EP1811153A2

EP1811153A2 - Air intake system in engine

Info

Publication number: EP1811153A2
Application number: EP07008928A
Authority: EP
Inventors: Hiroshige c/o Kakuda Development Center Akiyama
Original assignee: Keihin Corp
Current assignee: Keihin Corp
Priority date: 2000-11-30
Filing date: 2001-11-21
Publication date: 2007-07-25
Anticipated expiration: 2021-11-21
Also published as: TW544487B; JPWO2002044541A1; EP1347162A4; CN1478175A; JP3935075B2; EP1347162A1; EP1811152A3; EP1811153A3; EP1811152B1; CN1274952C; EP1811153B1; DE60135245D1; WO2002044541A1; EP1347162B1; EP1811152A2

Abstract

A bypass passage (15) is formed in a throttle body (1) and comprised of a bypass inlet bore (15i) and a bypass outlet bore (15o), which open into an upstream portion and a downstream portion of an intake passage (2) respectively with a throttle valve (5) interposed therebetween, and a bypass intermediate portion (15m) which is provided in a device block (11) detachably secured to a mounting surface (10a) formed on the throttle body (1) and is connected at its opposite ends to the bypass inlet bore (15i) and the bypass outlet bore (15o), respectively, and a bypass valve (25), an actuator (28) and an output portion (8b) of a throttle sensor (8) are mounted to the device block (11) to form a bypass valve/sensor assembly (43). The bypass valve/sensor assembly (43) can be fabricated in parallel with the formation of the throttle body (1). Thus, it is possible to provide an enhancement in productivity of an air intake system in an engine.

Description

FIELD OF THE INVENTION

The present invention relates to an air intake system in an engine, and particularly, to an improvement in an air intake system in an engine, comprising a bypass passage bypassing a throttle valve and connected to an intake passage in a throttle body, and an actuator which is connected to a bypass valve for opening and closing the bypass passage and is operable to open and close the bypass valve.

BACKGROUND ART

Such an air intake system in an engine is conventionally known, for example, as disclosed in Japanese Utility Model Publication No.6-45654 .
In such conventionally known air intake system in the engine, the entire bypass passage is defined in the throttle body, and the bypass valve and actuator are mounted to the throttle valve. Therefore, a complicated working is required for the throttle body, and all parts must be assembled to the throttle body itself. Thus, the known air intake system is accompanied by disadvantages such as a poor assemblability.

