The present invention relates to a lubrication system for a portable four-stroke engine and, in particular, to a lubrication system for a portable four-stroke engine in which no reduction in lubrication performance within the engine occurs even when the attitude of the engine is variously changed during use.
Two-stroke engines are conventionally used as the driving engines of portable power tools, such as portable trimmers for trees and plants and backpack power tools, carried by the operators themselves or on the backs of the operators. However, for example, as awareness of environmental issues grows and emission regulations become more stringent, there is an increasing need for replacement of two-stroke engines used as driving sources with four-stroke engines.
However, the numbers of required components of four-stroke engines are greater than those of two-stroke engines, and therefore the weights of the four-stroke engines tend to be greater than those of the two-stroke engines. A portable power tool, in particular, is used on the premise that the operator carries the tool during operation, and therefore there is a demand for a weight reduction of the engine.
Patent Document 1 proposes a lubrication system for a four-stroke engine. In this lubrication system, a pump for lubrication is not separately provided, and pressure changes in a crank chamber are utilized to circulate oil. In this lubrication system, a negative pressure created in the crank chamber is utilized to supply oil mist generated in an oil tank to the crank chamber through a first oil passage that is drilled in a crankshaft and communicates the oil tank with the crank chamber, and the crankshaft and components therearound are thereby lubricated. The floating oil mist generated in the oil tank is delivered, by utilizing a positive pressure created in the crank chamber, to a power transmission mechanism (including an intake valve and an exhaust valve) in a first valve-operating chamber and a cam mechanism in a second valve-operating chamber, which are disposed above the oil tank when the engine is upright, and these driving components are thereby lubricated.
A partition plate is disposed inside a head cover that forms the second valve-operating chamber. The partition plate partitions the space inside the head cover into an upper section serving as a breather chamber and a lower section serving as the second valve-operating chamber. The breather chamber is in communication with the second valve-operating chamber through a communication part that opens into the second valve-operating chamber. A box-shaped partition member is welded to the partition plate, and an oil collection chamber is formed between the partition plate and the partition member. Suction tubes extending toward the power transmission mechanism in the second valve-operating chamber are provided in the partition plate, and suction tubes extending toward the ceiling surface of the head cover are provided in the partition member. A conduit tube that is in communication with the oil collection chamber and protrudes toward the second valve-operating chamber is provided in the partition plate. The conduit tube is in communication with the crank chamber.
In this lubrication system, when a negative pressure is created in the crank chamber as the crankshaft rotates, a negative pressure is also formed in the oil collection chamber through the conduit tube. Therefore, the oil accumulated in the second valve-operating chamber or the breather chamber is sucked through the suction tubes and returned to the crank chamber.
The oil collection chamber in the conventional lubrication system is formed by attaching the box-shaped partition member to the partition plate provided in the head cover and has a bent shape that is bent to avoid the power transmission mechanism (including the intake valve and the exhaust valve) provided in the second valve-operating chamber. Therefore, the oil collection chamber has a complicated structure, and there is the problem in which this structure is not a simple structure suitable for production purposes.
The present invention has been made in view of the above circumstances, and it is an object of the invention to provide a lubrication system for a portable four-stroke engine, the lubrication system including a passage for collecting oil accumulated in a valve-operating chamber. The passage for collecting oil provides sufficient oil collection efficiency and has a simple structure suitable for production purposes.
To solve the foregoing problem, a first aspect of the present invention provides a lubrication system for a portable four-stroke engine. The lubrication system is configured to lubricate components in a valve-operating chamber and in a crank chamber with oil (such as lubricating oil A in an embodiment) by supplying the oil by utilizing changes in pressure inside the crank chamber caused by reciprocating movement of a piston while circulating the oil, the valve-operating chamber accommodating intake and exhaust valve mechanisms therein. In addition, lubrication system is configured to discharge blow-by gas in an oil circulation path from the valve-operating chamber to a combustion chamber through a breather passage connected to the valve-operating chamber. In the lubrication system, an opening end of the breather passage on a side of the valve-operating chamber is disposed at substantially a center of the valve-operating chamber, and the valve-operating chamber is formed by attaching a valve-operating chamber cover. The valve-operating chamber cover has a top plate portion and a side plate portion disposed along a circumferential edge of the top plate portion so as to be formed in a cap shape. An inner cover is attached to an inner surface of the valve-operating chamber cover so as to be provided along and in contact with the inner surface of the valve-operating chamber cover. A suction passage is formed as a gap between the circumferential edge of the top plate portion and the inner cover, the gap being formed by attaching the inner cover to the valve-operating chamber cover. Three or more suction tubes that are in communication with the suction passage are provided in the inner cover, each of the suction tubes extending to the vicinity of an end surface of the valve-operating chamber which faces the top plate portion, each of the suction tubes having an opening end that is disposed in the vicinity of the end surface. A direct passage (such as a passage including a cover-side direct passage 47 and a block-side direct passage 48 in the embodiment) is provided which communicates the suction passage with the crank chamber when a negative pressure is created in the crank chamber. At least one of the opening ends of the three or more suction tubes is provided lower than the opening end of the breather passage in an attitude of the four-stroke engine during use.
