JP2010196633A - Intake device structure for saddle ride type vehicle - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To compactly arrange an intake pipe comprising a main pipe connected to a throttle body and a branch pipe branching to multiple cylinders from the main pipe, in an intake device structure for a saddle ride type vehicle. <P>SOLUTION: In the intake device structure for the saddle ride type vehicle 1 including a multi-cylinder engine 20, an air cleaner box 60 purifying intake air supplied to the engine 20, and an intake pipe 70 comprising the main pipe connected to the throttle body 91 connected to the air cleaner box 60, and branch pipes 71, 72, 73 branching to each cylinder from the main pipe, a stepped part 64 is provided on the air cleaner box 60 and the main pipe is disposed at the stepped part 64. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to an intake device structure for a saddle-ride type vehicle.

2. Description of the Related Art Conventionally, there has been disclosed an intake device structure for a motorcycle (saddle-ride type vehicle) equipped with an intake manifold that branches from a single intake pipe connected to a throttle body to a plurality of intake pipes. (For example, refer to Patent Document 1).
JP 2005-171864 A

In the conventional intake device structure of a saddle-ride type vehicle, a plurality of intake pipes branching from one throttle body can be connected to a plurality of cylinders, and a single cylinder can be used for multiple cylinders. By the way, when an intake device structure having such an intake pipe is mounted on a saddle-ride type vehicle, it is desirable to arrange it as compact as possible.
The present invention has been made in view of the above-described circumstances. In an intake device structure of a saddle-ride type vehicle, an intake pipe including a main pipe connected to a throttle body and a branch pipe branched from the main pipe to a multi-cylinder is provided. The purpose is to enable a compact arrangement.

The present invention includes a multi-cylinder internal combustion engine and an air cleaner that purifies intake air supplied to the internal combustion engine, and a main pipe connected to a throttle body connected to the air cleaner, and branches from the main pipe to each cylinder. In an intake device structure for a saddle-ride type vehicle having an intake pipe composed of a branch pipe, the air cleaner is provided with a stepped portion or a recessed portion, and the main pipe is disposed in the stepped portion or the recessed portion. An intake device structure for a riding type vehicle is provided.
According to this configuration, in the intake pipe including the main pipe connected to the throttle body and the branch pipe branched from the main pipe to each cylinder, the main pipe is disposed in the step portion or the recess of the air cleaner. The intake pipe can be arranged in a compact manner by providing it inside.

In the above configuration, a connecting member that connects the air cleaner and the throttle body may be provided at an end of the stepped portion or the recessed portion in the vehicle width direction.
According to this configuration, the connecting member is provided at the end portion in the vehicle width direction, and the connecting member can be accessed from the vehicle width direction. Therefore, the air cleaner and the throttle body can be easily connected by the connecting member, and the assembling property is improved. good. Further, since the connecting member is provided at the end in the vehicle width direction, the intake pipe can be extended to the side of the connecting member on the side opposite to the end, and the intake pipe can be lengthened. . Thereby, the characteristic of an internal combustion engine can be improved, for example, the low speed torque of an internal combustion engine can be improved.

In addition, the upstream end of the main pipe intake flow is located in the center in the vehicle width direction, and the intake pipe to each cylinder has the same distance from the upstream end to the downstream end of the branch pipe to each cylinder. It may be provided as follows.
In this case, since the upstream end portion of the main pipe is located in the center in the vehicle width direction, the throttle body connected to the upstream side of the main pipe can also be provided in the center in the vehicle width direction, and the arrangement of the throttle body is easy. In addition, since the upstream end of the main pipe is located in the center in the vehicle width direction and is not biased to one side in the vehicle width direction, the distance from the upstream end of the main pipe to the downstream end of the branch pipe to each cylinder is easy. It can be provided so as to be approximately equal to. Thus, intake air can be supplied to each cylinder at an appropriate timing, and intake air can be supplied uniformly to each cylinder.

Further, a cross member of the vehicle body frame may be provided along the step of the air cleaner or the corner of the recess.
In this case, since the air cleaner can be supported by placing the air cleaner on the cross member, the assemblability of the air cleaner is good. Moreover, since the air cleaner is supported by the cross member and is stable, the connecting member can be easily attached to the air cleaner.

Furthermore, the side surface of the throttle body may overlap the vehicle body frame in a side view.
In this case, the throttle body can be protected by the vehicle body frame that overlaps the side surface of the throttle body.