DISCLOSURE OF THE INVENTION

It is an object of the present invention to provide an automatic starting system for a carburetor of the above-described type, wherein the above disadvantages are solved.
To achieve the above object, according to a first aspect and feature of the present invention, there is provided an air intake system in an engine, comprising a bypass passage bypassing a throttle valve and connected to an intake passage in a throttle body, and an actuator which is connected to a bypass valve for opening and closing the bypass passage and is operable to open and close the bypass valve, characterized in that the bypass passage is formed in the throttle body and comprised of a bypass inlet bore and a bypass outlet bore, which open into an upstream portion and a downstream portion of the intake passage respectively with the throttle valve interposed therebetween, and a bypass intermediate portion which is provided in a device block detachably secured to a mounting surface formed on the throttle body and is connected at opposite ends thereof to the bypass inlet bore and the bypass outlet bore, respectively, and the bypass valve, the actuator and an output portion of a throttle sensor for detecting an opening degree of the throttle valve are mounted to the device block to form a bypass valve/sensor assembly.
With the first feature, the number of working steps for the throttle body is reduced, and the bypass valve/sensor assembly can be fabricated in parallel to the formation of the throttle body, leading to an enhancement in productivity. Moreover, if the device block is removed from the throttle body, the maintenance of the bypass passage, the bypass valve, the throttle sensor and the like can be carried out easily. Furthermore, it is possible to simply provide an air intake system of an engine having a different specification while using the same throttle body by changing the specifications of the bypass valve, the actuator, the throttle sensor and the like in the device block, thereby enhancing the mass-productivity of the throttle body.
According to a second aspect and feature of the present invention, in addition to the first feature, the bypass inlet bore and the bypass outlet bore are disposed in parallel to each other.
With the second feature, the bypass inlet bore and the bypass outlet bore can be made at a stroke from the side of the mounting surface by a multi-spindle drilling machine or by a plurality of parallel core pins in a casting process, leading to a shortened fabricating time.
According to a third aspect and feature of the present invention, in addition to the first feature, the bypass inlet bore and the bypass outlet bore are disposed in parallel to a shaft bore for a valve shaft of the throttle valve.
With the third feature, the bypass inlet bore and the bypass outlet bore can be made at a stroke from the side of the mounting surface along with the shaft bore for the valve shaft by a multi-spindle drilling machine or by a plurality of parallel core pins in a casting process, leading to a shortened fabricating time.
According to a fourth aspect and feature of the present invention, in addition to any of the first to third features, a bottom surface of a housing integrally formed on the throttle body is the mounting surface, and the device block accommodated in the housing is integrally formed with a collar which water-tightly closes an open surface of the housing.
With the fourth feature, the closing of the open surface of the housing can be performed simultaneously with the mounting of the device block to the mounting surface, and an exclusive lid for closing the open surface is not required, which can contribute to the simplification of the construction.
According to a fifth aspect and feature of the present invention, in addition to any of the first to fourth features, the device block is made of synthetic resin.
With the fifth feature, the bypass intermediate portion can be made simultaneously with the formation of the device block of the synthetic resin, thereby shortening the fabricating time. Moreover, the weight of the entire air intake system can be reduced by employing the lightweight device block made of the synthetic resin.
According to a sixth aspect and feature of the present invention, there is provided an air intake system in an engine, comprising a bypass passage bypassing a throttle valve and connected to an intake passage in a throttle body, and a bypass valve incorporated in the bypass passage for controlling the amount of intake air in the bypass passage by cooperation with a metering bore provided in the intermediate portion of the bypass passage, characterized in that the metering bore is disposed so as to be located above a bypass inlet bore and a bypass outlet bore of the bypass passage, which open into an upstream portion and a downstream portion of the intake passage, respectively, either when the intake passage is disposed horizontally and when the intake passage is disposed with an inlet thereof turned upwards.
With the sixth feature, when the air intake system is used as any of a side-draft type and a downdraft type, the metering bore occupies a position above the bypass inlet bore and the bypass outlet bore. Therefore, even if a fluid foreign matter such as oil and water in a blow-by gas or an EGR gas enters the bypass passage, the foreign matter naturally flows down toward the bypass inlet bore and the bypass outlet bore after stoppage of the operation of the engine and hence, can be prevented from remaining deposited on a peripheral edge of the metering bore. Therefore, it is possible to previously avoid the failure of the operation and the deviation of the opening degree of the bypass valve due to the freezing or accumulation of the foreign matter on the peripheral edge of the metering bore. In addition, the intake system has general-purpose properties as described above and hence, not only the degree of freedom of the layout thereof can be increased, but also the mass-productivity can be enhanced to provide a reduction in cost.
