The present application claims a priority from Japanese Patent Application No. 2015-127120, filed Jun. 24, 2015, which is incorporated herein by reference.
The present invention relates to an air cleaner incorporated in a stratified scavenging two-stroke internal combustion engine.
Two-stroke internal combustion engines are used as power sources for portable working machines such as a brush cutter, a chain saw, and a power blower.
U.S. Pat. No. 7,494,113 B2 discloses a stratified scavenging two-stroke internal combustion engine. A stratified scavenging engine, in a scavenging stroke, introduce air free of air-fuel mixture, namely fresh air, into a combustion chamber before introducing air-fuel mixture in a crankcase into the combustion chamber. The fresh air, which is introduced early in the scavenging stroke into the combustion chamber, is called “leading air”.
An engine disclosed in U.S. Pat. No. 7,494,113 B2 has an intake system having two passages. A first passage is an “air passage”. A second passage is an “air-fuel mixture passage”. The fresh air, or the leading air, is fed to an engine body through the air passage. Air-fuel mixture is fed to the crankcase of the engine body through the air-fuel mixture passage.
The intake system disclosed in U.S. Pat. No. 7,494,113 B2 is constituted by an air cleaner, a carburetor, and an intake member connecting the carburetor and the engine body. The intake member has a first partition wall extending continuously in the longitudinal direction. The intake member has an air passage and an air-fuel mixture passage that are made independent from each other by the first partition wall.
The carburetor disclosed in U.S. Pat. No. 7,494,113 B2 has a throttle valve and a choke valve. The throttle valve and the choke valve are each formed by a butterfly valve. The throttle valve and the choke valve are in their fully opened positions while the machine is working at full throttle.
The carburetor disclosed in U.S. Pat. No. 7,494,113 B2 has a second partition wall dividing an internal gas passage of the carburetor into two passages. When the throttle valve and the choke valve are in the fully opened positions, these two valves and the second partition wall divide the internal passage of the carburetor into the air passage and the air-fuel mixture passage.
In this way, while the machine is working at full-throttle operating condition, air that has been cleaned by the air cleaner is fed to the crankcase through the air-fuel mixture passage as well as to the engine body through the air passage. The carburetor has a fuel nozzle in the air-fuel mixture passage. Fuel is sucked out through the fuel nozzle by air passing through the air-fuel mixture passage, and air-fuel mixture, that is, a mixture of fuel and air is generated within the air-fuel mixture passage in the carburetor.
U.S. Pat. No. 7,494,113 B2 discloses two types of carburetors. First and second types of carburetors are different from each other in their partition walls. In the first type of carburetor, the partition wall is shaped to divide, together with a fully opened throttle valve and a fully opened choke valve, the gas passage in the carburetor into two passages (
In the second type of carburetor, the partition wall is shaped similarly to that of the first type of carburetor but has a window formed by cutting away a part of the partition wall (
Two-stroke internal combustion engines including the stratified scavenging two-stroke internal combustion engine have a problem of air cleaner contamination caused by blow-back of fuel. The fuel blow-back problem is caused not only by blow-back of air-fuel mixture from the air-fuel mixture passage, but also by blow-back of air from the air passage. It is natural that this problem is caused in an engine having the second type of carburetor. The problem is also caused in an engine having the first type of carburetor during acceleration or deceleration, or at half throttle.
Japanese Patent Laid-Open No. 2009-185633 proposes a measure to prevent contamination of an element due to blown-back fuel by effectively using the characteristics of stratified scavenging two-stroke internal combustion engines. Specifically, Japanese Patent Laid-Open No. 2009-185633 proposes an air cleaner for a stratified scavenging two-stroke internal combustion engine.
The air cleaner disclosed in Japanese Patent Laid-Open No. 2009-185633 has a first inlet through which clean air cleaned by an element is sent to an air passage of a carburetor and a second inlet through which the clean air is sent to an air-fuel mixture passage of the carburetor. The first and second inlets are independent from each other.
The air cleaner disclosed in Japanese Patent Laid-Open No. 2009-185633 has a guide member guiding blown-back fresh air from the air passage to the second inlet. That is, the guide member is positioned adjacent to the first inlet and the second inlet and is shaped such that it guides the blown-back fresh air from the first inlet to the second inlet. Thus shaped guide member also functions to receive air-fuel mixture from the second inlet.