  In the intake device structure for a saddle-ride type vehicle according to the present invention, in the intake pipe including the main pipe connected to the throttle body and the branch pipe branching from the main pipe to each cylinder, the main pipe is disposed in the step or recess of the air cleaner. Therefore, the intake pipe can be arranged compactly by providing the intake pipe on the inner side of the air cleaner.

Further, since the connecting member provided at the end in the vehicle width direction can be accessed from the width direction of the vehicle, the air cleaner and the throttle body can be easily connected by the connecting member, and the assemblability is good. Further, the intake pipe can be extended to the opposite side of the connecting member provided at the end in the vehicle width direction, and the intake pipe can be lengthened. Thereby, the characteristic of an internal combustion engine can be improved, for example, the low speed torque of an internal combustion engine can be improved.
Further, since the upstream end portion of the main pipe is located in the center in the vehicle width direction, the throttle body connected to the upstream side of the main pipe can also be provided in the center in the vehicle width direction, and the arrangement of the throttle body is easy. Also, since the upstream end of the main pipe is located in the center in the vehicle width direction and is not biased to one side in the vehicle width direction, the distance from the upstream end to the downstream end of the branch pipe to each cylinder is It can be provided so as to be substantially equal. Thus, intake air can be supplied to each cylinder at an appropriate timing, and intake air can be supplied uniformly to each cylinder.

Further, since the air cleaner can be supported by being mounted on the cross member, the assemblability of the air cleaner is good. Moreover, since the air cleaner is supported by the cross member and is stable, the connecting member can be easily attached to the air cleaner.
Furthermore, the throttle body can be protected by the vehicle body frame overlapping the side surface of the throttle body.

Hereinafter, a saddle-ride type vehicle according to an embodiment of the present invention will be described with reference to the drawings. In the following description, the up / down, front / rear, and left / right directions are directions seen from the driver.
FIG. 1 is a left side view of a saddle-ride type vehicle 1 according to an embodiment of the present invention. FIG. 2 is a perspective view of the saddle riding type vehicle 1 as viewed from the left front.
As shown in FIGS. 1 and 2, the body frame F of the saddle-ride type vehicle 1 supports a front fork 2 that pivotally supports a front wheel WF and a steering handle 3 connected to the front fork 2 so as to be steerable. A head pipe 4 is provided at the front end. The rear wheel WR is suspended so as to be swingable up and down by a swing arm 50 supported at a middle portion in the front-rear direction of the body frame F.

As shown in FIG. 2, the vehicle body frame F is connected to the head pipe 4, a pair of left and right main frames 6 connected to the upper part of the head pipe 4 and extending rearward, and connected to the lower part of the head pipe 4. A pair of left and right down pipes 7 extending downward and a U-shaped subframe 8 connected to the rear end of the main frame 6 to connect the left and right main frames 6 are provided. The vehicle body frame F is a frame configured by combining pipes.
The main frame 6 includes an upper frame portion 6a extending rearward and downward from an upper portion of the head pipe 4 provided at the center in the vehicle width direction, a horizontal portion 6b extending substantially horizontally from a bent portion at the rear end of the upper frame portion 6a, and the horizontal portion. A rail portion 6d configured by a rear frame portion 6c that is bent from 6b and extends rearwardly is provided.

The upper frame portion 6a and the down pipe 7 extend rearward so as to be separated from each other toward the rear of the vehicle, and the upper frame portion 6a and the down pipe 7 are connected between the upper frame portion 6a and the down pipe 7. Connecting frames 9a and 9b are provided in order from the top. The connecting frames 9a and 9b are a part of the vehicle body frame F and are provided as a pair of left and right.
A first cross portion 10 (cross member) that connects the left and right upper frame portions 6a is provided at an intermediate portion of the upper frame portion 6a. In addition, a second cross portion 11 and a third cross portion 12 that connect the left and right down pipes 7 are respectively provided in the upper portion and the middle portion of the down pipe 7. Moreover, the 4th cross part 18 (FIG. 1) which connects the horizontal part 6b on either side is provided in the front part of the horizontal part 6b.

  Further, in the rail portion 6d, a pair of left and right back stay portions 13 extend forward and downward from the rear portion of the rear frame portion 6c. A pivot portion 13 a through which the pivot shaft 17 is inserted is provided at the lower ends of the left and right back stay portions 13. The pivot shaft 17 is a shaft that supports the swing arm 50. A pair of left and right pivot support pipes 14 extending substantially vertically downward and connected to the pivot portion 13a are provided at the front end of the rear frame portion 6c. The backstay part 13 is reinforced by connecting the pivot support pipe 14 to the pivot part 13a. The backstay portion 13 is a member that connects the pivot hole portion 51 (FIG. 2) provided at the front end of the swing arm 50 and the rail portion 6 d. Further, a fifth cross portion 15 that connects the left and right back stay portions 13 is provided at the upper portion of the back stay portion 13.

