a predetermined quantity of an engine oil. The oil feed pump pumps up the oil from the oil tank and feeds the oil by pressure to parts needing lubrication of the engine, and the oil return pump pumps up the used oil collected in the bottom of the crankcase or an oil pan and returns the used oil into the oil tank.
This dry-sump lubrication system increases the weight, component parts and cost of the engine, and needs pipes for connecting the crankcase and the oil tank.
A dry-sump lubrication type four-stroke cycle engine previously proposed by the assignee of the present patent application in JP-A No. 288466/1994 or JP-A No. 135419/1996 is not provided with any external oil tank and has a transmission chamber formed in a rear part of a crankcase of the engine and capable of holding a predetermined quantity of the engine oil. In this previously proposed dry-sump lubrication type four-stroke cycle engine, a suction port of a scavenging pump opens into an interior of a crank chamber of the crankcase, the scavenging pump sucks up the oil collected in the crank chamber and returns the oil into the transmission chamber to maintain the interior of the crank chamber in a dry state.
An engine disclosed in JP-A No. 215411/1986 is provided with a crankcase having a crank chamber and a transmission chamber. A lower part of the transmission chamber is used as an oil chamber. The crank chamber and the transmission chamber are separated by a partition wall, and the engine oil is contained in the oil chamber in the lower part of the transmission chamber. Right and left cover chambers provided at both sides of the crankcase are connected by an oil passage. The oil is allowed to flow from the crank chamber into the cover chambers, and a scavenging pump sucks the oil from the cover chambers and discharges the oil into the oil chamber.
The engine disclosed in JP-A No. 288466/1994 or JP-A No. 135419/1996, which sucks the oil directly from the crank chamber by the scavenging pump has the following problems.
(1) The pressure in the crank chamber varies repeatedly according to the variation of the volume of the crank chamber due to the reciprocation of the piston. Since the scavenging pump sucks the oil directly from the crank chamber, the suction of the scavenging pump is affected by the pressure variation in the crank chamber, the suction rate of the scavenging pump varies and the pumping ability of the scavenging pump cannot be fully utilized.
(2) Crank arms of the rotating crankshaft contained in the crank chamber agitate and splash the oil collected in the bottom of the crank chamber. The oil exerts resistance against the revolution of the crank arms and produces agitation loss.
(3) The oil flows in the reverse direction into the crank chamber gradually while the engine is stopped for a long time.
The engine disclosed in JP-A No. 215411/1986 has the following problems.
(1) Since the right and left cover chambers always communicate with each other, and a fixed quantity of oil is held always in the covers, a large quantity of oil flows into the crank chamber when the engine is tilted beyond a certain angle and hence it is possible that the crank chamber cannot be maintained in a dry state.
(2) Since the scavenging pump sucks the oil from the cover chambers and discharges the oil into the oil chamber, air cannot be satisfactorily removed from the oil and the oil containing air is returned to the oil chamber, which causes aeration in an oil feed pump.
The present invention has been made in view of the foregoing problems and it is therefore an object of the present invention to provide a compact dry-sump lubrication type four-stroke cycle engine provided with a lightweight lubricating system comprising a small number of component parts, being capable of efficiently using an oil pump and having an increased oil reverse capacity and simple oil passages formed in the crankcase.
According to one aspect of the present invention, a dry-sump lubrication type four-stroke cycle engine comprises: a crankcase in which a crank chamber is formed in its front part and a transmission chamber is formed in its rear part, the crankcase having a pair of end walls positioned at one end and other end along a crank axis direction, respectively; a first cover and a second cover disposed on the end walls of the crankcase, respectively; and a first chamber and a second chamber formed in the first cover and the second cover, respectively, wherein a partition wall of a given height is provided between the crank chamber and the transmission chamber so as to form an oil reservoir chamber in a lower part of the transmission chamber separated from the crank chamber by the partition wall, wherein one of the end walls is provided with a drain passage through which oil drains from the crank chamber into the first chamber, wherein the second chamber has a second oil reservoir chamber which communicates with the oil reservoir chamber so that a level of oil contained in the second oil reservoir chamber is equal to a level of oil in the oil reservoir chamber, and wherein the engine further comprising a scavenging pump pumping up oil from the first chamber and discharges oil into the oil reservoir chamber or the second oil reservoir chamber.