The guide member inhibits diffusion of blown-back fresh air from the first inlet and blown-back air-fuel mixture from the second inlet in the air cleaner.
The present invention aims to prevent contamination of an element in an air cleaner incorporated in a stratified scavenging two-stroke internal combustion engine.
The present invention further aims to improve the effect of preventing the contamination of the element in the air cleaner disclosed in Japanese Patent Laid-Open No. 2009-185633.
The present invention further aims to provide an air cleaner used in a stratified scavenging two-stroke internal combustion engine that prevents contamination of an element due to blow-back of fresh air or air-fuel mixture from an intake system air passage or an intake system air-fuel mixture passage.
According to the present invention, the above technical problems can be achieved by providing an air cleaner (30, 200) for a stratified scavenging two-stroke internal combustion engine, the air cleaner including:
Blow-back of fuel from the air passage or the air-fuel mixture passage in the engine intake system enters the air cleaner through the first inlet (60) or the second inlet (62). The passage forming member (70, 204) located to surround the first inlet (60) or the second inlet (62) prevents the blown-back fuel from diffusing in the air cleaner.
When the extended passage (72) is provided at the second inlet (62), blow-back of air-fuel mixture enters the extended passage (72) through the second inlet (62). The extended passage (72) is formed by the passage forming member (70), and thus this prevents fuel contained in the blown-back air-fuel mixture from diffusing in the air cleaner.
A preferable embodiment of the present invention will be described based on the attached drawings. The embodiment shows a typical example of the present invention in which an air-fuel mixture passage is extended, but the present invention can also be applied to extension of an air passage.
As can be seen from
The engine body 2 has a piston 12 fitted into a cylinder 10, and the piston 12 forms a combustion chamber 14. The piston 12 reciprocates in the cylinder 10. A reference numeral 16 denotes an exhaust port. The exhaust system 4 is connected to the exhaust port 16. A reference numeral 18 denotes an air-fuel mixture port. The air-fuel mixture port 18 leads to a crankcase 20 of the engine 100.
The cylinder 10 has scavenging passages 22 connecting the crankcase 20 to the combustion chamber 14. The scavenging passages 22 are in communication at one end with the crankcase 20 and at the other end with the combustion chamber 14 through scavenging ports 24.
The cylinder 10 also has an air port 26. Fresh air, or air free of air-fuel mixture, to be described later, is fed to the air port 26. The scavenging ports 24 are in communication with the air port 26 via a piston groove 28. That is to say, the piston 12 has a piston groove 28 on a circumferential surface thereof. The piston groove 28 is a recess formed on the circumferential surface of the piston 12, and has a function to temporarily store air.
The exhaust port 16, the air-fuel mixture port 18, the scavenging ports 24, and the air port 26 are opened and close by the piston 12. That is, the engine body 2 is of a so-called piston valve type. The communication between the piston groove 28 and the scavenging ports 24 and the communication between the piston groove 28 and the air port 26 are shut off by the operation of the piston 12. In other words, the reciprocation of the piston 12 controls communication and shut-off between the piston groove 28 and the scavenging ports 24, as well as controlling communication and shut-off between the piston groove 28 and the air port 26.
The intake system 6 is connected to the air port 26 and the air-fuel mixture port 18. The intake system 6 includes an air cleaner 30, a carburetor 32, and an intake member 34. The intake member 34 is made of a flexible material (elastic resin). The carburetor 32 is connected to the engine body 2 via the flexible intake member 34. The air cleaner 30 is fixed at an upstream end of the carburetor 32.
The carburetor 32 has a throttle valve 40 and a choke valve 42 located upstream of the throttle valve 40. The throttle valve 40 and the choke valve 42 are each formed by a butterfly valve. The carburetor 32 has a first partition wall 44. The throttle valve 40, the choke valve 42, and the first partition wall 44 form a first air passage 50 and a first air-fuel mixture passage 52 in an internal gas passage 46 of the carburetor 32 when the throttle valve 40 and the choke valve 42 are in the fully opened positions, that is, when the engine 100 is rotating at a high speed.