According to a seventh aspect and feature of the present invention, in addition to the sixth feature, the bypass passage is defined in the throttle body and comprised of the bypass inlet bore and the bypass outlet bore, which open into the upstream portion and the downstream portion of the intake passage respectively with the throttle valve interposed therebetween, and a bypass intermediate portion which is provided in the device block detachably secured to a mounting surface formed on the throttle body and is connected at opposite ends thereof to the bypass inlet bore and the bypass outlet bore and has the metering bore therein at an intermediate location, and the bypass valve and an actuator for opening and closing the bypass valve are mounted to the device block.
With the seventh feature, the number of working steps for the throttle body can be reduced, and an assembly comprising the device block, the bypass valve and the actuator can be fabricated in parallel with the formation of the throttle body, leading to an enhancement in productivity. Moreover, if the device block is removed from the throttle body, the maintenance of the bypass passage, the bypass valve and the like can be carried out easily. Furthermore, it is possible to simply provide an air intake system of an engine having a different specification while using the same throttle body by changing the specifications of the bypass valve and the step motor in the device block, thereby enhancing the mass-productivity of the throttle body.
According to an eighth aspect and feature of the present invention, in addition to the seventh feature, the device block is made of synthetic resin.
With the eighth feature, the bypass intermediate portion can be formed simultaneously with the formation of the device block of the synthetic resin and thus, it is easy to define the bypass passage. Moreover, the weight of the entire air intake system can be reduced by employing the lightweight device block made of the synthetic resin.
According to a ninth aspect and feature of the present invention, there is provided an air intake system in an engine, comprising a bypass passage bypassing a throttle valve and connected to an intake passage in a throttle body, and an actuator which is connected to a bypass valve for opening and closing the bypass passage and is operable to open and close the bypass valve, characterized in that the bypass passage is defined in the throttle body and comprised of a bypass inlet bore and a bypass outlet bore, which open into an upstream portion and a downstream portion of the intake passage respectively with the throttle valve interposed therebetween, and a bypass intermediate portion which is defined in a device block detachably secured to a mounting surface formed on the throttle body and is connected at opposite ends thereof to the bypass inlet bore and the bypass outlet bore, respectively, the bypass inlet bore and the bypass outlet bore being disposed in parallel to an shaft bore provided in the throttle body for a valve shaft of the throttle valve, and the bypass valve and the actuator are mounted to the device block.
With the ninth feature, the number of working steps for the throttle body is reduced, and an assembly comprising the device block, the bypass valve and the actuator can be fabricated in parallel with the formation of the throttle body, which can contribute to an enhancement in productivity. Particularly, the bypass inlet bore and the bypass outlet bore opening into the mounting surface of the throttle body are disposed in parallel to the shaft bore for the throttle valve and hence, these bores can be made at a stroke from the side of the mounting surface by a multi-spindle drilling machine or by a plurality of parallel core pins in a casting process, leading to a shortened fabricating time.
Moreover, if the device block is removed from the throttle body, the maintenance of the bypass passage, the bypass valve the throttle sensor and the like can be carried out easily.
Furthermore, it is possible to simply provide an air intake system of an engine having a different specification while using the same throttle body by changing the specifications of the bypass valve, the step motor and the like in the device block, thereby enhancing the mass-productivity of the throttle body.
According to a tenth aspect and feature of the present invention, in addition to the ninth feature, the bypass intermediate portion is provided with a metering bore for controlling the amount of intake air in the bypass passage by cooperation with the bypass valve, the metering bore being disposed so as to be located above the bypass inlet bore and the bypass outlet bore, either when the intake passage is disposed horizontally and when the intake passage is disposed with an inlet thereof turned upwards.
With the tenth feature, when the air intake system is used as any of a side-draft type in which the intake passage is disposed horizontally and a down-draft type in which the intake passage is disposed with its inlet turned upwards, the metering bore occupies a position above the bypass inlet bore and the bypass outlet bore. Therefore, even if a fluid foreign matter such as oil and water in a blow-by gas or an EGR gas enters the bypass passage, the foreign matter naturally flows down toward the bypass inlet bore and the bypass outlet bore and into the intake passage after stoppage of the operation of the engine and hence, cannot remain deposited on a peripheral edge of the metering bore. Therefore, it is possible to previously avoid the failure of the operation and the deviation of the opening degree of the bypass valve due to the freezing or accumulation of the foreign matter on the peripheral edge of the metering bore.
According to an eleventh aspect and feature of the present invention, in addition to the ninth or tenth feature, the device block is made of synthetic resin.
With the eleventh feature, the bypass intermediate portion can be formed simultaneously with the formation of the device block of the synthetic resin, thereby shortening the fabricating time. Moreover, the weight of the entire air intake system can be reduced by employing the lightweight device block made of the synthetic resin.
Incidentally, the actuator corresponds to a step motor 28 in an embodiment of the present invention which will be described hereinafter, and the output portion of the throttle sensor corresponds to a pickup coil 8b.
The above and other objects, features and advantages of the invention will become apparent from the following description of the preferred embodiment taken in conjunction with the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

