DE102013216348A1 - INLET DEVICE - Google Patents

Abstract

An inlet device comprises an air filter (2), a channel (3) downstream of the air filter, and a flow rate measuring section (4) attached to the channel. A filter housing (8) of the air filter and the channel define a bent part (15) through which inlet air is deflected to reach the flow rate measuring section. A distributor plate (30) is disposed in the filter housing and upstream of the flow rate measuring section. The bent part has an inner side, which is an inner side of the distributor plate, and an outer side, which is an outer side of the distributor plate, when intake air is deflected into the bent part. At least one of an inlet (22) and an outlet (23) of a bypass passage (18) of the flow rate measuring section is located adjacent to the inner side rather than to the outer side.

Description

The present disclosure relates to an intake apparatus including an air filter and a flow rate measuring portion that measures a flow rate of intake air discharged from the air cleaner and the air cleaner, respectively.

JP-H09-88658 A and JP-H11-211528 A describe an inlet device having an air filter, a channel connected to the air filter, and a flow rate measuring section attached to the passage. The flow rate measuring section has a bypass passage that sucks a part of intake air and a flow rate sensor that is disposed in the bypass passage. The inlet device has a bent part formed between a housing of the air filter and the passage to change the flow direction of an intake air. The flow direction in the housing and the flow direction in the channel intersect, therefore, the intake air flowing out of the housing is deflected near the intake port of the housing and flows into the passage. For this reason, when the flow of intake air is deflected, the flow velocity on the inside of the deflection becomes smaller and becomes larger on the outside of the deflection, therefore, a velocity distribution arises in the passage.

In general, in a case where a flow rate is measured by a measuring portion, if the flow velocity around an inlet or outlet of a bypass passage is small, it is difficult to stabilize the flow of intake air and to accurately measure the flow rate. Therefore, at least one of the inlet and the outlet of the bypass passage may be arranged at a position where the flow velocity is large.

In JP-H09-88658 A That is, the flow rate measuring section is attached in a manner such that the inlet of the bypass passage is at a position where the flow velocity on the outer side of the deflection is high.

However, there may be a case where the position of the flow rate measuring section can not be flexibly adjusted due to interference with other parts of the cross-sectional shape of the passage. That is, there may be a case where at least one of the inlet and the outlet of the bypass passage is disposed on the inner side of the deflection.

In JP-H11-211528 A a distributor plate is disposed upstream of the flow rate measuring section to reduce the turbulence in the flow of the intake air. However, the distributor plate can not reduce the deviation in the flow velocity distribution.

It is an object of the present disclosure to provide an intake device in which a flow rate of intake air can be accurately measured when at least one of the inlet and the outlet of a bypass passage of a flow rate measuring section is located on the inner side of the deflection.

According to an example of the present disclosure, an intake device includes an air cleaner that cleans intake air to be sucked into an internal combustion engine, a passage through which the intake air purified by the air cleaner passes, and a flow rate measuring section measures a flow rate of the intake air flowing through the passage.

The air filter has a filter element that filters the intake air flowing in a primary direction and a filter housing that accommodates the filter element. The filter housing has an intake port through which the intake air flows in a secondary direction, which is different from the primary direction.

The channel is connected to the inlet outlet of the filter housing. The filter housing and the channel define a bent portion through which the inlet air passing through the filter element is deflected to reach the flow rate measuring section.

The flow rate measuring section has a bypass passage into which a part of the intake air flows from the filter housing, and a flow rate sensor that detects a flow rate of the intake air flowing in the bypass passage.

The bent part has a passage that extends from the filter element to the flow rate measuring section with the bent shape, and is set to have an inner side that is on the inner side of the bent shape and an outer side which is on the outer side of the curved shape. At least one of an inlet and an outlet of the bypass passage is located adjacent to the inner side rather than the outer side in the bent part.

A distributor plate is disposed in the filter housing and located upstream the flow rate measuring section and controls a flow of the intake air and guides the intake air in the bypass passage.

The distributor plate has a curved shape along which the intake air is deflected from the primary direction to the secondary direction, and has a curvature set to become smaller from an upstream side to a downstream side in an intake air flow , That is, the radius of curvature of the distributor plate becomes larger from the upstream side to the downstream side in the flow of the intake air.

Accordingly, due to the distributor plate, the flow rate of the inlet air on the inner side becomes larger in the passage extending from the filter element to the flow rate measuring section.