In
The intake member 34 interposed between the carburetor 32 and the engine body 2 has a second partition wall 58. The intake member 34 has a second air passage 54 and a second air-fuel mixture passage 56 located respectively on one side and the other side of the intake member 34 across the second partition wall 58.
The carburetor 32 may be connected to the engine body 2 by a first member provided with the second air passage 54 and a second member that is separate from the first member and provided with the second air-fuel mixture passage 56, instead of by the intake member 34 provided with the second air passage 54 and the second air-fuel mixture passage 56.
As can be seen from the foregoing description, the first air passage 50 in the carburetor 32 together with the second air passage 54 of the intake member 34 form the air passage of the intake system 6, downstream of the air cleaner 30. The other, air-fuel mixture passage of the intake system is formed by the first air-fuel mixture passage 52 in the carburetor 32 and the second air-fuel mixture passage 56 of the intake member 34.
The air cleaner 30 has a first inlet 60 and a second inlet 62, which are independent from each other. External air is cleaned by a cleaner element 64 to produce clean air. The clean air enters the intake system air passage through the first inlet 60 and enters the intake system air-fuel mixture passage through the second inlet 62.
In the air cleaner 30, a passage forming member 70 is connected to the second inlet 62, that is, an inlet leading to the intake system air-fuel mixture passage. The passage forming member 70 has an extended air-fuel mixture passage 72. The extended air-fuel mixture passage 72 has an entrance opening 72a and an exit opening 72b. Part of air cleaned by the cleaner element 64 enters the extended air-fuel mixture passage 72 through the entrance opening 72a. Then, the air passing through the extended air-fuel mixture passage 72 enters the second inlet 62 through the exit opening 72b.
The passage forming member 70 is shaped to surround a periphery of the first inlet 60 leading to the intake system air passage.
Referring to
The passage forming member 70 has an arc shape as seen in a plan view. The passage forming member 70 is arranged inwardly of an inner circumferential surface 64b of the element 64. An outer circumferential surface 70a of the passage forming member 70 and the inner circumferential surface 64b of the cleaner element 64 are spaced apart from each other. A distance between the passage forming member 70 and the inner circumferential surface 64b of the cleaner element 64 is denoted by a reference character
As can be seen from
The passage forming member 70 attached to the second inlet 62 extends in a circumferential direction along an outer circumferential portion of the air cleaner base 30a. The entrance opening 72a of the extended air-fuel mixture passage 72 of the passage forming member 70 is located close to the exit opening 72b, or the second inlet 62.
The periphery of the first inlet 60 leading to the intake system air passage is surrounded by the passage forming member 70. The passage forming member 70 forms a peripheral wall surface 70b that defines a blown-back fuel diffusion preventing region 74 leading to the first inlet 60.
The cleaner element 64 has the circular ring shape as described above. Clean air filtered by the cleaner element 64 is reserved in a space surrounded by the element 64. The space surrounded by the element 64 is called an “air cleaner clean space”. The first and second inlets 60 and 62 are open to the air cleaner clean space.
The element 64 has a ceiling plate member 66 (
Part of air cleaned by the cleaner element 64 enters the extended air-fuel mixture passage 72 through the entrance opening 72a of the passage forming member 70 (the extended air-fuel mixture passage 72), and then passes through the extended air-fuel mixture passage 72 and enters the intake system air-fuel mixture passage through the exit opening 72b and the second inlet 62.
Part of air cleaned by the cleaner element 64 enters the blown-back fuel diffusion preventing region 74 through a first clearance gap 80 (
During operation of the engine 100, blow-back of air-fuel mixture through the intake system air-fuel mixture passage enters the passage forming member 70. Fuel components and oil components contained in the blown-back air-fuel mixture adhere to wall surfaces of the relatively long passage forming member 70. This prevents the contamination of the cleaner element 64 by the blown-back air-fuel mixture.
During operation of the engine 100, the inner circumferential wall of the passage forming member 70 inhibits diffusion of the blown-back air that has been flowed back through the intake system air passage. That is, the blown-back air is trapped in the blown-back fuel diffusion preventing region 74. This prevents the contamination of the cleaner element 64 that is otherwise caused by the air-fuel mixture and the oil components that can be contained in the blown-back air.