Fig.1 is a side view of an air intake system in an engine according to the present invention; Fig. 2 is a sectional view take along a line 2-2 in Fig. 1; Fig. 3 is a sectional view take along a line 3-3 in Fig. 1; Fig. 4 is a sectional view take along a line 4-4 in Fig.3; Fig. 5 is a sectional view take along a line 5-5 in Fig.4; Fig.6 is a sectional view take along a line 6-6 in Fig.3; Fig.7 is a sectional view take along a line 7-7 in Fig. 3; Fig. 8 is a sectional view take along a line 8-8 in Fig. 3; and Fig.9 is an exploded perspective view of the air intake system.

BEST MODE FOR CARRYING OUT THE INVENTION

Referring first to Figs.1 and 2, a throttle body 1 has an intake passage 2 extending horizontally. An inlet in the intake passage 2 is funnel-shaped and connected to an air cleaner (not shown), and an outlet of the intake passage 2 is connected to an intake port (not shown) of an engine. A pair of bosses 3 and 3' having shaft bores 4 and 4' perpendicular to the intake passage 2 are formed on opposite sides of an intermediate portion of the throttle body 1, respectively and a butterfly throttle valve 5 for opening and closing the intake passage 2 is secured to a valve shaft 6 rotatably carried in the shaft bores 4 and 4'. A throttle drum 7 is secured to one end of the valve shaft 6 and connects an actuating wire 9 connected to a throttle-actuating member (not shown), and a return spring 24 for biasing the throttle valve 5 in a closing direction is connected to the throttle drum 7. A rotor 8a of a throttle sensor 8 for detecting an opening degree of the throttle valve 5 is secured to the other end of the valve shaft 6. Reference character 44 is a bracket for supporting an outer wire for guiding the actuating wire 9. The bracket 44 is screwed to the throttle body 1.
As shown in Figs. 2 and 9, a housing 10 is integrally formed on one side of the throttle body 1. The other boss 3' protrudes on a bottom surface 10a of the housing 10, and the shaft bore 4' in the boss 3' and the bottom surface 10a are disposed to extend perpendicularly to each other. The bottom surface 10a of the housing 10 is a mounting surface, and a device block 11 accommodated in the housing 10 is secured to the mounting surface 10a by a plurality of bolts 12, 12. The device block 11 is integrally formed with a collar 11c for closing an open surface of the housing 10, and a seal member 13 is interposed between joint surfaces of the collar 11c and the housing 10 for sealing the inside of the housing 10 water-tightly.
A rotor-accommodating bore 14 is defined in a surface of the device block 11 opposed to the mounting surface 10a, and the other boss 3' and the rotor 8a are accommodated in the accommodating bore 14.
As shown in Figs.3 to 5, 7 and 8, a bypass passage 15 is defined to extend from the throttle body 1 to the device block 11. The bypass passage 15 is comprised of a bypass inlet bore 15i provided in the throttle body 1 to permit the intake passage 2 and the mounting surface 10a to communicate with each other at a location upstream of the throttle valve 5, a bypass outlet bore 15o provided in the throttle body 1 to permit the intake passage 2 and the mounting surface 10a to communicate with each other at a location downstream of the throttle valve 5, and a bypass intermediate portion 15m provided in the device block 11 to permit the bypass inlet bore 15i and the bypass outlet bore 15o to communicate with each other. Therefore, the bypass passage 15 is connected to the intake passage 2 around the throttle valve 5.
As best shown in Fig.5, the bypass intermediate portion 15m of the device block 11 is comprised of an upstream groove 16 and a downstream groove 17 defined in an inner surface of the device block 11 opposed to the mounting surface 10a, so that they communicate with the bypass inlet bore 15i and the bypass outlet bore 15o, respectively, a through-bore 18 connected to one end of the upstream groove 16, a valve guide bore 19 rising upwards from the through-bore 18, and a metering bore 20 permitting an intermediate portion of the valve guide bore 19 to communicate with the other end of the downstream groove 17. In this case, the upstream groove 16 is disposed inclined vertically, and the bypass inlet bore 15i opens into a lower end of the upstream