For this reason, even if at least one of the inlet is through the outlet of the bypass passage of the flow rate measuring section on the inner side in the channel, the flow rate can be accurately measured.

The foregoing and other objects, features and advantages of the present disclosure will become more apparent from the following detailed description made with reference to the attached drawings.

1 FIG. 12 is a schematic cross-sectional view illustrating an intake apparatus according to a first embodiment; FIG.

2 (a) (b) or (c) is a cross-sectional view taken along a line II-II in FIG 1 taken;

3 FIG. 12 is a schematic cross-sectional view illustrating a flow rate measuring portion of the intake apparatus of the first embodiment; FIG.

4 FIG. 12 is a schematic cross-sectional view illustrating an intake apparatus according to a second embodiment; FIG.

5 FIG. 12 is a graph illustrating a relationship between a flow rate, an intake air in a passage and a flow speed of an intake air at an inlet of a bypass passage of a flow rate measuring section of the intake apparatus of the second embodiment; FIG.

6 Fig. 10 is a graph illustrating a relationship between a flow rate of intake air in a passage and a variation in an output of the flow rate measuring section of the intake device of the second embodiment;

7 Fig. 12 is a graph illustrating a relationship between a flow rate of intake air in a passage and a variation in an output characteristic of the flow rate measuring portion of the intake apparatus of the second embodiment when a filter element is clogged;

8th FIG. 12 is a schematic cross-sectional view illustrating an intake apparatus according to a third embodiment; FIG.

9 FIG. 12 is a schematic cross-sectional view illustrating an intake apparatus according to a fourth embodiment; FIG. and

10 FIG. 12 is a schematic cross-sectional view illustrating an intake apparatus according to a fifth embodiment. FIG.

Embodiments of the present disclosure will be described hereinafter with reference to drawings. In the embodiments, a part corresponding to an item described in a preceding embodiment may be given the same reference numeral, and a redundant explanation for that part may be omitted. When only a part of a configuration is described in an embodiment, another preceding embodiment may be applied to the other parts of the configuration. The parts can be combined, even if it is not explicitly stated that the parts can be combined. The embodiments may be partially combined, even if not explicitly described, that the embodiments may be combined, provided that there is no disadvantage in this combination.

First Embodiment

An inlet device 1 according to a first embodiment is with reference to 1 to 3 explained.

As in 1 is shown has the inlet device 1 an air filter 2 which purifies an intake air to be sucked into an internal combustion engine (not shown), a passage 3 passing through the air filter 2 cleaned inlet air sends downstream, and a flow rate measuring section 4 who is on the canal 3 appropriate is attached to measure a flow rate of intake air passing through the duct 3 flows. Hereinafter, the flow rate measuring section 4 as an air flow meter 4 (AFM 4 ).

The air filter 2 has a filter element 7 , which filters inlet air, and a filter housing 8th that the filter element 7 accommodates or accommodates.

The filter housing 8th has approximately a rectangular box shape and is made of a resin or plastic. The filter housing 8th has an inlet 9 and an outlet 10 for the intake air.

The filter element 7 has a filter medium, such. A nonwoven fabric made of a synthetic fiber or filter paper, and is at a position between the inlet 9 and the outlet 10 of the filter housing 8th arranged. Intake air which passes through the inlet 9 flows, the filter element passes 7 and flows out of the filter housing 8th through the outlet 10 out.

In the filter housing 8th are a direction (primary direction) in the intake air through the filter element 7 flows, and a direction (secondary direction), in the intake air through the outlet 10 flows, different from each other.

The filter housing 8th has a first wall 8a and a second wall 8b in each other in a left-and-right direction 1 are opposite. The inlet 9 flows into the first wall 8a and the outlet 10 flows into the second wall 8b , The position of the inlet 9 and the position of the outlet 10 are in an up-and-down direction (primary direction) of 1 different, which is perpendicular to the left-and-right direction (secondary direction).

The filter element 7 is located between the inlet 9 and the outlet 10 in the up-and-down direction of 1 , For this reason, the flow direction of the intake air is in the filter element 7 different from the flow direction of the intake air in the outlet 10 , Also, the position of the inlet 9 and the position of the outlet 10 be different from each other in the other direction perpendicular to the up-and-down direction and the left-and-right direction in 1 ,

The channel 3 extends from the outlet 10 linear in the left-and-right direction. The air flow meter 4 is on the canal 3 attached and located downstream of the outlet 10 , The filter housing 8th and the channel 3 define a bent part 15 through which the intake air coming out of the filter element 7 flows out, is deflected and the air flow meter 4 reached.

