JP4704242B2 - Secondary air supply device for exhaust purification - Google Patents

Description

  The present invention relates to a secondary air supply device for purifying exhaust gas of an internal combustion engine mounted on a motorcycle or the like.

2. Description of the Related Art Conventionally, in an engine exhaust purification secondary air supply apparatus having two exhaust valves, an opening for supplying secondary air is provided at a position spaced downstream from the confluence of exhaust ports corresponding to each exhaust valve. There are some (for example, refer to Patent Document 1).
JP 2005-315242 A

By the way, in the above conventional configuration, since the opening for supplying the secondary air is formed at a position away from each exhaust valve, the exhaust of the secondary air that effectively uses the negative pressure associated with the opening and closing of each exhaust valve. It was difficult to implement a positive introduction to the port.
Accordingly, the present invention provides a secondary air supply device for purifying exhaust gas that can effectively introduce secondary air into an exhaust port by effectively utilizing negative pressure associated with opening and closing of a plurality of exhaust valves.

As a means for solving the above-mentioned problems, the invention described in claim 1 includes a single camshaft (37), at least two exhaust valves (26), and an exhaust port for guiding exhaust from the exhaust valves (26). (23), a separation partition wall (23c) for separating the upstream side of the exhaust port (23) into an exhaust passage (23a) corresponding to each exhaust valve (26), and secondary air to the exhaust port (23) And a stem (25a) of the intake valve (25) and a stem (26a) of each exhaust valve (26) across the camshaft (37). The camshaft (37) extends in a V shape when viewed from the side of the cylinder as viewed from the axial direction, and the power of the camshaft (37) is transferred to the intake valve (25) via the rocker arms (35, 36). ) And to each exhaust valve (26) In the emission control secondary air supply system of the cylinder head (10) of the SOHC engines,
The secondary air supply passage (81) opens downstream of the exhaust port (23) immediately after the separation partition wall (23c) and is formed in parallel with at least one of the exhaust valves (26), The cylinder head (10) extends along the stems (25a, 26a) of the intake valves (25) and the exhaust valves (26) in a side view of the cylinder, while the intake valves (25) and the exhaust valves (26). The passage forming portion (84) formed in the cylinder head (10) in the secondary air supply passage (81) and each exhaust valve ( 26) a valve spring (26b) for accommodating a reed valve (90) for controlling the flow of air to the secondary air supply passage (81). 2) at least partially overlapped, and the passage forming portion (84) is formed to reach the upper end (G) of the cylinder head (10), and the passage forming portion (84) and each exhaust valve The valve spring (26b) of (26) is characterized in that at least a part thereof is overlapped with each other in a side view of the cylinder.

The invention as set forth in claim 2, wherein the secondary air supply passage (81) comprises at the front of the cylinder head (10) is disposed inclined forwardly, the valve operating chamber front wall of said cylinder head (10) Is formed with a spring accommodating portion (85) which is changed into a convex trapezoidal shape so as to avoid the valve spring (26b) of each exhaust valve (26), and the left and right center of the spring accommodating portion (85). The passage forming portion (84) is formed over the top and bottom of the portion .

According to a third aspect of the present invention, the exhaust port (23) is formed to be bent to one side of the cylinder head (10) , and the separation partition wall (23c ) is formed along the exhaust port (23). ) Is also formed in a curved shape, and the secondary air supply passage (81) opens downstream immediately after the separation partition wall (23c) .
According to a fourth aspect of the present invention, an air introduction passage to the reed valve (90) is arranged in the front-rear direction of the cylinder head (10), and the top surface of each exhaust valve (26) is viewed from above. In the rocker arm (36), an arm portion extending toward the distal end of the stem of each exhaust valve (26) is provided avoiding the valve accommodating portion (82).

