阅读说明：本技术 灰尘过滤器 (Dust filter ) 是由 土屋拓己 近藤记裕 蔵田恒之 于 2021-07-02 设计创作，主要内容包括：本发明提供一种灰尘过滤器,确保在壳体设有排水口的灰尘过滤器的排水性能,并且抑制水自排水口进入。灰尘过滤器对被吸入于车辆的吸附罐的空气进行过滤,该过滤器具有：过滤构件；壳体,其具有收纳过滤构件的收纳室,壳体具有用于排出进入到收纳室内的液体的排水口,排水口是形成于收纳室的底部的至少一个孔,该灰尘过滤器具有覆盖排水口的罩,罩在比排水口靠下方的位置具有向外部开口的出口,在罩内配置有至少一个挡板,挡板具有在排水口侧形成倾斜路径的斜面。(The invention provides a dust filter, which ensures the drainage performance of the dust filter with a drainage port arranged on a shell and inhibits water from entering from the drainage port. The dust filter filters air sucked into an adsorption tank of a vehicle, and includes: a filter member; the dust filter includes a housing having a housing chamber for housing a filter member, the housing having a drain port for discharging liquid introduced into the housing chamber, the drain port being at least one hole formed in a bottom portion of the housing chamber, the dust filter having a cover for covering the drain port, the cover having an outlet opening to the outside at a position below the drain port, at least one baffle plate disposed in the cover, the baffle plate having a slope forming an inclined path on the drain port side.)

1. A dust filter for filtering air sucked into an adsorption tank of a vehicle,

the dust filter has:

a filter member;

a housing having a housing chamber housing the filter member,

the housing has a drain port for discharging the liquid introduced into the receiving chamber,

the drain opening is at least one hole formed at the bottom of the receiving chamber,

the dust filter has a cover covering the drain opening,

the cover has an outlet opening to the outside at a position below the drain opening,

at least one baffle is disposed within the housing,

the at least one baffle has a slope forming an inclined path at the drain port side.

2. The dust filter of claim 1,

the at least one baffle is a plurality of baffles and is configured to avoid straight-through communication of the outlet and the apertures.

Technical Field

The present technology relates to a dust filter for filtering air sucked into an adsorption tank of a vehicle.

Background

A vehicle such as an automobile equipped with an engine has a canister that traps evaporated fuel generated in a fuel tank. The canister communicates with the atmosphere via an atmosphere passage provided with a dust filter that filters air drawn into the canister during a purge operation or the like. Such a dust filter is described in, for example, japanese patent application laid-open No. 2011-256760. In this dust filter, a drain port for draining water is provided at the bottom of a housing in which a filter member is housed, in addition to an air inlet through which air is sucked. In addition, a gutter-shaped drainage guide protruding obliquely downward from the casing is provided at the drainage groove. Therefore, even if water enters the case of the dust filter through the air inlet during rainfall or car washing, the water is guided to the outside through the drain guide from the drain port at the bottom, and does not accumulate in the case.

Documents of the prior art

Patent document

Patent document 1: japanese patent laid-open publication No. 2011-256760

Disclosure of Invention

Problems to be solved by the invention

With the dust filter described in the above publication, there is a possibility that: when the vehicle is driven on standing water, the splashed water reversely enters from the drainage guide into the housing. In addition, the same thing may occur when the lower portion of the vehicle body is washed with high-pressure washing water. When the water flowing backward through the drainage guide is large and the water level in the housing rises, the filter member housed inside may be immersed in the water, and the function may be impaired. Therefore, it is desired to suppress the entry of water from the drain port while ensuring the drainage performance of the drain port.

Means for solving the problems

One aspect of the present technology is a dust filter that filters air sucked into an adsorption tank of a vehicle, the dust filter including: a filter member; the dust filter includes a housing having a housing chamber for housing a filter member, the housing having a drain port for discharging a liquid introduced into the housing chamber, the drain port being at least one hole formed in a bottom portion of the housing chamber, the dust filter having a cover for covering the drain port, the cover having an outlet opening to the outside at a position below the drain port, at least one baffle plate disposed in the cover, the baffle plate having a slope forming an inclined path on the drain port side. This ensures smooth drainage performance of the dust filter, and prevents water from entering the drain port.

According to the solution, said at least one baffle is a plurality of baffles and is configured so as to avoid straight through passage of said outlet and each hole. This can reliably block the passage of water that enters linearly from the outlet of the cover.

Drawings

Fig. 1 is a diagram showing a fuel system of an automobile as an embodiment.