groove 16 (see Fig.7), while the through-bore 18 opens into an upper end of the upstream groove 16. The downstream groove 17 is longer than the upstream groove 16 and defined so that it extends substantially horizontally from the side of the valve guide bore 19 and is bent downwards midway, and the bypass outlet bore 150 opens into a lower end of the downstream groove 17. In this manner, the metering bore 20 is disposed above the bypass inlet bore 15i and the outlet bore 15o and on the side of the inlet of the intake passage 2. Therefore, either when the intake passage 2 is disposed horizontally and when the intake passage 2 is disposed with its inlet turned upwards, as in the illustrated embodiment, the metering bore 20 occupies a position above the bypass inlet bore 15i and the bypass outlet bore 15o. In other words, the bypass passage 15 has a shape such that it extends downwards toward the bypass inlet bore 15i and the bypass outlet bore 15o from the metering bore 20 always serving as an apex.
As best shown in Figs.3 and 8, a boost vacuum take-out bore 21 for taking-out an intake vacuum, i.e., a boost vacuum from the intake passage 2 downstream from the throttle valve 5 is provided to extend in the throttle body 1 and the device block 11. The boost vacuum take-out bore 21 is comprised of a vacuum introducing bore 21a provided in the throttle body 1 to permit the intake passage 2 and the mounting surface 10a to communicate with each other at a location downstream of the throttle valve 5, and a vacuum guide bore 21b provided in the device block 11 bent from the vacuum introducing bore 21a to extend upwards, while communicating with the vacuum introducing bore 21a. A boost vacuum sensor 23 is mounted to the device block 11 with its sensing portion facing an upper end of the vacuum guide bore 21b.
All of the bypass inlet bore 15i, the bypass outlet bore 15o and the vacuum introducing bore 21a are disposed in parallel to the shaft bore 4'.
A seal member 22 is interposed between the mounting surface 10a of the housing 10 and the inner surface of the device block 11, which are bonded to each other, to surround various portions of the bypass passage 15 and the boost vacuum take-out bore 21.
Referring to Figs.3 to 6, a piston-type bypass valve 25 is slidably received in the valve guide bore 19. The bypass valve 25 has a hollow portion 25a with its lower surface opening toward the through-bore 18. A metering groove 26 is provided in a sidewall of the hollow portion 25a for controlling the flow rate of air in the bypass passage 15 by cooperation with the metering bore 20. The metering groove 26 comprises a wider section 26a which opens into a lower end of the bypass valve 25, and a narrower section 26b connected to an upper end of the wider section 26a. The metering groove 26 is capable of being moved upwards and downwards between a high-opening degree position where an upper portion of the wider section 26a faces the metering bore 20, and a low-opening degree position where only the narrower section 26b faces the metering bore 20. In this case, a positioning projection 27 is formed on the device block 11 to come into engagement the wider section 26a in order to prevent the rotation of the bypass valve 25.
A step motor 28 is disposed on the device block 11 above and coaxially with the bypass valve 25. The step motor 28 has a rotor 29 integrally provided with a threaded shaft 30 extending downwards. The threaded shaft 30 is threadedly engaged into a threaded bore 31 defined in the central portion of the bypass valve 25.
Further, a mounting recess 32 is defined in the device block 11 to adjoin the rotor-accommodating bore 14 and the upstream groove 16 with thin partition walls 11a and 11b respectively interposed therebetween, as shown in Fig.3, and a sensor holder 35 is inserted into the mounting recess 32. Retained on the sensor holder 35 are a pickup coil 8b opposed to the rotor 8a in the rotor-accommodating bore 14 with the partition wall 11a interposed therebetween, and an intake air temperature sensor 34 for detecting a temperature within the upstream groove 16 through the partition wall 11b. The pickup coil 8b forms a throttle sensor 8 for electrically detecting an opening degree of the throttle valve 5 by cooperation with the rotor 8a.