According to the present invention , since the secondary air supply passage is opened immediately downstream of the separation partition of the exhaust port, the secondary air supply opening and each exhaust valve can be made as close as possible. Secondary air can be positively introduced into the exhaust port by effectively utilizing the negative pressure associated with the opening and closing of the.
In addition, the secondary air supply passage and the exhaust valve insertion hole can be easily processed in the same process, reducing the machining man-hour of the cylinder head, and the secondary air supply passage and the exhaust valve are adjacent to each other. The exhaust purification performance can be improved by mixing the exhaust and secondary air at a high temperature.

According to the present invention , the reed valve, the air introduction passage, and the secondary air supply passage can be disposed at a high position of the engine, and the protection from flying stones or the like can be improved.

According to the present invention , the exhaust air purification performance can be further improved by opening the secondary air supply passage at the curved middle portion of the curved exhaust port.

Embodiments of the present invention will be described below with reference to the drawings.
A vehicle 201 shown in FIG. 11 includes left and right front wheels 202 and rear wheels 203, which are relatively large-diameter low-pressure balloon tires, in front of and behind a small and lightweight vehicle body. It is configured as a so-called ATV (All Terrain Vehicle) with improved running performance on rough terrain. The vehicle body frame 204 of the vehicle 201 forms a box structure that is long in the front-rear direction at the center in the vehicle width direction, and the engine (internal combustion engine) 1 as a prime mover of the vehicle 201 is mounted at the substantially center of the vehicle body frame 204. .

  As shown in FIGS. 1 to 3, the engine 1 is a water-cooled four-stroke single-cylinder engine. For example, the vehicle 201 is configured such that the rotation axis C <b> 1 of the crankshaft 2 is orthogonal to the vehicle traveling direction (along the left-right direction). Mounted on. Note that the directions such as front, rear, left and right in the following description are the same as those in the vehicle 201 unless otherwise specified. In the figure, the arrow FR indicates the front of the vehicle, the arrow LH indicates the left side of the vehicle, and the arrow UP indicates the upper side of the vehicle.

  A cylinder 4 is erected on the front upper side of the crankcase 3 of the engine 1, and the reciprocating motion of the piston 5 in the cylinder 4 is converted into the rotational motion of the crankshaft 2 in the front portion of the crankcase 3. The rotational power of the crankshaft 2 is transmitted to the output part on the left side of the rear part of the crankcase 3 via the clutch 6 and the transmission 7 in the rear part of the crankcase 3. Here, when the axis line along the standing direction in the cylinder 4 and the reciprocating direction of the piston 5 is C2, the axis line C2 is inclined slightly forward so that the upper part is located on the front side.

The cylinder 4 has a cylinder body 9 attached to the upper front side of the crankcase 3, a cylinder head 10 attached to the distal end side of the cylinder body 9, and a head cover 11 attached to the distal end side of the cylinder head 10. It becomes.
The cylinder head 10 and the cylinder main body 9 are integrally coupled to the crankcase 3 by four stud bolts 12 penetrating through the four corners along the cylinder axis C2 from above (see FIGS. 3 and 4). The head cover 11 is fixed to the cylinder head 10 by a plurality of bolts (not shown) inserted from above.

The piston 5 is fitted in the cylinder bore 13 of the cylinder body 9 so as to be able to reciprocate. A small end portion of a connecting rod 15 is connected to the piston 5 via a piston pin 14 so as to be swingable. The large end of the connecting rod 15 is rotatably connected to the crank pin 16 of the crankshaft 2.
The cylinder head 10 closes the tip opening of the cylinder bore 13 and forms a combustion chamber 17 above the piston 5. An intake pipe attachment 18 connected to the throttle body is provided on the rear surface side of the cylinder head 10, and an exhaust pipe attachment 19 connected to an exhaust pipe (not shown) is provided on the front side of the cylinder head 10.