The valve-operating chamber cover covers the valve mechanisms and forms a space that can receive blow-by gas and oil mist supplied from the crank chamber. The inner cover has a shape that conforms to the inner surface of the valve-operating chamber cover and is attached to the inner surface of the valve-operating chamber cover so as to be in contact therewith. When the inner cover is attached to the valve-operating chamber cover, the suction passage is formed as the gap between the inner cover and the circumferential edge of the top plate portion of the valve-operating chamber. More specifically, the valve-operating chamber cover includes the top plate portion that forms a top portion and the side plate portion connected to the circumferential edge of the top plate portion to be formed into a cap shape. The valve-operating chamber cover is configured such that, when the inner cover is attached inside the valve-operating chamber cover, the suction passage is formed as the gap between the connection portion of the top plate portion to the side plate portion and a portion of the inner cover that faces the connection portion.
In the present invention, oil is circulated by utilizing changes in pressure inside the crank chamber caused by the reciprocating movement of the piston. The crank chamber serving as a pressure source for oil circulation and the valve-operating chamber are connected through the direct passage. The direct passage communicates the valve-operating chamber with the crank chamber when a negative pressure is created in the crank chamber. Therefore, even when oil mist is liquefied in the valve-operating chamber and a large amount of the liquefied oil stays therein, the oil can be instantaneously delivered to the crank chamber by the strong negative pressure, so that the accumulation of the oil in the valve-operating chamber can be sufficiently suppressed.
In a second aspect, a gap in communication with the suction passage is formed between the valve-operating chamber cover and the inner cover and forms a part of the direct passage (for example, a cover-side direct passage 47 in the embodiment). More specifically, the gap is formed between the side plate portion of the valve-operating chamber cover and the side plate portion of the inner cover. The gap communicates with the suction passage and forms a part of the direct passage.
The three or more suction tubes are disposed such that at least one of the opening ends of the suction tubes can be immersed in the oil accumulated in the valve-operating chamber in an operating attitude of the portable four-stroke engine.
More specifically, in a third aspect, two of the three or more suction tubes are disposed in the valve-operating chamber and located at positions near opposite widthwise ends of a first side of the valve-operating chamber near a working unit which receives power from a crankshaft during operation. At least one of the three or more suction tubes is disposed in the valve-operating chamber and located at a position near a second side of the valve-operating chamber, the second side being opposite to the first side near the working unit.
By disposing two suction tubes at positions near the opposite widthwise ends of the first side of the valve-operating chamber near the working unit, the oil accumulated in the valve-operating chamber can be effectively sucked even in a power tool, such as a trimmer, that is operated with its working unit tilted downward during normal operation. By disposing at least one suction tube at a position near the second side of the valve-operating chamber that is opposite to the first side near the working unit, the oil accumulated in the valve-operating chamber can be effectively sucked even in a portable power tool, such as a trimmer, that is generally operated with its working unit tilted downward and also operated with the working unit tilted upward.
In a fourth aspect, small holes in communication with the suction passage are provided at positions near connection portions of the suction tubes provided in the inner cover to the inner cover. The positions near the connection portions of the suction tubes to the inner cover shall mean positions around the connection portions. More specifically, the small holes are formed in the top plate portion of the inner cover. Therefore, even when the four-stroke engine is used upside down, the oil accumulated in the valve-operating chamber is sucked through the small holes. In this manner, the oil accumulated in the valve-operating chamber can be effectively sucked even when the portable power tool is used in any attitude. Since the small holes are disposed near the connection portions of the suction tubes to the inner cover, the communication structure with the suction passage is suitable for production purposes.