Since the oil reservoir chamber is formed in the crankcase, the dry-sump lubrication type four-stroke cycle engine of the present invention needs parts necessary for defining the oil reservoir chamber less than those necessary for forming the external oil tank of the conventional dry-sump lubrication type four-stroke cycle engine, and has weight less than that of the conventional dry-sump lubrication type four-stroke cycle engine, does not need any space for the external oil tank and external pipings for the oil tank. Thus, the dry-sump lubrication type four-stroke cycle engine of the present invention is compact and can be manufactured at a low cost.
Since the dry-sump lubrication type four-stroke cycle engine of the present invention uses the second chamber as the second oil reservoir chamber, the quantity of the oil that can be reserved in the engine can be increased without enlarging the crankcase.
Since the scavenging pump sucks the oil from the first chamber instead of sucking the oil directly from the crank chamber, the pumping effect of the scavenging pump is not affected by the pressure variation in the crank chamber, the scavenging pump is able to suck and discharge the oil stably, and the scavenging pump is able to suck an increased quantity of the oil and to return the oil surely from the crank chamber into the oil reservoir chamber.
Since the oil flows from the crank chamber into the first chamber, and the scavenging pump sucks the oil contained in the first chamber, crank arms of a crank shaft in the crank chamber do not splash the oil in the crank chamber and hence the oil does not cause any agitation loss.
Preferably, the first and the second chamber may be connected by an oil passage. The scavenging pump may be disposed in the second chamber, and a suction port of the scavenging pump may be connected to one end of the oil passage to suck oil directly from the first chamber.
The scavenging pump can be disposed compactly by using a space in the second chamber and the scavenging pump needs simple piping. Since the first chamber communicating with the crank chamber by means of the drain passage is kept in a dry state by the scavenging pump, the oil can hardly reverse from the first chamber into the crank chamber even if the engine tilts during operation, and the reduction of power transmission efficiency due to power loss caused by the resistance of the oil contained in the crank chamber against the revolution of the crank arms can be prevented.
Preferably, the oil passage may be formed below the drain passage connecting the crank chamber to the first chamber so as to extend under the crank chamber across the crankcase.
Such an arrangement of the drain passage and the oil passage enhances the effect of preventing the reverse flow of the oil and prevents deteriorating the dry state of the crank chamber, and enables effectively using the lower space of the crank chamber as the oil passage.
Preferably, the oil passage is formed integrally with the crankcase.
Thus, piping associated with the scavenging pump can be formed by a small number of parts.
Preferably, the scavenging pump is placed in the second chamber so as to position a rotor thereof below a predetermined oil level in the second oil reservoir chamber.
Preferably, the scavenging pump placed in the second chamber is sealed so that oil is unable to flow in a reverse direction from the second chamber.
Thus, the reverse flow of the oil from the second chamber can be prevented even if the engine is stopped for a long time, the oil can be held at a fixed level in the second chamber, which enables accurate measurement of the oil level.
Preferably, the scavenging pump may have a discharge opening at a level above a level of oil in the second chamber to discharge oil into air.
Thus, gases contained in the oil sucked by the scavenging pump can be separated from the oil, and only the oil can be pumped into the second oil reservoir chamber in the second chamber.
Preferably, a flat filter may be placed in the oil passage.
Thus, any extra space for the filter is not necessary, and the flat filter can be easily placed in and removed from the oil passage.
Preferably, a generator of the engine is placed in the first chamber communicating with the crank chamber, and a clutch of the engine is placed in the second chamber communicating with the oil reservoir chamber.