Fig. 2 is a perspective view of a dust filter as an embodiment attached to an intake duct (the outer shape is shown by a dotted line).

Fig. 3 is a cross-sectional view of the dust filter of fig. 2 taken along a direction orthogonal to the intake pipe, and a flow path of air sucked into the dust filter is indicated by an arrow.

Fig. 4 is a sectional view of the dust filter of fig. 2 cut at a central plane, and a water discharge path formed by a baffle in the cover is indicated by an arrow.

Fig. 5 is a sectional view showing the arrangement of a baffle plate according to another embodiment.

Fig. 6 is a sectional view showing the arrangement of a baffle plate according to still another embodiment.

Fig. 7 is a plan view of the lower member with the upper member of the cover removed.

Fig. 8 is a perspective view showing the upper member of the cover alone.

Description of the reference numerals

10. An engine; 12. a fuel tank; 14. a pump assembly; 16. an air cleaner; 18. an air inlet pipe; 20. an ejector; 22. an oil supply port; 24. an air inlet pipe; 26. a cover; 28. an adsorption tank; 30. a tank-side passage; 32. an ORVR valve; 34. a purge passage; 36. a purge control valve; 38. an atmospheric port; 40. a dust filter; 42. a connection path; 44. a filter member; 46. a storage chamber; 48. a housing; 50. an atmospheric port; 52. a side opening of the adsorption tank; 54. a lower member; 56. an upper member; 58. a buckle assembling mechanism; 60. a holding member; 62. a buckle assembling mechanism; 63. a holding member; 64. an atmosphere-side space; 66. a canister side space; 68. a water outlet; 70. an aperture; 72. a guide passage; 74. a cover; 76. a drainage path; 78. an outlet; 80. a lower member; 82. an upper member; 84. a buckle assembling mechanism; 86. a recessed portion; 88a to 88g and a baffle plate; 90. a baffle plate; 92. a baffle plate; 94 a-94 g and an inclined plane.

Detailed Description

Hereinafter, various embodiments of the present technology will be described with reference to the drawings. Further, the substantially non-different portions in the following embodiments are denoted by the similar reference numerals to avoid the repetitive description. Fig. 1 shows a fuel system that can be applied to a vehicle such as an automobile. The fuel system has: an engine 10; and a fuel tank 12 that holds fuel that is burned at the engine 10. The engine 10 takes in air purified by an air cleaner 16 through an intake pipe 18. A pump unit 14 is provided in the fuel tank 12, and fuel delivered from the pump unit 14 is injected from an injector 20 into an intake pipe 18. An intake pipe 24 that introduces the fuel injected from the fuel supply port 22 into the fuel tank 12 is connected to the fuel tank 12. The fuel fill port 22 is detachably closed by a cap 26. The inlet pipe 24 extends generally obliquely upward from the fuel tank 12 to the fuel supply port 22.

[ adsorption tank ]

As shown in fig. 1, the fuel system has a canister 28, and the canister 28 traps the evaporated fuel generated at the fuel tank 12 to prevent the evaporated fuel from being released to the atmosphere. An adsorption layer made of activated carbon or the like is disposed in the housing of the canister 28. The canister 28 communicates with the fuel tank 12 through a tank-side passage 30, and the evaporated fuel flowing in from the tank-side passage 30 is captured by the adsorption layer. The fuel tank 12 is provided with an ORVR valve 32, and the ORVR valve 32 includes a float valve and the like, and transfers the evaporated fuel having passed through the ORVR valve 32 to the canister 28.

The canister 28 communicates with the intake pipe 18 of the engine 10 via a purge passage 34. The purge passage 34 is provided with a purge control valve 36. The opening and closing of the purge control valve 36 is controlled by, for example, an Electronic Control Unit (ECU)37 in accordance with the operating state of the engine 10. When the purge control valve 36 is opened, the intake negative pressure of the engine 10 acts on the canister 28 through the purge passage 34. Thereby, the evaporated fuel adsorbed on the adsorption layer in the canister 28 is desorbed and is introduced into the engine 10 together with the intake air flowing through the intake pipe 18, and therefore can be combusted in the engine 10.

Further, the canister 28 has an atmosphere port 38 communicating with the atmosphere. When the canister 28 is purged, air (purge air) is introduced from the atmosphere into the canister 28 through the atmosphere port 38. In addition to the purge operation, a negative pressure is applied to the inside of the fuel tank 12 due to, for example, fuel consumption or temperature reduction. Conversely, when the evaporated fuel is generated due to a temperature rise, fuel sloshing, or the like, a positive pressure is applied to the inside of the fuel tank 12. The pressure fluctuation in the fuel tank 12 is alleviated by introducing air into the canister 28 through the atmospheric port 38, or releasing air in the canister 28 to the atmosphere through the atmospheric port 38.