In the lubrication system for a portable four-stroke engine according to the present invention, three or more suction tubes are provided which are in communication with the suction passage, extend to the vicinity of the end surface of the valve-operating chamber that faces the top plate portion, and have opening ends disposed in the vicinity of this end surface. In addition, the direct passage is provided which communicates the suction passage with the crank chamber when a negative pressure is created in the crank chamber. Therefore, oil can be sufficiently collected from the valve-operating chamber. Moreover, the accumulation of the oil in the valve-operating chamber can be suppressed. The inner cover is configured such that, when the inner cover is attached to the valve-operating chamber cover formed into a cap shape, the suction passage is formed as the gap between the inner cover and the circumferential edge of the top plate portion of the valve-operating chamber cover, and a plurality of suction tubes are provided in the inner cover. Therefore, when the inner cover and the valve-operating chamber cover which have simple structures suitable for production purposes are attached to each other, a passage for collecting oil from the valve-operating chamber can be easily formed. The opening end of the breather passage on the side of the valve-operating chamber is disposed at substantially the center of the valve-operating chamber, and at least one of the opening ends of the plurality of suction tubes is located lower than the opening end of the breather passage in the attitude of the four-stroke engine during use. Therefore, even when a certain amount of oil is accumulated in the valve-operating chamber, the oil is prevented from being easily released from the breather passage into the combustion chamber, and the oil consumption can thereby be reduced.
Hereinafter, preferred embodiments of a lubrication system for a portable four-stroke engine of the present invention will be described with reference to
The portable four-stroke engine 1 (hereinafter referred to simply as “engine 1”) includes a cylinder block 3 integrated with a cylinder head 3a, a crank case 5 that is attached to the lower portion of the cylinder block 3 and forms a crank chamber 5a, and an oil reservoir 7 disposed below the crank case 5, as shown in
As shown in
An intake port and an exhaust port that communicate with a carburetor (not shown) and an exhaust muffler (not shown), respectively, are provided in the upper wall of the cylinder 3b formed in the cylinder block 3, and an intake valve and an exhaust valve for opening and closing the intake and exhaust ports are disposed in these ports.
A valve operating unit 20 for driving these valves includes: a valve driving gear 21 that is secured to the crankshaft 9; a cam gear 22 driven by the valve driving gear 21; a cam 23 connected to one end of the cam gear 22; a pair of cam followers 25 that are oscillated by the cam 23 and rotatably supported on the cylinder block 3; a pair of rocker arms 27 that are supported on the rocker shaft 26 disposed on the head portion of the cylinder block 3 and abut against the valve heads of the intake and exhaust valves at first ends; a pair of push rods 28 that connect the cam followers 25 to the second ends of the rocker arms 27; and valve springs 29 that urge the intake and exhaust valves in the directions of closing the valves. The valve driving gear 21, the cam gear 22, and the cam 23 that constitute a part of the valve operating unit 20 are accommodated in a valve driving chamber 52 (see
An oil feed passage 54 is disposed between the oil reservoir 7 and the cylinder block 3, as shown in
When a negative pressure tends to be created in the crank chamber 5a as the piston 13 moves upward, the oil feed passage 54 allows the crank chamber 5a and the oil reservoir 7 to be in communication with each other so that the oil A is thereby sucked from the oil reservoir 7 and supplied to the crank chamber 5a through the oil feed passage 54. An opening end 54a of the oil feed passage 54 being opened in the crank chamber 5a is disposed so as to establish communication with the crank chamber 5a when the piston 13 moves from a position near a top dead center toward the top dead center. This opening end 54a is positioned on the bottom dead center side of a skirt 13a provided in the lower portion of the piston when the piston is moved to the position near the top dead center. Therefore, the opening end 54a of the oil feed passage 54 is already in a fully open state when the piston 13 reaches the top dead center.
The oil feed passage 54 may be allowed to be in communication with the crank chamber 5a, when a negative pressure is created in the crank chamber 5a, by providing a reed valve at the opening end 54a of the oil feed passage 54, or providing a passage in the crankshaft 9 so as to function as a rotary valve.
A one-way valve 57 is provided in the oil feed passage 54. The one-way valve 57 is configured so as to be opened and closed according to the change in pressure inside the crank chamber 5a. More specifically, the one-way valve 57 is opened to communicate the oil feed passage 54 with the crank chamber 5a when the pressure inside the crank chamber 5a is lower than the pressure inside the oil reservoir 7. The one-way valve 57 is closed when the pressure inside the crank chamber 5a is higher than the pressure inside the oil reservoir 7.