  The fuel tank 53 is placed on the vehicle body frame F so as to straddle between the left and right rail portions 6d. As shown in FIG. 1, a seat 35 on which a passenger sits is provided above the fuel tank 53. The seat 35 is formed with a front seat portion 35a where the driver is seated and a rear seat portion 35b which is formed one step higher behind the front seat portion 35a and where the passenger is seated. The fuel filler port 54 of the fuel tank 53 is provided below the rear seat portion 35b.

The swing arm 50 is pivotally supported by the pivot hole 51 so that the pivot shaft 17 penetrating the left and right pivot portions 13a of the backstay portion 13 is inserted into the pivot hole portion 51. The rear wheel WR is pivotally supported at the rear end of the swing arm 50.
A rear cushion 52 that absorbs the swing of the swing arm 50 is provided below the fuel tank 53 and between the fifth cross portion 15 and the swing arm 50. The rear cushion 52 is configured by providing a cylindrical damper unit inside a coil spring coiled in a cylindrical shape.

The engine 20 as an internal combustion engine is a multi-cylinder engine having a plurality of cylinders. Specifically, the engine 20 is a water-cooled four-cycle in-line three-cylinder engine, and the cylinder 21 of the engine 20 is provided at the front portion of the crankcase 22 with the cylinder axis greatly inclined forward, and from the crankcase 22 side. In order, a cylinder block 23 and a cylinder head 24 are provided. The cylinder block 23 is formed with a cylinder portion (not shown) that is a cylindrical space, and a piston (not shown) is provided in the cylinder portion so as to be reciprocally movable in the cylinder axial direction. Three cylinder portions of each cylinder are formed side by side in the vehicle width direction.
Further, as shown in FIG. 1, an oil pan 25 for storing oil in the engine 20 is provided at a lower portion of the crankcase 22 located below the horizontal portion 6b. The oil pan 25 bulges below the crankcase 22.

The engine 20 is provided below the main frame 6 at the center in the vehicle longitudinal direction. Specifically, the engine 20 penetrates through the engine fastening portions 16a, 16b, and 16c provided at the front and rear ends of the left and right horizontal portions 6b and the lower end of the down pipe 7 and the rear end portion of the engine 20 in the vehicle width direction. A pivot shaft 17 supports the body frame F.
Exhaust gas from each cylinder portion is exhausted from an exhaust port 23 d provided at one location below the cylinder block 23. An exhaust pipe 26 extending below the engine 20 to the vicinity of the rear end of the engine 20 is connected to the exhaust port 23d. The exhaust pipe 26 includes a catalyst portion 26a extending downward from the exhaust port 23d and a pipe 26b extending rearward from the catalyst portion 26a. The catalyst portion 26a is formed to have a larger diameter than the pipe 26b, and a catalyst for purifying exhaust gas is provided inside. As shown in the front view of FIG. 6, the catalyst portion 26 a extends from the exhaust port 23 d to the lower left and the pipe 26 b passes through the left side of the oil pan 25 so as to avoid the oil pan 25.

A box-shaped muffler 27 connected to the rear end of the exhaust pipe 26 is connected to the rear side of the engine 20 below the swing arm 50. At the rear end of the muffler 27, a tail pipe 27a for exhausting the exhaust to the outside is provided.
In the saddle-ride type vehicle 1, the cylinder 21 is inclined forward, the exhaust pipe 26 and the muffler 27 are provided below the engine 20, and the fuel tank 53 is provided below the seat 35. The center of gravity is reduced.

A drive sprocket 40 that outputs the rotation of the engine 20 is provided on the left side surface of the rear portion of the engine 20. A driven sprocket 41 is provided on the left side surface of the rear wheel WR, and the rear wheel WR is driven by a chain 42 wound around the drive sprocket 40 and the driven sprocket 41.
A plate-like step holder 30 that extends rearward on the side of the swing arm 50 is provided below the back stay portion 13. A pair of left and right step holders 30 are provided, and a main step 31 on which the driver puts his feet and a tandem step 32 on which his passengers put his feet are attached. A shift pedal 33 for performing a shift operation is provided in front of the main step 31 on the left side of the vehicle. A brake pedal 34 (FIG. 6) for operating braking of the rear wheel WR is provided in front of the main step on the left side of the vehicle.