Information regarding operational conditions of the engine is input to an electronic control unit 36 connected to the step motor 28, such as a throttle valve opening degree θth, a boost vacuum Pb and a temperature of an intake air Ta detected respectively by the throttle sensor 8, the boost vacuum sensor 23 and the intake air temperature sensor 34 and an engine temperature Te detected by an engine cooling-water temperature sensor (not shown).
The sensor holder 35 is integrally provided with first and second retaining arms 35a and 35b to urge the step motor 28 and the boost vacuum sensor 23 against the housing 10 from the above to retain them. First and second locking claws 38a and 38b are formed on the first and second retaining arms 35a and 35b to come into resilient engagement in an engage recess 37a and an engage bore 37b in the device block 11. Therefore, the sensor holder 35 is detachably mounted to the device block 11 by the engagement of the first and second locking claws 38a and 38b in the engage recess 37a and the engage bore 37b, whereby the step motor 28, the boost vacuum sensor 23, the pickup coil 8b and the intake air temperature sensor 34 are retained all together in the device block 11.
Protruding pieces 40 and 41 are integrally formed on the device block 11 and the sensor holder 35 respectively to extend through the bottom of the housing 10, while defining a wire guide passage 39 by cooperation with each other, and various lead wires 42, 42 connected to the step motor 28, the pickup coil 8b, the boost vacuum sensor 23 and the intake air temperature sensor 34 are drawn out of the housing 10 through the wire guide passage 39.
A bypass valve/sensor assembly 43 is formed by mounting the bypass valve 25, the step motor 28, the pickup coil 8b, the boost vacuum sensor 23 and the intake air temperature sensor 34 to the device block 11 in the above-described manner.
The operation of this embodiment will be described below.
When the throttle valve 5 is closed fully, the electronic control unit 36 calculates an amount of current supplied to the step motor 28, carries out the supplying of current and rotates the rotor 29 in a normal or reverse direction along with the threaded shaft 30 in order to provide an optimal opening degree of the bypass valve 25 corresponding to the engine operational conditions during starting, first idling and usual idling operations of the engine, during operation of engine brake and the like, based on the information regarding the engine operational conditions such as the throttle valve opening degree θth, the boost vacuum Pb, the intake air temperature Ta and the engine temperature Te, input as described above. When the threaded shaft 30 is rotated or reversed, the non-rotatable bypass valve 25 is moved upwards or downwards along the valve guide bore 19.
When the bypass valve 25 is moved upwards to occupy a high-opening degree position, the wider portion 26a of the metering groove 26 in the bypass valve 25 is exposed to the metering bore 20 of the bypass passage 15. Therefore, the amount of the air flowing through the bypass passage 15 into the engine can be controlled to a relatively large amount in accordance with an area of wider portion 26a opening into the metering bore 20, thereby accommodating the starting or idling operation of the engine. When the bypass valve 25 is moved downwards to occupy a low-opening degree position, the narrower portion 26b of the metering groove 26 in the bypass valve 25 is exposed to the metering bore 20. Therefore, the amount of the intake air flowing through the bypass passage 15 can be controlled to a relatively small amount in accordance with an area of narrower portion 26b opening into the metering bore 20, thereby accommodating the usual idling operation of the engine or the engine brake.
If the throttle valve 5 is opened, an amount of the intake air corresponding to the opening degree is supplied through the intake passage 2 to the engine, and the operation of the engine is shifted to an output operational region.