That is, the intake air coming from the inlet 9 flows out, the filter element happens 7 in the up-and-down direction, the flow direction of the intake air in the bent part becomes 15 changed and flows through the outlet 10 and the channel 3 to the air flow meter 4 ,

The channel 3 can be a round cross section, as in 2 (a) is shown, or may have an elliptical cross section, as in 2 B) or shown in (c). Alternatively, the channel 3 have a flat circular cross section or disk cross section.

There is also a channel 16 with the inlet 9 connected and the channel 16 extends linearly from the inlet 9 in the left-and-right direction. The channel 3 and the channel 16 may be formed integrally with the filter housing made of resin or plastic or may be separate from the filter housing 8th be educated. Furthermore, z. B. the channel 3 in an upstream part, which is connected to the filter housing 8th is integrated, and a downstream part, which is separate from the filter housing 8th is made.

As in 3 shown is the air flow meter 4 a known structure including a housing 19 that a bypass passage 18 and a flow rate sensor 20 , Part of the intake air chamber coming out of the filter housing 8th in the channel 3 flows, flows into the bypass passage 18 , The flow rate sensor 20 detects a flow rate of the intake flow into the bypass passage 18 ,

The bypass passage 18 is inside the case 19 educated. An inlet connection 22 the bypass passage 18 is to the upstream side of an intake air in the flow direction in the channel 3 open, and an output port 23 the bypass passage 18 is to the downstream side of an intake air in the flow direction in the channel 3 open.

The flow rate sensor 20 is in the bypass passage 18 arranged and outputs an electrical signal, such. A voltage signal, according to the flow rate of the air passing through the bypass passage 18 flows.

As in 1 shown in a passage extending from the filter element 7 to the flow rate measuring section 4 extends, the bent part 15 an inner peripheral space on the inner peripheral side of the bent shape of the bent part 15 is, and an outer circumferential space, that on the outer peripheral side of the bent shape of the bent part 15 lies.

That is, the inner peripheral side is in arrow directions in 1 shown and is set to get under the channel 3 and on the left side of the filter housing 18 in 1 to be located.

The air flow meter or AFM 4 has the inlet connection 22 which is more adjacent to the inner peripheral side of the channel 3 as the outer peripheral side is located. For example, the air flow meter 4 on the canal 3 fastened by being inserted into a mounting hole located in the inner circumferential side of the channel 3 is defined. An opening area of the inlet port 22 of the air flow meter 4 on the inner peripheral side is larger than an opening area or open area of the inlet port 22 the air flow meter on the outer peripheral side with respect to the center of the channel 3 ,

A distributor or distributor 30 is inside the filter housing 8th arranged. The distributor 30 directs intake air into the bypass passage 18 and controls the flow of intake air to the upstream side of the air flow meter 4 to have no impairment or disturbance.

The distributor 30 is located downstream of the filter element 7 in the filter housing 8th and has a plate shape extending along the flow direction of the intake air.

An upstream end X of the distributor 30 is further on the outer peripheral side than a downstream end Y of the distributor 30 , The position of the downstream end Y of the distributor 30 in the flow direction is at the upstream end of the channel 3 , In other words, the position of the downstream end Y of the distributor 30 corresponds to the position of the outlet 10 ,

The position of the upstream end X of the distributor 30 is further on the outer peripheral side than the inner peripheral end of the inlet 22 and is located further on the inner peripheral side than the outer peripheral end of the inlet 22 , That is, the upstream end X is within the range of the inlet 22 in a radial direction defined by connecting the inner peripheral side and the outer peripheral side with each other. This will allow intake air through the manifold 30 in the bypass passage 18 of the air flow meter 4 pulled or sucked.

The distributor 30 has the curved shape between the upstream end X and the downstream end Y, so that the intake air in a predetermined direction corresponding to the curved shape of the distributor 30 is distracted. That is, the distributor 30 has a recess shape that is recessed from the inner peripheral side to the outer peripheral side. The curvature of the curved shape of the distributor 30 is set to become smaller from the upstream side to the downstream side in the flow of the intake air.

According to the first embodiment, the inlet port is located 22 of the air flow meter 4 in the channel 3 rather adjacent to the inner peripheral side than to the outer peripheral side. The distributor 30 , the intake air into the bypass passage 18 and controls the flow of intake air has the curved shape to change the flow direction of the intake air. The curvature of the curved shape is set to become smaller from the upstream side to the downstream side.