The ceiling plate member 66 forming the ceiling wall of the blown-back fuel diffusion preventing region 74 may be integral with or separate from the element 64.
The shape of the passage forming member 70 as seen in a plan view is not limited to circle. It may have an elliptical or polygonal shape. The term “polygonal” is not limited to the geometric sense. It means a shape having corners. The corners are preferably rounded. The passage forming member 70 preferably has no turns like hairpin turns. The length of the passage forming member 70 may be a half circle or three-fourths of circle, for example.
In the example in
The extended air-fuel mixture passage 72 of the passage forming member 70 most preferably has the same effective cross-sectional area at any point in the longitudinal direction. Of course, the effective cross-sectional area may be varied to an acceptable degree.
Referring to
The air cleaner base 202 and the passage forming member 204 are moldings made of synthetic resin. The element member 206 includes the ring-shaped element 64 and the ceiling plate member 66, and the cleaner element 64 is formed by a filtering material such as a mesh material.
The passage forming member 204 has a plurality of legs 210, and the legs 210 each has a claw 212 at an end. The passage forming member 204 is fixed to the air cleaner base 202 by using the claw legs 210. The passage forming member 204 has a U-shaped cross-section that is opened toward the air cleaner base 202, and forms the extended air-fuel mixture passage 72 together with the air cleaner base 202.
The passage forming member 204 is located adjacent to the cleaner element 64, which has a circular shape in a plan view. The passage forming member 204 has an arc shape in a plan view and extends along almost the entire length of the cleaner element 64. The passage forming member 204 is capable of rectifying air passing therethrough because of the long, arc shape.
As can be seen from
The blown-back fuel diffusion preventing region 74 defined by the passage forming member 204 is opened outwardly through two parts. A first part is the first clearance gap 80 between the entrance opening 72a and the exit opening 72b of the passage forming member 204 (the extended air-fuel mixture passage 72). A second part is the concave portion 218 of the passage forming member 204 as described above, the concave portion 218 is located diagonally opposite to the first inlet 60, that is, substantially opposite to the first clearance gap 80. Air cleaned by the element 64 enters the blown-back fuel diffusion preventing region 74 through these two parts, and enters the intake system air passage through the first inlet 60.
The preferable embodiment of the present invention has been described. An air cleaner according to the present invention is suitably applied to a stratified scavenging engine in the form of the disclosure in U.S. Pat. No. 7,494,113 B2. As in the foregoing description, the engine disclosed in U.S. Pat. No. 7,494,113 B2 has a partition wall in the carburetor. The partition wall substantially partitions the engine intake system into the air passage and the air-fuel mixture passage when the throttle valve is in its fully opened position.
Referring to
The second type of carburetor has the window in the partition wall in the carburetor, so that the intake system air passage and the intake system air-fuel mixture passage are in communication with each other all the times. The window may be formed at any portion of the engine intake system.
The above embodiment has shown the case where the intake system air-fuel mixture passage is extended, while the present invention is not limited to this. The present invention can be suitably applied to extension of the intake system air passage, instead of the extension of the intake system air-fuel mixture passage. When the passage forming member 70 is provided at the first inlet 60 for extending the intake system air passage, the location of the first inlet 60 and the second inlet 62 may be reversed so that the first inlet 60 is formed outwardly of the second inlet 62.
100 Stratified scavenging engine
6 Intake system
12 Piston
14 Combustion chamber
18 Air-fuel mixture port
20 Crankcase
22 Scavenging passage
30 air cleaner
30
a Air cleaner base
60 First inlet
62 Second inlet
64 Cleaner element
66 Ceiling plate member of cleaner element
70 Passage forming member
72 Extended air-fuel mixture passage
72
a Entrance opening of extended air-fuel mixture passage
72
b Exit opening of extended air-fuel mixture passage
74 Blown-back fuel diffusion preventing region
80 Clearance gap between entrance opening and exit opening of passage forming member
200 Air cleaner in embodiment
202 Air cleaner base
204 Passage forming member
204
a Ceiling wall of passage forming member
206 Element member
Number | Date | Country | Kind |
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2015-127120 | Jun 2015 | JP | national |