A communication passage 59 for communicating the crank chamber 5a with the oil reservoir 7 is provided between the bottom portion of the crank chamber 5a and the oil reservoir 7. The communication passage 59 is used to deliver oil mist generated in the crank chamber 5a and liquid oil formed by liquefaction of the oil mist to the oil reservoir 7. A reed valve 60 is provided at the opening end 59a of the communication passage 59 being opened to the crank chamber. The reed valve 60 is configured so as to be opened and closed according to the change in pressure inside the crank chamber 5a. More specifically, the reed valve 60 is opened by a positive pressure created inside the crank chamber when the piston 13 moves toward the bottom dead center, so that the communication passage 59 is allowed to communicate with the crank chamber. Therefore, when the reed valve 60 is opened to allow the communication passage 59 to be in communication with the crank chamber, the oil mist and oil in the crank chamber 5a is delivered to the oil reservoir 7 through the communication passage 59.
The communication passage 59 has an opening end 59b being opened to the oil reservoir 7 and disposed at substantially the center of the oil reservoir 7. Irrespective of the tilted state of the oil reservoir 7, the opening end 59b is located at a position above the surface of the oil A that is stored in the oil reservoir 7 in an amount equal to or less than the rated amount. Therefore, the oil mist ejected from the opening end 59b of the communication passage 59 is blown against the oil surface, and the oil is not bubbled. Accordingly, the oil mist is gently returned to the oil reservoir 7, and most of the oil mist is liquefied. However, part of the oil mist ejected from the opening end 59b bounces off the oil surface and the wall surfaces of the oil reservoir 7 and stays in a space 7a above the oil surface in the oil reservoir 7. As described above, the opening end 59b of the communication passage 59 that is disposed above the surface of the oil A functions as a part of liquefying means for liquefying oil mist.
Therefore, most of the oil mist ejected from the communication passage 59 is liquefied, so that the concentration of oil mist staying in the oil reservoir 7 can be reduced.
An opening end 51a of the supply passage 51 is opened to the oil reservoir 7 and disposed at substantially the center of the inner space of the oil reservoir 7. Irrespective of the tilted state of the oil reservoir 7, the position of the opening end 51a is always above the surface of the oil stored in the oil reservoir 7 in an amount equal to or less than the rated amount, even when the position of the oil surface is changed. Moreover, the opening end 51a is disposed such that the opening end 59b protrudes further than the opening end 51a.
As described above, the opening end 59b of the communication passage 59 and the opening end 51a of the supply passage 51 are disposed in the oil reservoir 7 such that the opening end 59b protrudes further than the opening end 51a. Therefore, the oil mist ejected from the opening end 59b of the communication passage 59 does not directly enter the opening end 51a of the supply passage 51. More specifically, the arrangement of the supply passage 51 and the communication passage 59 in the oil reservoir 7 functions as a flow blocking mechanism for preventing the oil mist ejected from the communication passage 59 from flowing directly into the opening end 51a of the supply passage 51. Therefore, the concentration of the oil mist flowing through the supply passage 51 is lower than the concentration of the oil supplied from the oil feed passage 54 to the crank chamber 5a.
An opening end 51b of the supply passage 51 is opened to the valve-operating chamber 30 so as to be in communication with the valve-operating chamber 30 on its cylinder block 3 side. Therefore, the oil mist flowing through the supply passage 51 lubricates a valve-operating mechanism 19 (including a valve driving gear 24 and the cam gear 22) in the valve driving chamber 52. The oil mist is then ejected from the opening end 51b and supplied to the valve-operating chamber 30, so as to lubricate the rocker arms and other components in the valve-operating chamber 30.