A radiator 36 for cooling the cooling water of the engine 20 is fixed in front of the left and right down pipes 7. An ignition coil 37 as an ignition device of the engine 20 is attached to the side surface of the down pipe 7. A meter 38 indicating the engine speed and the vehicle speed is provided on the upper portion of the front fork 2.
Also, brake discs 43 are attached to both side surfaces of the front wheel WF, and brake calipers 44 that brake the front wheels WF by sandwiching the brake disc 43 are provided below the left and right front forks 2, respectively. A rear brake disc 45 is provided on the right side surface of the rear wheel WR, and a rear brake caliper (not shown) for braking the rear wheel WR is attached to the right portion of the swing arm 50.

FIG. 3 is a plan view of the vicinity of the horizontal portion 6b. FIG. 4 is a cross-sectional view taken along the line AA in FIG.
As shown in FIGS. 2 and 3, a tray 81 in which the battery 39 and the like are accommodated is provided between the left and right horizontal portions 6b. The tray 81 has flange portions 82 that extend to the front side and the left and right sides of the vehicle, respectively, and these flange portions 82 are disposed on the fourth cross portion 18 and the left and right horizontal portions 6b. A plurality of fixing bolts 83 provided on the portion 82 are fixed to the vehicle body frame F.
As shown in FIG. 4, the tray 81 is provided with a partition plate 84 that partitions the inside of the tray 81 left and right. A battery accommodating portion 85 that bulges downward is formed on the left side of the tray 81, and the battery 39 is provided in the battery accommodating portion 85 on the left side of the partition plate 84.

  In the tray 81, a box-shaped ABS modulator 46 that controls the hydraulic pressure of the brake caliper 44 and the rear brake caliper is disposed in a component housing portion 86 that is formed on the right side of the partition plate 84 and higher than the battery housing portion 85. Has been. The ABS modulator 46 controls the hydraulic pressure for braking the front wheel WF and the rear wheel WR based on detection information such as the vehicle speed when the front wheel WF and the rear wheel WR are likely to be locked by a brake operation. Is automatically controlled to prevent the front wheel WF and the rear wheel WR from being locked. The ABS modulator 46 includes a pump (not shown) that pumps brake oil and a control unit (not shown) that controls the operation of the ABS modulator 46.

FIG. 5 is a left side view of the vicinity of the upper frame portion 6a. FIG. 6 is a front view of the saddle-ride type vehicle 1. Here, in FIG.5 and FIG.6, illustration of the front fork 2 and the front wheel WF is abbreviate | omitted.
An air cleaner box 60 (air cleaner) for purifying the air supplied to the engine 20 is provided between the left and right upper frame portions 6 a behind the head pipe 4. The air cleaner box 60 has a box-shaped box body 61 extending along the upper frame portion 6 a from the rear portion of the head pipe 4 to above the connection frame 9 b, and a lid portion 62 that covers the box body 61. . The box body 61 has an open surface along the left and right upper frame portion 6a, and the lid portion 62 covers the opening. The lid portion 62 is fixed to the box body 61 by a fixture 63 that fits into a plurality of fixing portions formed on the peripheral edge of the box body 61. Inside the air cleaner box 60, a filter-like element 74 (FIG. 7) that collects dust and the like in the air supplied to the engine 20 is provided. In the air cleaner box 60, the lid portion 62 can be removed to expose the element 74, and the element 74 can be maintained. The air cleaner box 60 is provided to the full width of the left and right upper frame portions 6a.

As shown in FIG. 5, the box main body 61 is provided with a stepped portion 64 that is formed between the left and right upper frame portions 6 a so that the lower portion is recessed inward. The step portion 64 includes a step portion bottom portion 65 formed substantially horizontally above the connection frame 9a, and a step portion side surface portion 66 that extends continuously downward from the first cross portion 10 continuously to the step portion bottom portion 65. The box body 61 is continuous from the left end to the right end in the vehicle width direction. Further, a bulging portion 61 b that bulges downward is formed on the rear side of the stepped portion 64 in the box body 61.
Further, a corner portion 67 formed in a curved surface is formed at a portion where the step bottom portion 65 and the step portion side surface portion 66 intersect, and the air cleaner box 60 includes a first cross portion provided along the corner portion 67. 10 is arranged so that a corner portion 67 is placed thereon, and is supported by the first cross portion 10. Further, a cushioning material 10a made of a material capable of reducing vibrations, such as rubber, is wound around the first cross portion 10. The cushioning material 10a reduces vibration of the vehicle body frame F transmitted to the air cleaner box 60. is doing.