  Here, the engine 1 in this embodiment is a SOHC (single overhead camshaft) type and is a four-valve type having two intake and exhaust valves. A pair of left and right intake combustion chamber side openings 22 in the intake port 21 are formed in the rear portion of the cylinder head 10 that forms the ceiling of the combustion chamber 17 (hereinafter referred to as the ceiling forming portion 27). Two pairs of left and right exhaust combustion chamber side openings 24 in the exhaust port 23 are formed in the front part. These combustion chamber side openings 22 and 24 are opened and closed by an intake valve 25 or an exhaust valve 26, respectively.

A spark plug mounting hole 28 penetrating the ceiling forming portion 27 is provided on the left side of the cylinder head 10 so as to be inclined with respect to the cylinder axis C2 and for attaching / detaching the plug to the spark plug mounting hole 28. A plug hole 29 is provided open to the left side of the cylinder head 10. In the figure, reference numeral 30 denotes a water jacket in the ceiling forming portion 27.
The upper part of the ceiling forming part 27 is a valve operating chamber forming part 31 that opens upward, and the upper open part of the valve operating chamber forming part 31 is covered by the head cover 11 to accommodate the valve operating mechanism for operating each valve. A valve operating chamber 32 is formed. The plug hole 29 is adjacent to the lower left side of the valve operating chamber forming portion 31.

  The intake port 21 forms a single intake pipe side opening 33 at the intake pipe attachment portion 18, and extends from the intake pipe side opening 33 to the downstream side (combustion chamber 17 side) in the cylinder head 10. The two branches into the intake combustion chamber side openings 22. On the other hand, the exhaust port 23 extends from the exhaust combustion chamber side opening 24 in the cylinder head 10 to the downstream side (exhaust pipe attachment portion 19 side), and merges into one in the cylinder head 10 to form the exhaust pipe attachment portion 19. To the exhaust pipe side opening 34 (see FIG. 7). Hereinafter, the separation passages before the merging in the exhaust port 23 are referred to as upstream exhaust passages 23a, the single passage after the merging is referred to as a downstream exhaust passage 23b, and a partition between the upstream exhaust passages 23a is referred to as a separation partition 23c.

  The valves 25 and 26 are formed by extending rod-shaped stems 25a and 26a upward from umbrella-shaped valve bodies aligned with the combustion chamber side openings 22 and 24 of the ports 21 and 23, respectively. The stems 25a and 26a of the valves 25 and 26 extend in a V shape in a side view of the cylinder toward the tip of the cylinder head 10 and pass through the upper walls of the intake or exhaust ports 21 and 23, respectively. After reaching 32, the tip is engaged with the rocking ends of the intake side or exhaust side rocker arms 35, 36. A retainer (not shown) is attached to the distal ends of the stems 25a, 26a of the valves 25, 26, and receives the spring force of the valve spring 26b (shown only on the exhaust valve 26 side in FIG. 4) via the retainer. The valves 25 and 26 are energized in a direction to close the combustion chamber side openings 22 and 24 of the ports 21 and 23.

  Between the stems 25a and 26a of the valves 25 and 26, a single camshaft 37 extending in the left and right directions in parallel with the crankshaft 2 is disposed. The camshaft 37 has an intake cam 38 and an exhaust cam 39 integrally in the middle in the longitudinal direction, and both left and right end portions are rotatably supported by the cylinder head 10 via ball bearings 40 and 41. Hereinafter, the rotation axis of the camshaft 37 will be described as C3. A cam driven sprocket 42 is coaxially fixed to the right end of the cam shaft 37, and an endless cam chain 44 is wound around the cam driven sprocket 42 and the cam drive sprocket 41 at the right end of the crankshaft 2. It is linked to the crankshaft 2 and driven to rotate in the same direction. In the figure, reference numeral 45 denotes a cam chain tensioner.