A dead space under the clutch can be effectively used for accommodating the scavenging pump.
Preferably, the clutch may be placed in the second chamber so that the clutch is not immersed in oil.
Thus, the oil does not exert any resistance on the clutch when the clutch rotates, which prevents the reduction of power transmission efficiency.
Preferably, transmission gears of a transmission installed in the transmission chamber are disposed so that the transmission gears are not immersed in oil contained in the oil reservoir chamber, and an oil spraying unit is placed in the transmission chamber to spray oil on the transmission gears.
Thus, the lower part of the transmission chamber can be effectively used as the oil reservoir chamber, the transmission gears can be properly lubricated, the transmission gears do not agitate the oil, and hence the reduction of power transmission efficiency due to agitation loss can be prevented.
The above and other objects, features and advantages of the present invention will become more apparent from the following description taken in connection with the accompanying drawings, in which:
[Straddle Type All-terrain Four-wheel Vehicle]
Referring to
The engine 7 is built by stacking and fastening together a cylinder 21, a cylinder head 22 and a cylinder head cover 23 in that order on a crankcase 20. An exhaust pipe 24 is connected to an exhaust port formed in a front part of the cylinder head 22. The exhaust pipe 24 is bent to the right and is extended rearward. A muffler 25 is connected to the rear end of the exhaust pipe 24. An intake pipe 26 is connected to an intake port formed in a rear part of the cylinder head 21. A carburetor 27, an intake duct 28 and an air cleaner 30 provided with an air cleaner element 29 are connected to the intake pipe 26.
The vehicle is provided with a chain-drive mechanism including a drive sprocket 31 mounted on the output shaft of the engine 7, a driven sprocket 33 mounted on a rear axle 32, and a drive chain 34 extended between the drive sprocket 31 and the driven sprocket 33. The rear wheels 5 are driven through the chain-drive mechanism by the engine 7. In
[Engine]
A right crankcase cover 57 and a left crankcase cover 56 are fastened to the right end wall 54 and the left end wall 53, respectively, of the crankcase 20. A generator 60 is placed in a left end chamber 58 covered with the left crankcase cover 56. A multiple-disk clutch 61 is placed in the right end chamber 59 covered with the right crankcase cover 57.
In the following description, the left crankcase cover 56 and the left end chamber 58 will be referred to as a generator cover 56 and a generator chamber 58, respectively, and the right crankcase cover 57 and the right end chamber 59 will be referred to as a clutch cover 57 and a clutch chamber 59, respectively.
[Power Transmission System]
The crankshaft 41 is supported for rotation in bearings 65 on the right end wall 54 and the left end wall 53 of the crankcase 20. The crankshaft 41 is formed by connecting right and left shaft members by a crank pin 37. The crankshaft 41 has a left end part projecting into the generator chamber 58. A crankshaft sprocket 68, a starter gear 84 and a rotor 70 included in the generator 60 are mounted on the left end part of the crankshaft 41. The rotor 70 of the generator 60 serves also as a flywheel. A camshaft sprocket 72 is mounted on a camshaft 48 in a cylinder head cover 23. A timing chain 71 is extended through a timing chain tunnel 62 formed in a cylinder 21 and a cylinder head 22 between the crankshaft sprocket 68 and the camshaft sprocket 72.
The crankshaft 41 has a right end part projecting into the clutch chamber 59. A crankshaft gear 82 and a balancer drive gear 83 are fixedly mounted on the right end part of the crankshaft 41. The crankshaft gear 82 is engaged with a clutch gear 81 included in the multiple-disk clutch 61.