A resonator 80 as a chamber for air that is taken in from the outside and flows to the air cleaner box 60 is provided on the upper portion of the air cleaner box 60.
Further, as shown in FIGS. 5 and 6, below the air cleaner box 60, a connecting tube 68 (connecting member) connected to the step bottom portion 65 and a connecting tube 68 are connected and supplied to the engine 20. A throttle body 91 that adjusts the amount of air, and an intake pipe 70 that connects the throttle body 91 and the intake ports 23a, 23b, and 23c (FIG. 8) of the engine 20 are provided. The intake pipe 70 includes one main pipe 75 connected to the throttle body 91, a first branch pipe 71, a second branch pipe 72, and a third branch pipe 73 that branch from the main pipe 75 into three. ing.
In addition, the connecting tube 68, the throttle body 91, and the intake pipe 70 overlap with connecting frames 9a provided on the left and right sides of the vehicle in a side view, and the connecting frame 9a connects the connecting tube 68, the throttle body 91, and The intake pipe 70 can be protected.

7 is a cross-sectional view taken along the line BB in FIG.
As shown in FIGS. 6 and 7, the connecting tube 68 that connects the air cleaner box 60 and the throttle body 91 is provided in the left end portion in the vehicle width direction in the stepped portion 64. Further, the throttle body 91 is connected to the connecting tube 68 and is provided in the step portion 64 closer to the center in the vehicle width direction. The downstream end of the throttle body 91 is located at the center in the vehicle width direction, and an upstream end 77 provided at the upstream end of the main pipe 75 in the flow of intake air is connected to the downstream end. ing.

The main pipe 75 has an upstream end 77 located at the center in the vehicle width direction, and extends in the stepped portion 64 to the right end in the vehicle width direction. That is, the connecting tube 68, the throttle body 91, and the main pipe 75 are disposed in the step portion 64, and are arranged in a straight line from the left end portion to the right end portion of the step portion 64.
As described above, since the main pipe 75 is provided in the stepped portion 64, the intake pipe 70 can be provided on the inner side of the air cleaner box 60 and can be disposed compactly. Furthermore, since the connecting tube 68 and the throttle body 91 are also provided in the step portion 64, these intake devices can be provided inside the air cleaner box 60 to be compactly arranged. In addition, since the connecting tube 68 is provided at the left end in the vehicle width direction, a large space can be secured on the opposite side of the throttle body 91, and a relatively long main pipe 75 can be disposed in this space.
Further, as shown in FIG. 6, the left and right upper frame portions 6a and the down pipe 7 are formed narrower as they approach the head pipe 4 in front of the vehicle, but the throttle body 91 is closer to the center in the vehicle width direction. Because of the layout, the throttle body 91 can be easily provided using a relatively large space near the center.

  As shown in FIG. 7, the throttle body 91 is a cylindrical throttle body main body 92 and a throttle valve 93 that is rotatably disposed in the throttle body main body 92 and adjusts the amount of air flowing through the throttle body main body 92. And. The throttle valve 93 is configured to rotate integrally with a throttle pulley 94 (FIG. 6) provided outside the throttle body main body 92, and a rotation operation of a throttle grip (not shown) provided on the steering handle 3. It is operated by two cables operated by More specifically, an open side throttle cable (not shown) and a close side cable (not shown) are connected to the throttle pulley 94, and these cables are connected to two locations on the outer periphery of the disc-shaped throttle pulley 94. Cable connection portions 94a and 94b are formed. The open side throttle cable is pulled in response to turning the throttle grip to the open side, and the close side throttle cable is pulled in response to turning the throttle grip to the close side. Cable.

As shown in FIG. 6, the throttle pulley 94 is provided with its disk-shaped surface facing the front side of the vehicle. Further, on the vehicle front side of the throttle body 91, a cable stay 95 that supports the opening side throttle cable and the closing side throttle cable is provided above the throttle pulley 94. Further, the throttle body 91 is provided with an idle air control valve 96 adjacent to the throttle pulley 94 for adjusting the air intake amount when the engine 20 is idling.
In addition, a sensor unit 97 including a throttle position sensor that detects the opening of the throttle valve 93 and a temperature sensor that detects the temperature of intake air that passes through the throttle valve 93 is provided below the throttle body 91. Information detected by the sensor unit 97 is output to an ECU (not shown) that controls each unit including the electrical components of the saddle-ride type vehicle 1.