Therefore, intake air flows along the manifold 30 Therefore, the flow rate of intake air on the inner peripheral side in the passage extending from the filter element 7 to the air flow meter 4 extends, gets big. Furthermore, through the distributor 30 Turbulence in the flow of intake air can also be reduced.

For this reason, the flow rate of intake air at the inlet port 22 of the air flow meter 4 be made big when the inlet port 22 of the air flow meter 4 on the inner peripheral side in the channel 3 and, accordingly, the flow rate can be accurately measured.

Second Embodiment

A second embodiment will be described with reference to FIG 4 to be discribed.

In the second embodiment, the flow direction of intake air passing through the filter element is set as a primary direction. The filter housing 8th is set to an inner wall surface 31 to have on the inside circumference side of the bent part 15 located, and around an outside wall surface 32 to have on the outer peripheral side of the bent part 15 located. The flow direction of intake air flowing in the duct 3 between the outlet 10 and the air flow meter 4 flows, is set as a secondary direction. The channel 3 is set to an inner wall surface 33 to have on the inside circumference side of the bent part 15 located, and around an outer wall surface 34 to have on the outer peripheral side of the bent part 15 located.

The outer wall surface 32 of the filter housing 8th corresponds to a part of the first wall 8a the first embodiment and the inner wall surface 33 of the filter housing 8th corresponds to a part of the second wall 8b the first embodiment. The up-and-down direction in 4 corresponds to the primary direction or primary direction and the channel 3 extends in the secondary direction or secondary direction.

As in 4 is shown are the inner wall surface 31 and the outer wall surface 32 spaced from each other by a distance of B1 in a direction perpendicular to the primary direction. The inner wall surface 31 and the upstream end X of the manifold 30 are spaced from each other by a distance of B2 in the direction perpendicular to the primary direction. The inner wall surface 33 and outer wall surface 34 are spaced from each other by a distance of A1 in a direction perpendicular to the secondary direction. The inner wall surface 33 and the downstream end Y of the manifold 30 are spaced from each other by a distance of A2 in the direction perpendicular to the secondary direction. Among the preceding definitions is the distributor 30 designed to satisfy the following formula (1). A1 / A2> B1 / B2 ... Formula (1)

Similar to the first embodiment, the curvature of the curved shape of the manifold 30 between the upstream end X and the downstream end Y is set to become smaller from the upstream side to the downstream side in the flow of intake air. The distributor 30 may extend linearly between the upstream end X and the downstream end Y, or may have a curvature different from that of the first embodiment under the condition that the formula (1) is satisfied.

Advantages of the second embodiment will be with reference to 5 to 7 be explained. In a first comparative example, the distributor is 30 eliminated compared to the second embodiment. In a second comparative example, the distributor fulfills 30 a formula of A1 / A2 = B1 / B2. The other conditions of the first comparative example and the second comparative example are set equal to those of the second embodiment for a comparison between the second embodiment and the comparative example.

First, the flow rate of intake air at the inlet port becomes 22 of the air flow meter 4 compared. As in 5 is shown, is a flow rate at the inlet port 22 larger in the second embodiment than in the first comparative example and the second comparative example. The flow velocity is greater in the second comparative example than in the first comparative example, but the flow velocity is greater in the second embodiment than in the second comparative example.

Next will be a change in the output from the air flow meter 4 compared. The axis of an ordinate in 6 represents an index that represents the variation in the output of the air flow meter 4 represents. The index is calculated by a percentage (%) of a fluctuation width σ relative to an average value Q of a detection signal.

As in 6 12, the variation in the output in the second comparative example can be made smaller than in the first comparative example, and can be made smaller in the second embodiment than in the first comparative example and the second comparative example. In particular, in the smaller flow rate region in the channel, the output deviation is smaller in the second embodiment. In contrast, the variation in the output in the first comparative example and the second comparative example is relatively large when the flow rate in the channel is smaller. According to the second embodiment, the variation in the output can be maintained to be smaller in almost the whole area regardless of the flow rate in the channel. That is, in the second embodiment, turbulence in the intake air can be further reduced.

Next, an output characteristic deviation of the air flow meter (AFM) becomes 4 in a case where clogging is caused in the filter element. The axis of an ordinate in 7 represents the output characteristic variation of the air flow meter 4 at the time of clogging under a definition that the output characteristic is set to zero when the filter element in the initial state has no clogging.