  Referring also to FIG. 4, an intake side rocker shaft 46 or an exhaust side rocker shaft 47 that extends in the left and right directions in parallel with the camshaft 37 is disposed above and behind the camshaft 37. Hereinafter, the axes of the rocker shafts 46 and 47 are C4 and C5, respectively. The rocker shafts 46 and 47 are positioned below (cylinder head 10 side) below the mating surface (hereinafter also referred to as the G surface) of the cylinder head 10 and the head cover 11, and the left and right ends of each rocker shaft 46, 47 are ceilings. It is supported by the left and right intake side shaft support portions 48 or the exhaust side shaft support portions 49 erected from the formation portion 27 into the valve operating chamber 32. The rocker shafts 46 and 47 respectively support the front and rear intermediate portions of the intake side or exhaust side rocker arms 35 and 36 so as to be swingable.

  Referring also to FIG. 6, cam rollers 50 that are in contact with the outer peripheral surface of the intake cam 38 or the exhaust cam 39 are rotatably supported at the end portions of the rocker arms 35 and 36 on the camshaft 37 side. On the other hand, tappet bolts 51 are screwed and fixed to the other end portions (the swing end portions) of the rocker arms 35 and 36, respectively. The rocker arms 35 and 36 are engaged with the tips of the stems 25a and 26a of the valves 25 and 26 via tappet bolts 51, respectively. When the camshaft 37 is driven to rotate, the cams 38 and 39 The other end of each rocker arm 35, 36 swings according to the outer peripheral pattern, and the corresponding valve is reciprocated along its stem to open and close the combustion chamber side openings 22, 24 of the ports 21, 23. .

  As shown in FIGS. 1 to 3, a cam chain chamber 52 that houses the cam chain 44 is provided in the right side of the cylinder 4. The cam chain chamber 52 forms a flat storage space with a reduced lateral width, and enters the crankcase 3 of engine oil (hereinafter sometimes simply referred to as oil) fed into the valve train chamber 32. It also functions as a return path. Hereinafter, the left and right inner walls in the cam chain chamber 52 may be referred to as inner walls, and the left and right outer walls may be referred to as outer walls.

The crankshaft 2 has left and right journals 54 on the left and right sides thereof, and the journals 54 are rotatably supported on the left and right crank bearings 55 of the crankcase 3 via metal bearings. The crank pins 16 are supported between the journals 54 via left and right crank webs 56.
A balancer drive gear 58 for driving a balancer 57 disposed in the front portion of the crankcase 3 is coaxially fixed between the left journal 54 and the left crank web 56. A water pump 59 that is coaxial with the balancer 57 and is driven integrally with the balancer 57 is provided on the right side of the front part of the crankcase 3. A starter driven gear 61 and a one-way clutch 62 that are linked to the starter motor 60 behind the cylinder 4 are coaxially arranged on the left side of the crankshaft 2. A generator 63 is coaxially arranged at the left end of the crankshaft 2.

  On the right side of the crankshaft 2, the cam drive sprocket 41 is coaxially provided adjacent to the right side of the right journal 54, and the primary drive gear 64 is provided coaxially adjacent to the right side of the cam drive sprocket 41, A pump drive gear is coaxially provided adjacent to the right side of the primary drive gear 64.

  A main shaft 66 that extends to the left and right in parallel with the crankshaft 2 is disposed inside the rear portion of the crankcase 3. The main shaft 66 constitutes the transmission 7 by supporting a transmission gear group 68 together with a counter shaft 67 that is parallel to the main shaft 66. The clutch 6 that is coaxial with the main shaft 66 is disposed on the right side of the rear portion of the crankcase 3. A relatively large primary driven gear 69 that is coaxial with the primary drive gear 64 and meshes with the primary drive gear 64 is attached to the clutch 6. Power transmission between the crankshaft 2 and the main shaft 66 is interrupted via the clutch 6.

As shown in FIG. 2, an oil pump 71 that pumps engine oil to each part of the engine 1 is disposed on the lower right side in the crankcase 3. The oil pump 71 is driven in conjunction with the crankshaft 2 by meshing the pump driven gear 72 with the pump drive gear on the right side of the crankshaft 2.
Here, the engine 1 includes a dry sump type lubrication device. That is, the engine 1 has a relatively large oil tank (not shown) in addition to the small oil pan 73 below the crankcase 3.