The transmission M has five forward speeds and reverse. A transmission input shaft 42 is supported in bearings 73 on the end walls 53 and 54 of the crankcase 20. Input forward-speed gears 85, namely, input 1st-speed, input 5th-speed, input 3rd-speed, input 2nd-speed and input 4th-speed gears 85, are arranged in that order from the right toward the left on the transmission input shaft 42. An input reverse gear 86 is mounted on a left end part of the transmission input shaft 42. The transmission input shaft 42 has a right end part projecting into the clutch chamber 59, and a hub included in the multiple-disk clutch 61 is mounted on the right end part of the transmission input shaft 42.
A transmission output shaft 43 is supported in bearings 74 on the end walls 53 and 54. The transmission output shaft 43 has a left end part projecting from the transmission chamber 52, and a drive sprocket 31 for driving the rear wheels is fixedly mounted on the left end part of the transmission output shaft 43. Output forward-speed gears 87, namely, output 1st-speed, output 5th-speed, output 3rd-speed, output 2nd-speed and output 4th-speed gears 87, are arranged in that order from the right toward the left on the transmission output shaft 43. An output reverse gear 88 is mounted on a left end part of the transmission output shaft 43. The output forward-speed gears 87 are engaged with the input forward-speed gears 85, respectively, and the output reverse gear 88 is engaged with a reverse idle gear 90 mounted on a reverse idle shaft 44 and engaged with the input reverse gear 86 as shown in
Referring to
A balancer shaft 50 is disposed in front of the crankshaft 41. A balancer gear 91 mounted on the balancer shaft 50 is engaged with the balancer drive gear 83 mounted on the crankshaft 41. A large starting intermediate gear 93 and a small starting intermediate gear 94 are mounted on a shaft disposed above the transmission input shaft 42. A starter motor 95 is disposed above the starting intermediate gears 93 and 94. The large starting intermediate gear 93 is engaged with a pinion 96 mounted on the output shaft of the starter motor 95, and the small starting intermediate gear 94 is engaged with a starting idle gear 97 disposed in front of the small starting intermediate gear 94 and engaged with a starting gear 84 mounted on the crankshaft 41.
Referring to
The large starting intermediate gear 93, the small starting intermediate gear 94 and the starting idle gear 97 of the starting mechanism are disposed in an upper part of the generator chamber 58, and the starter motor is attached to the upper wall of the crankcase 20.
[Lubrication System]
Referring to
The transmission input shaft 42 and the transmission output shaft 43 are provided with oil passages 118 and 119, respectively. The oil passages 118 and 119 are connected to an oil chamber 120 formed in the left end wall 53 of the crankcase 20, and are opened in parts, on which the gears 85, 86, 87 and 88 are mounted, of the input shaft 42 and the output shaft 43. The cylinder head cover 23 is provided with an oil passage 121 for carrying oil to lubricate the sliding parts of the camshaft 48.
Referring to
[Oil Holding Structure in Crankcase]
The respective axes O2, O3 and O4 of the transmission input shaft 42, the transmission output shaft and the reverse idle shaft 44 are on levels above that of the axis O1 of the crankshaft 41 such that the lower ends of the transmission gears 85, 87 and 90 mounted on the shafts 42, 43 and 44 are substantially above an oil level L1 of the oil contained in the oil reservoir chamber 64 and the transmission gears 85, 87 and 90 are scarcely immersed in the oil contained in the oil reservoir chamber 64. The oil level L1 is the predetermined oil level of the maximum quantity of oil stored in the oil reservoir chamber 64. Thus, the oil does not exert resistance against the rotation of the transmission gears 85, 87 and 90 and hence the reduction of power transmission efficiency due to the resistance of the agitated oil can be prevented.
Referring to
Referring to
The left end wall 53 of the crankcase 20 defining the left end of the crank chamber 51 is provided with three drain passages 125 opening into the bottom of the crank chamber 51 and the generator chamber 58. The openings opening into the generator chamber 58 of the drain passages 125 are at a height D from a bottom wall 58a defining the bottom of the generator chamber 58. Thus, oil is able to drain away from the crank chamber 51 through the drain passages 125 into the generator chamber 58 and is unable to flow from the generator chamber 58 into the crank chamber 51.