FIG. 8 is a plan view of the vicinity of the throttle body 91 and the intake pipe 70 as viewed from above the vehicle. In addition, illustration of the 1st cross part 10 is abbreviate | omitted in FIG.
A first intake port 23a, a second intake port 23b, and a third intake port 23c are provided in the upper part of the cylinder block 23 in order from the left side of the vehicle corresponding to each cylinder. Is inhaled.
The first air inlet 23a, the second air inlet 23b, and the third air inlet 23c are linearly arranged in the vehicle width direction at substantially equal intervals. Of the three air intake ports, the second air intake port 23b located in the intermediate portion is provided closer to the vehicle left side than the center in the vehicle width direction. That is, the first intake port 23a, the second intake port 23b, and the third intake port 23c are provided offset to the left side of the vehicle from the center in the vehicle width direction as a whole.

The main pipe 75 connected to the throttle body 91 has an upstream end 77 located at the center in the vehicle width direction, and extends to the right end in the vehicle width direction within the width of the left and right connecting frames 9a (FIG. 7). .
A first branch portion 75a and a second branch portion, to which the upstream ends of the first branch pipe 71, the second branch pipe 72, and the third branch pipe 73 are connected to the outer peripheral portion of the cylindrical main pipe 75, respectively. 75b and a third branch part 75c are provided. The first branch portion 75 a to which the first branch pipe 71 is connected is provided in the vicinity of the upstream end 77, and the second branch portion 75 b to which the second branch pipe 72 is connected is an intermediate portion in the longitudinal direction of the main pipe 75. The third branch portion 75c to which the third branch pipe 73 is connected is connected to the end of the main pipe 75 on the right connection frame 9a side. For this reason, the distance from the upstream end portion 77 to each branch portion 75a, 75b, 75c is the shortest from the upstream end portion 77 to the first branch portion 75a, and from the upstream end portion 77 to the third branch portion 75c. The distance from the upstream end 77 to the second branch 75b is longer than the distance from the upstream end 77 to the first branch 75a, and from the distance from the upstream end 77 to the third branch 75c. It is getting shorter.

  The first branch pipe 71, the second branch pipe 72, and the third branch pipe 73 that branch from the main pipe 75 in three directions are respectively a first intake port 23a, a second intake port 23b, and a first branch port of the cylinder head 24. 3 is connected to the air inlet 23c. Specifically, the first branch pipe 71 is bent greatly from the first branch portion 75a to the left rear side of the vehicle and extends downward, and a first downstream end portion 71a provided at the lower end thereof is connected to the first intake port 23a. ing. The second branch pipe 72 bends from the second branch portion 75b to the left rear side of the vehicle and extends downward, and a second downstream end 72a provided at the lower end thereof is connected to the second intake port 23b. The third branch pipe 73 bends from the third branch portion 75c to the left rear side of the vehicle and extends downward, and a third downstream end 73a provided at the lower end thereof is connected to the third intake port 23c.

  The lengths of the branch pipes 71, 72, 73 are set corresponding to the lengths from the upstream end 77 to the branch parts 75a, 75b, 75c, respectively. The lengths L1, L2, and L3 (FIG. 8) of the intake pipe 70 that is configured by combining 71, 72, and 73 and that forms an intake path connected to each cylinder are formed to be substantially equal. . That is, in the intake path of the intake pipe 70, the distance L1 from the upstream end 77 to the first downstream end 71a, the distance L2 from the upstream end 77 to the second downstream end 72a, and the upstream end 77 to the first downstream end 71a. 3 The distance L3 to the downstream end 73a is substantially equal to the distance L3.

Specifically, each branch pipe 71, 72, 73 is bent around the left side longer as the branch pipe provided on the left side of the vehicle, and the length of each branch pipe 71, 72, 73 is adjusted. ing. That is, in the three branch pipes, the first branch pipe 71 connected to the first branch part 75a having the shortest distance from the upstream end 77 is formed to be the longest, while the distance from the upstream end 77 is short. The third branch pipe 73 connected to the longest third branch portion 75c is formed to be the shortest. The second branch pipe 72 is formed shorter than the first branch pipe 71 and longer than the third branch pipe 73.
Further, each of the branch portions 75a, 75b, and 75c is provided at a lower position as the branch portion provided on the left side of the vehicle. As shown in FIG. 5, the first branch pipe 71 passes through the lowest position. The third branch pipe 73 is disposed so as to pass through the highest position.
Further, the upstream ends of the branch pipes 71, 72, 73 are accommodated in the stepped portion 64 of the box body 61 as shown in FIG. 5, and the branch pipes 71, 72, 73 are arranged in a compact manner. Yes.