As in 7 4, even at the clogging point in time, the second embodiment can achieve approximately the same output characteristic as in the initial state. In contrast, in the first comparative example, there is a tendency in which the output for Clogging time becomes smaller than in the initial state. In addition, in the second comparative example, the output at the clogging timing becomes smaller than in the initial state, although the second comparative example is better than the first comparative example.

In general, foreign matters will be on the inner peripheral side of the filter element 7 Therefore, a flow velocity distribution between the inner peripheral side and the outer peripheral side due to a deviation in the flow of intake air relative to the filter element 7 is generated, and the difference becomes large. For this reason, the output in the first comparative example and the second comparative example becomes smaller. In contrast, according to the second embodiment, the flow velocity on the inner peripheral side can be increased, and therefore the output characteristic does not change at the time even if the filter element 7 is added.

Third Embodiment

A third embodiment will be described with reference to FIG 8th to be discribed.

In the third embodiment, the downstream end Y of the distributor is located 30 downstream of the upstream end of the channel 3 in the flow direction of the intake air, ie the distributor 30 juts into the canal 3 further than the inlet or intake outlet 10 , Accordingly, it may be possible to use the distributor 30 immediately before the air flow meter 4 to arrange, and the advantages of the first embodiment can be further enhanced in the third embodiment.

Fourth Embodiment

A fourth embodiment will be described with reference to FIG 9 to be discribed.

In the fourth embodiment, an auxiliary distributor 37 on the inner peripheral side of the distributor 30 arranged to control the flow of intake air. The auxiliary distributor 37 has a curved shape and the curvature of the curved shape of the auxiliary manifold 37 is set to become smaller from the upstream side to the downstream side in the flow of intake air, similar to the distributor 30 , The auxiliary distributor 37 may extend linearly and may have a curvature different from the curvature of the manifold 30 to have. The number of auxiliary or additional distributors 37 is not limited to one, which is why several auxiliary distributors 37 can be arranged on the inner peripheral side or the outer peripheral side or more auxiliary distributor 37 can be arranged to the distributor 30 between them.

Accordingly, turbulences of the intake air on the inner peripheral side can be further reduced, and the advantages of the first embodiment can be further improved in the fourth embodiment.

Fifth Embodiment

A fifth embodiment will be described with reference to FIG 10 to be discribed.

In the fifth embodiment, the inner wall surface intersect 31 of the filter housing 8th and the inner wall surface 33 of the canal 3 together on a cut piece 38 with a round or chamfered shape. That is, the inner peripheral corner part of the bent part 15 has the round or chamfered shape.

Accordingly, a separation of the flow of intake air at the inner peripheral corner part can be reduced, and therefore the turbulence of intake air can be further reduced, whereby the advantages of the first embodiment in the fifth embodiment can be further improved.

(Modifications)

In the foregoing embodiments, the inlet port is located 22 of the air flow meter 4 adjacent to the inner peripheral side of the channel 3 , Alternatively, at least one of the inlet port 22 and the outlet port 23 adjacent to the inner peripheral side of the channel 3 are located.

For example, if only the outlet port 23 on the inner peripheral side of the channel 3 is located, the flow velocity on the inner peripheral side of the channel 3 through the distributor 30 large. Therefore, intake air easily becomes the bypass passage 18 and the flow rate can be measured accurately. The AFM or air mass meter 4 can on the channel 3 by being inserted into a mounting hole defined in the outer peripheral side wall instead of the inner peripheral side wall.

In the foregoing embodiments, the position of the upstream end X of the distributor is 30 set to go to the area of the inlet 22 in the radial direction, so that intake air to the bypass passage 18 is sucked. Alternatively, the position of the upstream end X may be on the outer peripheral side, at least further than that inner peripheral end of the inlet port 22 , Furthermore, the distributor 30 be arranged such that the upstream end X within the range of the outlet port 23 is in the radial direction.

Such changes and modifications must be understood as within the scope of the present disclosure as defined by the appended claims.