As shown in
The valve-operating chamber cover 31 includes a rectangular top plate portion 32 and a side plate portion 33 disposed along the circumferential edge of the top plate portion 32 and extending on the rear side of the top plate portion so as to be formed into a cap shape. The side plate portion 33 may extend from the top plate portion 32 so as to be substantially perpendicular thereto (see
A breather passage 36 is provided at substantially the center of the top plate portion 32 of the valve-operating chamber cover 31. The first end portion of the breather passage 36 extends from the top plate portion 32 to the inside of the valve-operating chamber cover 31. The breather passage 36 is configured such that its opening end 36a is located substantially at the center of the valve-operating chamber 30 when the valve-operating chamber cover 31 is fixed to the cylinder block 3 (see
As shown in
The side plate portion 43 of the inner cover 40 extends along the side plate portion 33 of the valve-operating chamber cover 31. Therefore, when the side plate portion 33 of the valve-operating chamber cover 31 extends substantially perpendicular to the top plate portion 32 of the valve-operating chamber cover 31, the side plate portion 43 of the inner cover 40 also extends substantially perpendicular to the top plate portion 42 of the inner cover 40. When the side plate portion 33 of the valve-operating chamber cover 31 extends from the top plate portion 32 of the valve-operating chamber cover 31 so as to be tilted outward, the side plate portion 43 of the inner cover 40 also extends from the top plate portion 42 of the inner cover 40 so as to be tilted outward.
A through hole 42a for allowing the breather passage 36 to be inserted thereinto is provided at substantially the center of the top plate portion 42 of the inner cover 40. The annular step portion 41 protruding outward from the circumferential edge of the opening end of the inner cover 40 is provided at the protruding end of the side plate portion 43 of the inner cover 40. When the valve-operating chamber cover 31 is fixed to the cylinder block 3 through the bolts 35 with the step portion 41 fitted into the recessed groove 33a of the valve-operating chamber cover 31, the inner cover 40, together with the valve-operating chamber cover 31, is fixed to the cylinder block 3 through the step portion 41.
As shown in
Three suction tubes 46 extending toward the opening edge of the inner cover 40 are provided in the inner cover 40. These suction tubes 46 protrude outward from an opening edge 40a of the inner cover 40, and opening ends 46b are formed at the protruding ends of the suction tubes 46. The base portions of the suction tubes 46 pass through the side plate portion 43 to form opening ends 46a (see
With reference to
When the inner cover 40 is attached to the valve-operating chamber cover 31, a space is formed between the inner cover 40 and the side plate portion 33 of the valve-operating chamber cover 31 so as to serve as a cover-side direct passage 47. In the attached state, the cover-side direct passage 47 is in communication with the suction passage 45. An opening end 47a of the direct passage 47 is substantially flush with the opening edge 40a of the inner cover 40 (see
In this configuration, the suction passage 45 in communication with the suction tubes 46 can be easily formed by simply attaching the inner cover 40 inside the valve-operating chamber cover 31.
As shown in
A one-way valve that allows a flow from the valve-operating chamber 30 toward the crank chamber 5a but prevents a flow from the crank chamber 5a toward the valve-operating chamber 30 may be provided in the block-side direct passage 48. In this manner, the back flow of oil and oil mist from the crank chamber 5a to the valve-operating chamber 30 can be reliably prevented.
The second end of the breather passage 36 is connected to an air cleaner 63. The breather passage 36 is provided to discharge blow-by gas into a combustion chamber. The oil mist and blow-by gas in the valve-operating chamber 30 are delivered to the air cleaner 63 through the breather passage 36, and oil and the blow-by gas are separated by an oil separator 63a provided in the air cleaner 63. As described above, the breather passage 36 at its first end is opened at substantially the center of the valve-operating chamber 30. Therefore, even when a large amount of oil stays in the valve-operating chamber 30, the oil is not easily sucked. A one-way valve 36b is provided in the breather passage 36, and the backflow of blow-by gas and oil mist from the air cleaner 63 toward the valve-operating chamber 30 is prevented by the one-way valve 36b.
The liquid oil separated from the gas component is delivered to the crank chamber 5a through a circulation passage 65 that communicates the air cleaner 63 with the crank chamber 5a. A one-way valve 65a that allows only a flow toward the crank chamber is disposed in the circulation passage 65. The blow-by gas separated from the liquid component is delivered to the combustion chamber together with intake air.
A return passage 66 for returning the oil in the valve driving chamber 52 to the crank chamber 5a is provided between the crank chamber 5a and the bottom portion of the valve driving chamber 52 on the oil reservoir side. When a negative pressure is created in the crank chamber 5a, the oil accumulated in the valve driving chamber 52 is sucked through the return passage 66. The return passage 66 is formed to have a cross-sectional area smaller than 1/10 of the cross-sectional area of the communication passage 59. When a positive pressure is created in the crank chamber 5a, the reed valve 60 is opened, and the crank chamber 5a and the oil reservoir 7 are thereby in communication with each other. The oil mist and oil in the crank chamber 5a flow through the communication passage 59 having a large cross-sectional area, and the return passage 66 is blocked with oil. Therefore, almost no oil flows back from the crank chamber 5a to the valve driving chamber 52. In the present embodiment, the inner diameter of the communication passage 59 is set to φ9 mm, and the inner diameter of the return passage 66 is set to φ2 mm.