  The first downstream end portion 71a, the second downstream end portion 72a, and the third downstream end portion 73a are provided with branch pipe flange portions 78 connected to the intake ports 23a, 23b, and 23c. The branch pipe flange portion 78 is formed in a plate shape that integrally connects the lower ends of the branch pipes 71, 72, and 73, and the strength and rigidity of the branch pipes 71, 72, and 73 are enhanced. The branch pipe flange portion 78 is provided with a plurality of fixing holes 78a, and the branch pipe flange portion 78 is fixed to the cylinder block 23 with bolts (not shown) through the plurality of fixing holes 78a.

  Furthermore, each branch pipe 71, 72, 73 is provided with an injector 76 for injecting fuel therein. The injectors 76 are provided in the vicinity of the intake ports 23a, 23b, and 23c, and an air-fuel mixture made by mixing air and fuel injected by the injectors 76 in the branch pipes 71, 72, and 73 is provided for each intake air. It is supplied to each cylinder from the ports 23a, 23b, 23c.

Next, the flow of intake air in the intake device structure of the present embodiment will be described.
As indicated by arrows in FIG. 7, the air taken into the resonator 80 from the outside flows into the air cleaner box 60 and is cleaned when passing through the element 74 in the air cleaner box 60, and then passes through the connecting tube 68. The throttle body 91 is reached. The air reaching the throttle body 91 is adjusted in flow rate by a throttle valve 93 provided in the throttle body 91, and then passes through the main pipe 75 to the first branch pipe 71, the second branch pipe 71, as shown in FIG. It branches into the branch pipe 72 and the 3rd branch pipe 73, respectively, and flows to each inlet port 23a, 23b, 23c. In the present embodiment, since the lengths L1, L2, and L3 of the intake pipe 70 are formed to be equal lengths, one throttle body 91 is connected to the intake pipe 70 including the branch pipes 71, 72, and 73. Even in this configuration, intake air can be supplied to each cylinder at an appropriate timing, and intake air can be supplied uniformly to each cylinder.

  As described above, according to the embodiment to which the present invention is applied, the main pipe 75 connected to the throttle body 91, the first branch pipe 71 that branches from the main pipe 75 to each cylinder, the second branch pipe 72, and In the intake pipe 70 composed of the third branch pipe 73, the main pipe 75 is disposed in the stepped portion 64 of the air cleaner box 60. Therefore, the intake pipe 70 is provided on the inner side of the air cleaner box 60 and the intake pipe 70 is disposed in a compact manner. be able to.

  Further, since the connecting tube 68 is provided at the end in the vehicle width direction and can be accessed from the vehicle width direction, the air cleaner box 60 and the throttle body 91 can be easily connected by the connecting tube 68 and assembled. Good sex. In addition, since the connecting tube 68 is provided at the end in the vehicle width direction, the intake pipe 70 can be extended to the side of the connecting tube 68 on the side opposite to the end, and the intake pipe 70 is lengthened. can do. Thereby, the characteristic of the engine 20 can be improved, for example, the low speed torque of the engine 20 can be improved.

  Further, since the upstream end 77 of the main pipe 75 is located in the center in the vehicle width direction, the throttle body 91 connected to the upstream of the main pipe 75 can also be provided in the center in the vehicle width direction, and the arrangement of the throttle body 91 is easy. . Further, since the upstream end 77 is located in the center in the vehicle width direction and is not biased to one side in the vehicle width direction, the distance L1 from the upstream end 77 to each downstream end 71a, 72a, 73a to each cylinder, L2 and L3 can be easily provided so as to be substantially equal. Thus, intake air can be supplied to each cylinder of the engine 20 at an appropriate timing, and intake air can be supplied uniformly to each cylinder.

Furthermore, since the air cleaner box 60 can be supported by placing the air cleaner box 60 on the first cross portion 10, the assembly of the air cleaner box 60 is good. Further, since the air cleaner box 60 is supported by the first cross portion 10 and is stable, the connecting tube 68 can be easily attached to the air cleaner box 60.
Furthermore, the throttle body 91 can be protected by the connecting frame 9 a overlapping the side surface of the throttle body 91.

  In the above embodiment, the main pipe 75 is described as being provided in the stepped portion 64 of the air cleaner box 60. However, the present invention is not limited to this, and the main pipe 75 is recessed in the air cleaner box 60. A shape different from that of the stepped portion 64 may be used as long as it is provided in the portion. This case will be described as a modified example.