[ dust filter ]

As shown in fig. 2 and 3, the fuel system is provided with a dust filter 40 (air filter), and the dust filter 40 is used to remove foreign matters such as dust from the air sucked into the canister 28. The dust filter 40 communicates with the canister 28 through an appropriate connection passage 42 formed of a pipe or a hose (see fig. 1). The dust filter 40 includes a filter member 44 and a housing 48 made of, for example, resin and having a housing chamber 46 for housing the filter member 44. When the purge operation of the canister 28 is performed, the dust filter 40 filters air sucked through the connection passage 42 to remove foreign substances such as dust. The housing 48 is provided with: an atmospheric port 50 opened to the atmosphere for sucking air; and a canister side port 52 connected to the canister 28.

The dust filter 40 is attached to the vicinity of the oil supply port 22 of the intake pipe 24, for example. The housing 48 is formed, for example, in a substantially semi-cylindrical shape so as to be able to abut against the side surface of the intake pipe 24. When the dust filter 40 is attached to the inclined portion of the intake duct 24, the dust filter 40 also assumes an attitude in which the shaft is inclined. The housing 48 includes a lower member 54 and an upper member 56, and can be coupled by an appropriate attachment mechanism such as a snap attachment mechanism 58.

The dust filter 40 is secured to the air inlet duct 24 by a suitable retaining member 60. The holding member 60 is formed in a semi-cylindrical shape, for example, and the dust filter 40 can be fixed by surrounding the intake duct 24 with the holding member 60 and the housing 48. The holding member 60 is coupled to the housing 48 using an appropriate fitting mechanism such as a snap fitting mechanism 62. The air intake port 50 is disposed, for example, on the inner peripheral side of the casing 48, and an appropriate gap is secured between the air intake port and the side surface of the intake pipe 24.

The filter member 44 is, for example, a filter paper folded into a pleated shape, and is positioned at a predetermined position of the storage chamber 46 by using an appropriate holding member 63. As another embodiment, the filter member 44 may be a block including a foamed urethane resin. When the filter member 44 is positioned at a predetermined position, the housing chamber 46 is divided by the filter member 44 into an atmosphere-side space 64 on the lower side and a canister-side space 66 on the upper side.

When the connection passage 42 becomes negative pressure, air flows from the atmosphere into the case 48 through the atmospheric port 50. In the case 48, the air moves from the atmosphere side space 64 to the canister side space 66 through the filter member 44, and at this time, the filter member 44 captures dust. The purified air is introduced from the canister-side space 66 to the canister 28 through the connection passage 42.

[ Water discharge opening ]

As shown in fig. 3 to 5, a drain port 68 is provided in the bottom of the case 48, and the drain port 68 is used for discharging liquid such as water that has entered the inside of the case 48. The drain port 68 is provided on the atmosphere side of the filter member 44, that is, at a position communicating with the atmosphere side space 64 of the housing chamber 46 inside the housing 48. In a state where the dust filter 40 is attached to the intake duct 24, the drain port 68 is located at the lowest portion of the atmosphere side space 64 inside the housing 48. During rainy weather, or during car wash, there is a possibility that water enters the housing 48 from the atmosphere 50 together with air. Even in such a case, water is discharged from the drain port 68 at the bottom of the atmosphere-side space 64 to the outside of the housing 48. Therefore, the water is prevented from accumulating at the bottom of the housing chamber 46 of the case 48 and degrading the filtering performance of the dust filter 40. The drain port 68 is, for example, at least one hole 70 opened in the bottom surface of the housing 48.

The hole 70 may be provided with a guide passage 72 extending obliquely downward from the housing 48. The guide passage 72 may be provided with a structure that can easily close the drain port 68 when the housing 48 of the dust filter 40 is subjected to a leak test, for example, by cutting the tip end of the guide passage in a flat surface.