The return passage 66 may be provided such that the valve driving chamber 52 and the block-side direct passage 48 are in communication with each other. By providing the return passage 66 in the manner described above, oil is not supplied more than necessary to the valve-operating chamber 30. A one-way valve that allows a flow toward the crank chamber but prevents a flow toward the valve driving chamber 52 may be provided in the return passage 66. In this manner, the backflow of oil from the crank chamber 5a to the valve driving chamber 52 can be reliably prevented.
A flow rate control passage 67 is provided between the valve driving chamber 52 and the oil feed passage 54. The air in the valve driving chamber 52 is sucked into the flow rate control passage 67, and the flow rate of oil supplied to the crank chamber 5a through the oil feed passage 54 is thereby controlled. When the amount of sucked air is large, the flow rate of oil supplied through the oil feed passage 54 is low. Preferably, the flow rate control passage 67 is disposed so as to be spaced apart from the bottom of the valve driving chamber 52 so that the oil staying in the valve driving chamber 52 is less likely to be sucked.
The flow rate control passage 67 is connected to the oil feed passage 54 at a position that is closer to the oil reservoir than the one-way valve 57 provided in the oil feed passage 54. Therefore, when the supply of oil is stopped by the one-way valve 57, the oil in the oil feed passage 54 is accumulated on the oil reservoir side of the one-way valve 57, and the oil is accumulated in the connection portion of the flow rate control passage 67 to the oil feed passage 54. Therefore, when air is sucked from the flow rate control passage 67 into the oil feed passage 54, only the air does not flow through the oil feed passage 54, but the oil in the oil feed passage 54 is delivered to the crank chamber 5a together with the air delivered from the valve driving chamber 52.
A flow restrictor 68 for controlling the flow rate of air delivered from the valve driving chamber 52 to the oil feed passage 54 is provided in the flow rate control passage 67. By controlling the flow restrictor 68 to adjust the amount of air sucked from the valve driving chamber 52, the flow rate of oil supplied to the crank chamber 5a through the oil feed passage 54 can be controlled. More specifically, the flow rate of oil can be easily controlled only by the design of the flow restrictor 68, irrespective of the inner diameter of the flow rate control passage 67.
The flow restrictor 68 may not be provided separately from the flow rate control passage 67 and may be provided as a part of the flow rate control passage 67. For example, if a part of the flow rate control passage 67 is formed along the sealing surface between the cylinder block 3 and the crank case 5 and is connected to the oil feed passage 54 at a position on the sealing surface, the flow restrictor 68 can be easily formed.
More specifically, the circulation path of the lubrication system 70 includes the oil feed passage 54, the communication passage 59, the supply passage 51, the suction tubes 46, the suction passage 45, the cover-side direct passage 47, the block-side direct passage 48, the breather passage 36, the circulation passage 65, the return passage 66, and the flow rate control passage 67.
When the engine 1 is started, pressure changes occur in the crank chamber 5a due to the upward and downward movement of the piston 13. When the piston 13 moves upward, the pressure inside the crank chamber 5a is reduced, so that a negative pressure tends to be created. When the piston 13 moves downward, the pressure inside the crank chamber 5a is increased, so that a positive pressure tends to be created.
As the piston 13 moves to the vicinity of the top dead center, a negative pressure tends to be created in the crank chamber 5a, and communication between the opening end 54a of the oil feed passage 54 and the crank chamber 5a is established. Then the crank chamber 5a communicates with the oil reservoir 7, and the negative pressure created in the crank chamber 5a is applied to the oil feed passage 54. Even when the engine 1 is tilted, the suction part 55 of the oil feed passage 54 is located below the surface of the oil A in the oil reservoir 7, and the oil A is sucked from the oil reservoir 7 and delivered to the crank chamber 5a. Since the opening end 54a is already in a fully open state when the piston 13 reaches the top dead center, the negative pressure in the crank chamber 5a can be sufficiently applied to the oil feed passage 54. Therefore, the oil A sucked from a position below the oil surface can be sufficiently supplied to the crank chamber 5a.