A first oil passage 130 and a second oil passage 131 are formed in the crankcase 20 in parallel to the axis O1 of the crankshaft 41 under the bottom wall 102 defining the bottom of the crank chamber 51. The first oil passage 130 has a left end opening into the generator chamber 58 and a closed right end. The second oil passage 131 has a closed left end and a right end opening into the clutch chamber 59 at a level below the oil level L1. The oil passages 130 and 131 are separated by a partition wall 133. A flat third filter 135 is fitted in an opening formed in a right part of the partition wall 133, so that the oil passages 130 and 131 communicate with each other by means of the opening provided with the third filter 135. Thus, the generator chamber 58 on the left side and the clutch chamber 59 on the right side communicate with each other by means of the flat third filter 135 and the oil passages 130 and 131. The left open end 130a of the first oil passage 130 is positioned below the drain passages 125 opening into the crank chamber 51 by a distance corresponding to the height D. and is at the level of the inner surface of the bottom wall 58a defining the bottom of the generator chamber 58. Thus, oil flowed from the crank chamber 51 into the generator chamber 58 is drained quickly through the first oil passage 130.
As shown in
Referring to
Referring to
[Oil Feed Pump and Scavenging Pump]
Referring to
The clutch cover 57, a pump housing 151 and a pump cover 153 form the casing of the pumps 106 and 107. The pump housing 151 is fastened to the inner surface of the clutch cover 57, and the pump cover 153 is fastened to the left end surface of the pump housing 151. An O ring 152 is held between the pump housing 151 and the pump cover 153. The rotor 106a of the oil feed pump 106 is placed in a rotor chamber 106b formed in the clutch cover 57. The rotor 107a of the scavenging pump 107 is placed in a rotor chamber 107b formed in the pump housing 151. The respective rotors 106a and 107a of the pumps 106 and 107 are fixedly mounted on the same rotor shaft 155. The common rotor shaft 155 is supported on the pump housing 151 and the pump cover 153, is extended through the pump cover 153 so as to project into the clutch chamber 59. A pump gear 156 is fixedly mounted on the projecting part and is engaged with the crankshaft gear 82 of the crankshaft 41.
[Scavenging Pump]
Referring to
To prevent the flow of oil from the clutch chamber 59 into the scavenging pump 107, oil seals 170 and 171 are provided, on the opposite sides of the rotor 107a of the scavenging pump 107, between the rotor shaft 155 and insertion holes of the rotor shaft 155 formed in the pump cover 153 and the pump housing 151, in addition to the O rings 152 and 161 sealing the joint of the pump housing 151 and the pump cover 153 and the joint of the pump cover 153 and the crankcase 20.
[Oil Feed Pump]
Referring to
A relief valve 200 is placed in a suction chamber 175 formed in the oil feed pump 106. The relief valve 200 opens after the discharge pressure of the oil feed pump 106 has increased beyond a set pressure to return part of oil from a discharge chamber 173 through an oil return passage 206 and the relief valve 200 into the suction chamber 175.
The relief valve 200 includes a valve case 201 having the shape of a cylinder with a bottom wall, a cylindrical plunger 202 axially slidably fitted in the valve case 201, and a valve spring 203 pushing the plunger 202 in a valve-closing direction. The valve case 201 is fixed to the pump housing 151 so as to extend laterally across the oil chamber 175. The valve case 201 is provided in its side wall with oil return holes 205 arranged at angular intervals and opening into the oil chamber 175. The right end surface (pressure-receiving surface) of the plunger 202 is exposed through an opening 201a formed in the right end wall (the bottom wall) of the valve case 201 to the oil return passage 206. Normally, the plunger 302 is biased to the right by the valve spring 203 so that the oil return holes 205 are closed. As the discharge pressure of the oil feed pump 106 increases beyond the set pressure, the plunger 202 is shifted to the left against the resilient force of the valve spring 203 and the oil return holes 205 are opened to return part of oil into the oil chamber 175 on the suction side. Although the relief valve 200 appears to be blocking the oil chamber 175 in
The discharge part 173 of the oil feed pump 106 is connected to an oil feed passage 210 formed in the clutch cover 57, the oil feed passage 210 has an opening that opens into the clutch chamber 59, and an oil feed pipe 212 is connected to the opening of the oil feed passage 210 by a connector 213.