  Referring also to FIG. 5, the oil pump 71 coaxially arranges the feed pump 71 a and the scavenge pump 71 b and integrally drives them. When the oil pump 71 is operated as the engine 1 is operated, First, the feed pump 71a sucks engine oil in the oil tank through the pressure-feed side oil hose 74a, and pumps the oil to each part in the engine 1 through the oil filter 75 on the right side of the crankcase 3. The oil that has been supplied to each part in the engine 1 and has returned to the oil pan 73 by natural dripping or the like is sucked into the scavenge pump 71b and returned to the oil tank through the recovery-side oil hose 74b. By repeating such a process, the engine oil circulates between the oil tank and the engine 1.

  The engine oil that has passed through the oil filter 75 is pumped to a shaft end oil chamber 76 that faces the right end of the crankshaft 2, and is also supplied to a cylinder oil passage 77 and a case oil passage 78 that branch at the top of the crankcase 3. Pumped. The engine oil pumped to the shaft end oil chamber 76 is supplied to each oil supply location via a crankshaft oil passage 79 formed in the crankshaft 2. On the other hand, the engine oil pressure-fed to the cylinder oil passage 77 is supplied to each oil supply location in the valve operating chamber 32, and the engine oil pressure-fed to the case oil passage 78 is supplied to each oil supply location in the rear part of the crankcase 3. To be supplied. The in-cylinder oil passage 77 is formed along the right side of the cylinder 4 (inside the outer wall of the cam chain chamber 52) so as to extend almost directly from the oil pump 71 (see FIG. 3).

Here, the engine 1 includes a secondary air supply device that supplies air to the exhaust gas and promotes purification thereof.
As shown in FIGS. 4 and 6, the secondary air supply device includes a secondary air supply passage 81 formed across the cylinder head 10 and the head cover 11, and an upper end of the secondary air supply passage 81 formed in the head cover 11. And a valve accommodating chamber 82 for opening the.

  The secondary air supply passage 81 is formed between the left and right exhaust valves 26 and in the valve chamber front wall 83. Hereinafter, a portion forming the secondary air supply passage 81 in the valve chamber front wall 83 is referred to as a passage formation portion 84. Here, the valve chamber front wall 83 is formed with a spring accommodating portion 85 that changes into a convex trapezoidal shape so as to avoid the valve spring 26 b for each exhaust valve 26. The passage forming portion 84 is formed over the top and bottom of the left and right central portion.

  The passage forming portion 84 has a semicircular cross section from the front and rear surfaces of the spring accommodating portion 85 and protrudes into and out of the valve operating chamber 32. The portion inside (rear side) of the valve operating chamber 32 in the passage forming portion 84 protrudes so as to avoid the left and right valve springs 26b and enters between them. The upper part of the cylinder 4 is made smaller by effectively using the empty space in the valve operating chamber 32 by overlapping the part with the side view of the cylinder.

The secondary air supply passage 81 is formed so as to be parallel to the stem 26 a of each exhaust valve 26. Therefore, when the stem insertion hole is formed in the cylinder head 10, the secondary air supply passage 81 can be formed in the same process while keeping the angle of the cylinder head 10 as it is.
The secondary air supply passage 81 extends vertically in the front part of the cylinder head 10 (part of the front part of the head cover 11), and the upper part is located on the front side in the vertical direction when the engine 1 is mounted on the vehicle. (See FIGS. 1 and 2), and is further inclined with respect to the cylinder axis C2 so that the upper part is located on the front side.

The lower end of the secondary air supply passage 81 opens to the upper inner wall of the exhaust port 23, and fresh air from an air cleaner case (not shown) is discharged from the secondary air supply passage 81 into the exhaust gas in the exhaust port 23. It can be supplied.
Referring also to FIG. 7A, the lower end opening 86 of the secondary air supply passage 81 is located immediately downstream of the separation partition wall 23 c in the exhaust port 23. In other words, the lower end opening 86 of the secondary air supply passage 81 is located at the junction of the upstream exhaust passages 23 a in the exhaust port 23.