The oil delivered to the crank chamber 5a lubricates the driving components such as the piston 13 and the connecting rod 11 and is simultaneously scattered by the driving components to form oil mist. Part of the oil mist adheres to the wall surfaces of the crank chamber 5a and is re-liquefied.
When the piston 13 moves downward from the top dead center, a positive pressure is created in the crank chamber 5a, and the reed valve 60 is opened to communicate the crank chamber 5a with the oil reservoir 7. Then, the oil mist and oil increased in pressure in the crank chamber 5a are delivered to the oil reservoir 7 through the communication passage 59, and the pressure inside the oil reservoir 7 is increased. The oil mist ejected from the communication passage 59 collides with the surface of the oil A stored in the oil reservoir 7 and with the wall surfaces of the oil reservoir 7, is thereby liquefied, and is stored in the oil reservoir 7. The concentration of the remaining oil mist that has collided and bounced off within the oil reservoir 7 is lower than the concentration of oil mist in the crank chamber 5a. When a positive pressure is created in the crank chamber 5a, the oil feed passage 54 is blocked by the action of the one-way valve 57 so that oil is prevented from flowing back from the crank chamber 5a to the oil reservoir 7, and then the opening end 54a is covered with the piston 13.
When the pressure inside the oil reservoir 7 is increased, a pressure gradient is generated between the oil reservoir 7 and the valve-operating chamber 30. The oil mist accumulated in the oil reservoir 7 is delivered to the valve-operating chamber 30 through the supply passage 51. In the process of delivering the oil mist from the oil reservoir 7 to the valve-operating chamber 30, the components included in the valve-operating mechanism 19 in the valve driving chamber 52 provided in the supply passage 51 are lubricated. During this process, part of the oil mist is liquefied.
The oil liquefied in the valve driving chamber 52 can be delivered to the crank chamber 5a through the return passage 66. Therefore, excessive accumulation of oil in the valve driving chamber 52 can be prevented, and the flow of oil to the valve-operating chamber 30 can thereby be prevented. In addition, clogging of the supply passage 51 with oil can be prevented.
The oil mist supplied to the valve-operating chamber 30 lubricates the valve mechanism 24 provided in the valve-operating chamber 30 and is delivered to the crank chamber 5a through the cover-side direct passage 47 and the block-side direct passage 48. Even when the oil mist supplied to the valve-operating chamber 30 is liquefied and stays therein, a strong negative pressure in the crank chamber 5a is applied to the liquefied oil, and therefore the oil can be delivered to the crank chamber 5a, so that the oil is prevented from staying in the valve-operating chamber 30.
Therefore, the oil is prevented from being emitted together with blow-by gas discharged from the valve-operating chamber 30 through the breather passage 36.
When the engine 1 equipped with the lubrication system 70 configured as above is installed in a trimmer, which is an exemplary power tool, the above-described lubrication effect of the engine 1 can be efficiently obtained. As shown in
A gear head 84 is attached to the front end of the operating rod 81 and connected to the driving shaft (not shown) of the engine 1 through a driving shaft (not shown) provided in the operating rod 81, so that the power of the engine 1 can be transmitted to the gear head 84. The trimming edge 82 is attached to the gear head 84, and the power of the engine 1 is transmitted to the trimming edge 82 through the gear head 84 to rotate the trimming edge 82.
A handle 85 is attached to an intermediate portion of the operating rod 81, and a control lever (not shown) for controlling the power of the engine 1 is attached to the handle 85. An operator M operates the handle 85 with hands to perform trimming.
In all the possible operating attitudes of the trimmer 80 shown in
In particular, in the operating attitudes shown in
As described above, even when the above-described engine 1 is installed in the trimmer 80 that greatly changes its attitude, excessive accumulation of the lubricating oil in the valve-operating chamber 30 does not occur in all the possible operating attitudes, and therefore the liquefied lubricating oil is not discharged from the opening end 36a.
In the embodiment described above, two suction tubes 46 are provided in the valve-operating chamber 30 near the working unit, and one suction tube 46 is provided in the valve-operating chamber 30 on its side opposite to the working unit. However, as shown in
If the work is not performed in the upside-down state in which the valve-operating chamber 30 is located at a lower position, the small holes 73 may be omitted, and four suction tubes 46 may be provided in the valve-operating chamber 30 in the manner shown in
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