[ shade ]

As shown in fig. 2, 4, and 5, the dust filter 40 includes a cover 74 that covers the drain port 68 and prevents liquid such as water from entering the housing 48. The cover 74 is a hollow member having a drain passage 76 formed therein, and has an outlet 78 opening to the outside below the drain port 68. The water that has entered the housing 48 can be discharged from the drain port 68 into the cover 74, and then falls from the outlet 78 to the outside via the drain path 76. The drain passage 76 is formed so as to avoid straight through connection between the outlet 78 and the holes 70 (each hole in the case where there are a plurality of holes) forming the drain port 68 of the housing 48. Thus, the length of the drain path 76 is longer than the linear distance from the hole 70 to the outlet 78. Such a shape is, for example, a labyrinth shape. With such a shape of the drain path 76, even if a jet of water or cleaning liquid enters from the outlet 78 during high-pressure washing of the vehicle, for example, the momentum thereof is weakened, and the jet is suppressed from reaching the drain port 68. Further, the discharge path may be branched or merged.

As shown in fig. 2, 4, 5, 8, the cover 74 can be fully or partially integrally formed with the housing 48. For example, the cover 74 is composed of a lower member 80 and an upper member (cover member) 82, and only the lower member 80 is integrally formed with the housing 48. Although not shown, the cover 74 may be completely independent and attached to the housing 48 by an appropriate mechanism. In this case, the cover 74 can be similarly configured by two members. The upper member 82 can be attached to the lower member 80 by an appropriate mechanism such as a snap-fit mechanism 84. By configuring the cover 74 in two parts in this manner, the desired drainage path 76 as described above can be easily formed. If necessary, the upper member 82 may be provided with a recessed portion 86, and the recessed portion 86 may be provided to avoid interference with a surrounding member (for example, a tapered portion of the intake pipe 24).

[ baffle ]

As shown in fig. 4 and 5, the cover 74 has linear baffles 88a, 88b, 88c inside that cross the connection holes 70 and the outlet 78. Baffles 88a, 88b, 88c are formed on the lower member 80. By the baffles 88a, 88b, 88c, the drain path 76 is formed to avoid straight-through communication between the hole 70 and the outlet 78. The water discharge path 76 in the cover 74 can be formed into a labyrinth shape by the baffles 88a, 88b, and 88 c. The baffles 88a, 88b, 88c are configured to prevent the aperture 70 of the drain 68 and the outlet 78 from being straight through. As shown in fig. 6, as another embodiment, a baffle 88d that does not reach either of the left and right walls of the cover 74 is provided, and the discharge paths can be branched and merged. Further, two baffle plates 88e and 88f extending in the direction facing each other from the left and right walls of the cover 74 may be provided. These baffles 88d, 88e, 88f are also configured to prevent the aperture 70 of the drain 68 and the outlet 78 from passing straight through. As shown in fig. 7, as another embodiment, only one baffle 88g is provided, and the hole 70 of the drain port 68 and a part (left side part in the drawing) of the outlet 78 can be linearly communicated.

As shown in fig. 4 and 8, another baffle 90 may be provided on the upper member 82 so as to overlap with the baffle 88c of the lower member 80 when the upper member is attached to the lower member 80. Even if a gap (not shown) for fitting exists between the baffle 88c of the lower member 80 and the inner surface of the upper member 82, the presence of the baffle of the upper member 82 suppresses the momentum of the water flow entering from the outlet 78 and passing over the upper side of the baffle 88c toward the drain port 68. The baffle is disposed, for example, on the side of the drain port 68 with respect to the baffle 88c on the outermost outlet side of the upper member 82. The wall of the recess 86 of the upper member 82 can also function as an additional baffle 92.

[ sectional area of drainage route ]

As is apparent from fig. 4 and 5, the cross-sectional area of the drain passage 76 is larger than the cross-sectional area of the hole 70 of the drain port 68 which is a narrowed portion. When a plurality of holes are present, the cross-sectional area of the drainage path is preferably larger than the total cross-sectional area of the holes. Since the air sucked into the adsorption tank 28 through the dust filter 40 or discharged from the adsorption tank 28 also passes through the drain port 68, the cross-sectional area of the drain port 68 is designed as described above, thereby suppressing a decrease in air flow resistance due to the cover 74.

[ inclined plane of baffle ]

As shown in fig. 5 to 7, the baffle plates 88a to 88g have inclined surfaces 94a to 94g forming inclined paths on the drain side. The inclined surfaces 94a to 94g are, for example, surfaces whose intersecting lines with the bottom surface of the housing 48 are inclined to either side with respect to the horizontal. The inclined surfaces 94a to 94g form inclined paths, and as described above, the baffles 88a to 88g can prevent water from entering from the outlet 78, and water from the drain port 68 can smoothly flow down inside the cover 74.

Although specific examples have been described above, the present technology is not limited to these examples, and those skilled in the art can make various substitutions, improvements, and changes without departing from the scope of the present technology.