In such air intake system, the bypass valve/sensor assembly 43 is formed by mounting the bypass valve 25, the step motor 28, the pickup coil 8b, the boost vacuum sensor 23 and the intake air temperature sensor 34 to the device block 11 detachably mounted to the housing 10 integral with the throttle body 1. Therefore, the number of working steps for the throttle body 1 can be reduced, and the bypass valve/sensor assembly 43 can be fabricated in parallel with the formation of the throttle body 1, leading an enhancement in productivity. Moreover, the maintenance of the bypass passage 15, the bypass valve 25, the throttle sensor 8 and the like can be carried out by removing the device block 11 from the throttle body 1. Furthermore, it is possible to simply provide an air intake system of an engine having a different specification while using the same throttle body 1 by changing the specifications of the bypass valve 25, the step motor 28 and the various sensors 8, 23 and 34 in the device block 11, thereby enhancing the mass-productivity of the throttle body 1.
In addition, the bypass passage 15 is comprised of the bypass inlet bore 15i and the bypass outlet bore 15o provided in the throttle body 1, and the bypass intermediate portion 15m defined in the device block 11 made of the synthetic resin and connected at its opposite ends to the bypass inlet bore 15i and the bypass outlet bore 15o. In this case, the bypass inlet bore 15i, the bypass outlet bore 15o and the vacuum introducing bore 21a are disposed in parallel to the shaft bore 4' carrying the valve shaft 6 of the throttle valve 5. Therefore, the shaft bore 4', the bypass inlet bore 15i, the bypass outlet bore 15o and the vacuum introducing bore 21a can be made at a stroke from the side of the mounting surface 10a by a multi-spindle drilling machine or by a plurality of parallel core pins in a casting process. Moreover, the bypass intermediate portion 15m can be made simultaneously with the formation of the device block 11 made of the synthetic resin and hence, the fabricating time can be shortened largely. Further, the weight of the entire intake system can be reduced by employing the lightweight device block 11 of the synthetic resin.
In the bypass passage 15, the metering bore 20 is disposed above the bypass inlet bore 15i and the bypass outlet bore 15o and on the side of the inlet of the intake passage 2. Therefore, not only when the throttle body 1 is used as a side-draft type with the intake passage 2 disposed horizontally, as in the illustrated embodiment, but also when the throttle body 1 is used as a down-draft type with the inlet of the intake passage. 2 turned upwards, the metering bore 20 occupies a position above the bypass inlet bore 15i and the bypass outlet bore 15o, and the bypass passage 15 extends downwards toward the bypass inlet bore 15i and the bypass outlet bore 15o with the metering bore 20 always serving as the apex. Therefore, even if a fluid foreign matter such as oil and water in a blow-by gas or an EGR gas supplied from the inlet of the intake passage 2 enters the bypass passage during operation of the engine, the foreign matter naturally flows down toward the bypass inlet bore 15i and the bypass outlet bore 15o into the intake passage 2 after stoppage of the operation of the engine and hence, cannot remain deposited on the peripheral edge of the metering bore 20. Therefore, it is possible to previously avoid the failure of the operation and the deviation of the opening degree of the bypass valve 25 due to the freezing or accumulation of the foreign matter on the peripheral edge of the metering bore 20.
In addition, the intake system has general-purpose properties as described above and hence, the degree of freedom of the layout thereof can be increased, and moreover, the mass-productivity can be enhanced to provide a reduction in cost.
Further, the device block 11 coupled to the mounting surface 10a of the housing 10 by the bolts 12, 12 is integrally formed with the collar 11c closing the open surface of the housing 10. Therefore, the open surface of the housing 10 can be closed simultaneously with the mounting of the device block 11 to the mounting surface 10a and thus, an exclusive lid for closing the open surface is not required, which can contribute to the simplification of the construction.
The present invention is not limited to the above-described embodiment, and various modifications in design may be made without departing from the spirit and scope of the invention defined in claims.