[Modification]
FIG. 9 is a left side view of the vicinity of the upper frame portion 6a in the modified example.
In the modification shown in FIG. 9, the same parts as those in the above-described embodiment are denoted by the same reference numerals, and the description thereof is omitted.
An air cleaner box 160 (air cleaner) provided between the left and right upper frame portions 6a behind the head pipe 4 has a box-shaped box main body 161 extending along the upper frame portion 6a and a lid portion 62. is doing.
The box main body 161 is provided with a concave portion 164 whose lower portion is recessed upward toward the inside of the air cleaner box 160. The recess 164 is continuous from the left end to the right end of the box body 161 in the vehicle width direction.

The connecting tube 68 is provided at the left end in the vehicle width direction in the recess 164, and the throttle body 91 is connected to the connecting tube 68 in the recess 164. The main pipe 75 is provided in the recess 164 and extends to the vicinity of the connecting frame 9a on the right side of the vehicle as shown in FIG. Further, the recess 164 is provided with a corner portion 67 extending in the vehicle width direction, and the first cross portion 10 is provided along the corner portion 67. And the air cleaner box 160 is supported by the 1st cross part 10 which contact | abuts to the corner | angular part 67 via the shock absorbing material 10a.
Thus, since the main pipe 75 connected to the throttle body 91 is disposed in the recess 164 of the air cleaner box 160, the intake pipe 70 can be provided in a compact manner by providing the intake pipe 70 on the inner side of the air cleaner box 160. it can.

In addition, the said embodiment shows the one aspect | mode which applied this invention, Comprising: This invention is not limited to the said embodiment.
In the above embodiment, the engine 20 is a three-cylinder engine, and the three branch pipes 71, 72, 73 of the intake pipe 70 connected to the throttle body 91 are connected to the respective cylinders. The present invention is not limited to this, and the present invention can also be applied to engines having two cylinders or four cylinders or more. For example, two branch pipes branched from an intake pipe connected to one throttle body that supplies intake air to a 2-cylinder engine are connected to each cylinder of the 2-cylinder engine, and each cylinder is connected from the upstream end of the intake pipe. The distance to the downstream end of the branch pipe may be equal. The present invention is not limited to a two-wheeled vehicle, but can be applied to a saddle-ride type vehicle having a number of wheels exceeding three or four wheels. Of course, other detailed configurations of the saddle-ride type vehicle 1 can be arbitrarily changed.

1 is a left side view of a saddle-ride type vehicle according to an embodiment of the present invention. It is the perspective view which looked at the saddle-ride type vehicle from the left front. It is a top view of the vicinity of a horizontal part. It is AA sectional drawing in FIG. It is a left view of the vicinity of an upper frame part. It is a front view of a saddle-ride type vehicle. It is BB sectional drawing in FIG. It is the top view which looked at the vicinity of a throttle body and an intake pipe from the vehicle upper direction. It is a left view of the vicinity of the upper frame part in a modification.

1 saddle riding type vehicle 9a connecting frame 10 first cross part (cross member)
20 engine (internal combustion engine)
23 Cylinder block 23a First intake port 23b Second intake port 23c Third intake port 60, 160 Air cleaner box (air cleaner)
64 steps 67 corners 68 connecting tubes (connecting members)
70 Intake Pipe 71 First Branch Pipe 71a First Downstream End 72 Second Branch Pipe 72a Second Downstream End 73 Third Branch Pipe 73a Third Downstream End 75 Main Pipe 77 Upstream End 91 Throttle Body 164 Recessed L1, L2 , L3 distance

Claims (5)

A multi-cylinder internal combustion engine, and an air cleaner for purifying the intake air supplied to the internal combustion engine,
In the intake device structure of a saddle-ride type vehicle having an intake pipe composed of a main pipe connected to a throttle body connected to the air cleaner and a branch pipe branched from the main pipe to each cylinder,
Steps or recesses are provided in the air cleaner,
The main pipe is disposed in the stepped portion or the recessed portion;
An intake device structure for a saddle-ride type vehicle. A connecting member for connecting the air cleaner and the throttle body is provided at an end of the stepped portion or the recessed portion in the vehicle width direction;
The intake device structure for a saddle-ride type vehicle according to claim 1. The upstream end of the main pipe intake flow is located in the center in the vehicle width direction,
The intake pipe to each cylinder is provided so that the distance from the upstream end to the downstream end of the branch pipe to each cylinder is equal;
The intake device structure for a saddle-ride type vehicle according to claim 1 or 2. A cross member of the vehicle body frame is provided along the step of the air cleaner or the corner of the recess;
The intake device structure for a saddle-ride type vehicle according to any one of claims 1 to 3. The side surface of the throttle body overlaps the body frame in a side view;
The intake device structure for a saddle-ride type vehicle according to any one of claims 1 to 4.

Images