An inlet device has an air filter ( 2 ), a channel ( 3 ) downstream of the air filter and a flow rate measuring section ( 4 ), which is attached to the channel. A filter housing ( 8th ) of the air filter and the channel define a curved part ( 15 ) through which intake air is deflected to reach the flow rate measuring section. A distributor plate ( 30 ) is disposed in the filter housing and upstream of the flow rate measuring section. The bent part has an inner side, which is an inner side of the distributor plate, and an outer side, which is an outer side of the distributor plate, when intake air is deflected into the bent part. At least one of an inlet ( 22 ) and an outlet ( 23 ) of a bypass passage ( 18 ) of the flow rate measuring section is located adjacent to the inner side rather than to the outer side.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• JP 09-88658 A [0002, 0004]
• JP 11-211528 A [0002, 0006]

Claims (6)

An intake device, comprising: an air filter ( 2 ), which purifies intake air to be sucked into an internal combustion engine; a channel ( 3 ), through which the inlet air flows through the air filter ( 2 ) is cleaned; and a flow rate measuring section ( 4 ) located on the canal ( 3 ) is mounted to measure a flow rate of the intake air passing through the duct (Fig. 3 ), the air filter ( 2 ) a filter element ( 7 ) that filters the intake air flowing in a primary direction and a filter housing (FIG. 8th ), in which the filter element ( 7 ), the filter housing ( 8th ) a receiving outlet ( 10 ) through which the intake air flows in a secondary direction different from the primary direction, the duct (FIG. 3 ) with the receiving outlet ( 10 ) of the filter housing ( 8th ), the filter housing ( 8th ) and the channel ( 3 ) a bent part ( 15 ) through which the intake air passing through the filter element ( 7 ) is deflected to the flow rate measuring section (FIG. 4 ), the flow rate measuring section ( 4 ) a bypass passage ( 18 ) into which a part of the intake air from the filter housing ( 8th ) flows, and a flow rate sensor ( 20 ), which detects a flow rate of the intake air, which is in the bypass passage ( 18 ), a distributor plate ( 30 ) in the filter housing ( 8th ) upstream of the flow rate measuring section (FIG. 4 ) is arranged to control a flow of the intake air, and the intake air into the bypass passage passes, the bent part ( 15 ) has a passage extending from the filter element ( 7 ) to the flow rate measuring section ( 4 ), and the passage is set to have an inner side, which is an inner side of the distributor plate, and an outer side, which is an outer side of the distributor plate, when the intake air is deflected in the bent part, and at least one of an inlet ( 22 ) and an outlet ( 23 ) of the bypass passage ( 18 ) is located closer to the inner side than the outer side. Inlet device according to claim 1, wherein the filter housing ( 8th ) an inner peripheral wall surface ( 31 ) adjacent to the inner side and an outer peripheral wall surface ( 32 ) adjacent to the outer side, the inner peripheral wall surface ( 31 ) and the outer peripheral wall surface ( 32 ) of the filter housing are spaced from each other by a distance of B1 in a direction perpendicular to the primary direction, the inner peripheral wall surface (FIG. 31 ) of the filter housing and an upstream end X of the distributor plate ( 30 ) are spaced from each other by a distance of B2 in the direction perpendicular to the primary direction, the channel (FIG. 3 ) an inner peripheral wall surface ( 33 ) adjacent to the inner side and an outer peripheral wall surface ( 34 ) adjacent to the outer side, the inner peripheral wall surface ( 33 ) and the outer peripheral wall surface ( 34 ) of the channel are spaced from each other by a distance of A1 in a direction perpendicular to the secondary direction, the inner peripheral wall surface (Fig. 33 ) of the channel and a downstream end Y of the distributor plate ( 30 ) are spaced apart from each other by a distance of A2 in the direction perpendicular to the secondary direction, and a ratio of A1 / A2> B1 / B2 is satisfied. Inlet device according to claim 1 or 2, wherein the distributor plate ( 30 ) has a curved shape along which the intake air is deflected from the primary direction to the secondary direction and has a curvature set to become smaller from an upstream side to a downstream side in a flow of the intake air. Inlet device according to one of claims 1 to 3, wherein the distributor plate ( 30 ) has a downstream end (Y) in a flow of the intake air, and the downstream end of the distributor plate is located downstream of an upstream end of the channel (5). 3 ) is in a flow of intake air. An inlet device according to any one of claims 1 to 4, further comprising: an auxiliary manifold plate (10). 37 ) located on the inner side or the outer side of the distributor plate ( 30 ) to control a flow of the intake air. Inlet device according to one of claims 2 to 5, wherein the inner peripheral wall surface ( 31 ) of the filter housing and the inner peripheral wall surface ( 33 ) of the channel to each other at a sectional part ( 38 ), which is formed in a round or chamfered shape.

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