Claims

An air intake system in an engine, comprising a bypass passage (15) bypassing a throttle valve (5) and connected to an intake passage (2) in a throttle body (1), and a bypass valve (25) incorporated in said bypass passage (15) for controlling the amount of intake air in said bypass passage (15) by cooperation with a metering bore (20) provided in the intermediate portion of said bypass passage (15),
characterized in that said metering bore (20) is disposed so as to be located above a bypass inlet bore (15i) and a bypass outlet bore (15o) of said bypass passage (15), which open into an upstream portion and a downstream portion of said intake passage (2), respectively, either when said intake passage (2) is disposed horizontally and when said intake passage (2) is disposed with an inlet thereof turned upwards.
An air intake system in an engine according to claim 1, wherein
said bypass passage (15) is defined in said throttle body (1) and comprised of said bypass inlet bore (15i) and said bypass outlet bore (15o), which open into the upstream portion and the downstream portion of said intake passage (2) respectively with said throttle valve (5) interposed therebetween, and a bypass intermediate portion (15m) which is provided in said device block (11) detachably secured to amounting surface (10a) formed on said throttle body (1) and is connected at opposite ends thereof to said bypass inlet bore (15i) and said bypass outlet bore (15o) and has said metering bore (20) therein at an intermediate location, and said bypass valve (25) and an actuator (28) for opening and closing said bypass valve (25) are mounted to said device block (11).
An air intake system in an engine according to claim 2, wherein
said device block (11) is made of synthetic resin.
(amended) An air intake system in an engine, comprising a bypass passage (15) bypassing a throttle valve (5) and connected to an intake passage (2) in a throttle body (1), and an actuator (28) which is connected to a bypass valve (25) for opening and closing said bypass passage (15) and is operable to open and close said bypass valve (25),
characterized in that said bypass passage (15) is formed in said throttle body (1) and comprised of a bypass inlet bore (15i) and bypass outlet bore (150), which open into an upstream portion and a downstream portion of the intake passage (2) respectively with said throttle valve (5) interposed therebetween, and a bypass intermediate portion (15m) which is provided in a device block (11) detachably secured to a mounting surface (10a) formed on said throttle body (1) and is connected at opposite ends thereof to said bypass inlet bore (15i) and said bypass outlet bore (15o), respectively, and said bypass valve (25), said actuator (28) and an output portion (8b) of a throttle sensor (8) for detecting an opening degree of said throttle valve (5) are mounted to said device block (11) to form a bypass valve/sensor assembly (43).
An air intake system in an engine according to claim 4, wherein
said bypass inlet bore (15i) and said bypass outlet bore (15o) are disposed in parallel to each other.
An air intake system in an engine according to claim 4,
wherein
said bypass outlet bore (15i) and said bypass outlet bore (15o) are disposed in parallel to a shaft bore (4') for a valve shaft (6) of said throttle valve (5).
An air intake system in an engine according to any of claims 4 to 6, wherein
a bottom surface of a housing (10) integrally formed on said throttle body (1) is said mounting surface (10a), and said device block (11) accommodated in said housing (10) is integrally formed with a collar (11c) which water-tightly closes an open surface of said housing (10).
An air intake system in an engine according to any of claims 4 to 7, wherein said device block (11) is made of synthetic resin.
An air intake system in an engine, comprising a bypass passage (15) bypassing a throttle valve (5) and connected to an intake passage (2) in a throttle body (1), and an actuator (28) which is connected to a bypass valve (25) for opening and closing said bypass passage (25) and is operable to open and close said bypass valve (25),
characterized in that said bypass passage (15) is defined in said throttle body (1) and comprised of a bypass inlet bore (15i) and a bypass outlet bore (15o), which open into an upstream portion and a downstream portion of said intake passage (2) respectively with said throttle valve (5) interposed therebetween, and a bypass intermediate portion (15m) which is defined in a device block (11) detachably secured to a mounting surface (10a) formed on said throttle body (1) and is connected at opposite ends thereof to said bypass inlet bore (15i) and said bypass outlet bore (15o), respectively, said bypass inlet bore (15i) and said bypass outlet bore (15) being disposed in parallel to an shaft bore (4') provided in said throttle body (1) for a valve shaft (6) of said throttle valve (5), and said bypass valve (25) and said actuator (28) are mounted to said device block (11),
An air intake system in an engine according to claim 9, wherein
said bypass intermediate portion (15m) is provided with a metering bore (20) for controlling the amount of an intake air in said bypass passage (15) by cooperation with said bypass valve (25), said metering bore (20) being disposed so as to be located above said bypass inlet bore (15i) and said bypass outlet bore (15o), either when said intake passage (2) is disposed horizontally and when said intake passage (2) is disposed with an inlet thereof turned upwards.
An air intake system in an engine according to claim 9 or 10, wherein
said device block (11) is made of synthetic resin.