[Oil Feed Circuit]
An oil feed passage 220 extends forward from an outlet 115a of the second filter 115, and a crankshaft lubricating oil feed passage 110 extends downward from the outlet 115a of the second filter 115. As shown in
Referring to
The oil feed pipe 240 extends upward through the timing chain tunnel 62 and is connected to an oil inlet port 243 formed in the cylinder head 22. As shown in
[Operations]
[Oil Feed from Oil Feed Pump to Parts Needing Lubrication]
The oil feed operation of the oil feed pump 106 will be briefly described with reference
Referring to
[Other Parts Needing Lubrication]
Referring to
[Return Flow of Oil]
Referring to
Referring to
Thus, the oil collected in the bottom of the crank chamber 51 flows through the oil drain passages 125 into the generator chamber 58, and then scavenging pump 107 sucks the oil from the generator chamber 58 and returns the oil to the clutch chamber 59. Therefore, the suction of the scavenging pump 107 is not affected by the variation of pressure in the crank chamber 51, the revolving crank arms 49 do not splash oil, and hence the ability of the scavenging pump 107 can be fully utilized. Therefore, the scavenging pump 107 is able to pump oil at a necessary pumping rate even if the same does not have a large pumping capacity.
Referring to
Even when the engine is stopped for a long time, oil does not flow in the reverse direction from the oil reservoir chamber 64 and the clutch chamber 59 through the scavenging pump 107 into the generator chamber 58 and the crank chamber 51 because the gaps around the scavenging pump 107 are sealed by the oil seals 170 and 171 and O rings 152 and 161. Thus, the crank chamber 51 can be maintained in a dry state, and oil levels in the clutch chamber 59 and the oil reservoir chamber 64 can be held constant. Therefore, the quantity of oil contained in the oil reservoir chamber 64 can be accurately measured even after the engine has been kept stopped for a long time. Since the scavenging pump 107 keeps the generator chamber 58 in a dry state in principle while the engine is in operation and the oil passages 130 and 131 are at levels below that of the drain passages 125, oil will not flow in the reverse direction into the crank chamber 51.
[Modifications]
Oil may be drained from the crank chamber into the clutch chamber, and the oil contained in the clutch chamber may be pumped by the scavenging pump into the oil reservoir chamber.
Although the invention has been described in its preferred embodiments with a certain degree of particularity, obviously various changes and variations are possible therein. It is therefore to be understood that the present invention may be practiced otherwise than as specifically described herein without departing from the scope and spirit thereof.
Number | Name | Date | Kind |
---|---|---|---|
4674457 | Berger et al. | Jun 1987 | A |
4915070 | Okui | Apr 1990 | A |
6205987 | Shigedomi et al. | Mar 2001 | B1 |
6823829 | Kawamoto et al. | Nov 2004 | B1 |
20020053489 | Schnitzer | May 2002 | A1 |
20030101959 | Hare | Jun 2003 | A1 |
Number | Date | Country |
---|---|---|
A 61-215411 | Sep 1986 | JP |
01-169171 | Jul 1989 | JP |
04-292514 | Oct 1992 | JP |
06-248927 | Sep 1994 | JP |
A 6-288466 | Oct 1994 | JP |
A 8-135419 | May 1996 | JP |
11-148309 | Jun 1999 | JP |
2002-040409 | Feb 2002 | JP |
Number | Date | Country | |
---|---|---|---|
20040245050 A1 | Dec 2004 | US |