  The exhaust port 23 shown in FIG. 7 (a) extends forward from each exhaust combustion chamber side opening 24 toward the exhaust pipe side opening 34 without being biased left and right, but is shown in FIG. 7 (b). Like the exhaust port 23 ′, for example, it may extend forward from each exhaust combustion chamber side opening 24 while curving to the left or right to avoid a vehicle body frame or the like. At this time, the separation partition wall 23c is similarly curved along the exhaust passages 23a and 23b. In this manner, the exhaust air purification performance can be further improved by opening the secondary air supply passage 81 at the curved middle portion of the curved exhaust port 23 '.

  The valve housing chamber 82 is provided in front of the valve valve chamber upper wall 87 (head cover 11 upper wall) and immediately above the secondary air supply passage 81, and has a rectangular shape that is long in the front-rear direction when viewed from above along the cylinder axis C2. The front-rear width is from the passage formation portion 84 to the exhaust-side rocker shaft 47, and the left-right width is until it wraps inside the valve spring 26b of the left-right exhaust valve 26.

  A lower changing portion 88 is formed on the valve operating chamber upper wall 87 by changing the rectangular range downward (inside the valve operating chamber 32), and an upper opening portion of the lower changing portion 88 is a valve lid member 89. The valve housing chamber 82 is configured by being closed with a valve. In such a valve storage chamber 82, a thin plate-like reed valve 90 that is generally aligned with the inside of the upper open portion of the downward changing portion 88 is disposed.

  The reed valve 90 is a mechanical type that normally closes the secondary air supply path 81 and opens the secondary air supply path 81 when the pressure in the exhaust port 23 is negative, and can appropriately supply secondary air into the exhaust port 23. And The form of the reed valve 90 is not particularly limited, and may be an electric type that operates using, for example, a solenoid.

  An air introduction passage 91 extending rearward above the head cover 11 is provided at the rear portion of the valve lid member 89. The air introduction passage 91 has a tubular shape, and a secondary air supply hose extending from an air cleaner case (not shown) is connected to the air introduction passage 91. When the engine 1 is mounted on the vehicle, the air introduction passage 91 is disposed so as to incline rearwardly with respect to the horizontal direction (see FIGS. 1 and 2), and is substantially orthogonal to the cylinder axis C2 in a side view. Be placed.

  As shown in FIG. 8, the camshaft 37 protrudes leftward from the intake side and exhaust side cams 38 and 39 arranged side by side at the approximate center of the valve operating chamber 32 and the left side of the intake side cam 38 located on the left side. The left journal 92 includes a right shaft portion 93 protruding rightward from the right side of the exhaust side cam 39 located on the right side, and a right journal 94 protruding further rightward from the right side of the right shaft portion 93. .

The left journal 92 constitutes the left end portion of the cam shaft 37, and the left ball bearing 40 is attached to the outer periphery of the left journal 92 by press fitting or the like. On the other hand, the right journal 94 constitutes the right end portion of the camshaft 37, and the right ball bearing 41 is attached to the outer periphery of the right journal 94 by press-fitting or the like. A decompression mechanism 95 that opens the exhaust valve 26 during the compression process at the time of starting the engine is attached to the outer periphery of the right shaft portion 93 so as to be adjacent to the right side of the exhaust side cam 39.
The right journal 94 passes through the right ball bearing 41 and protrudes further to the right. A flange member 96 for attaching the cam driven sprocket 42 is attached to the outer periphery of the right journal 94 by press fitting or the like.

The cam shaft 37 is inserted into the cylinder head 10 (in the valve operating chamber 32) from the right side along the rotational axis C3 in a state where the above-described components are attached in advance.
Referring also to FIG. 9, a right insertion hole 97 through which the camshaft 37 to which the above-described components are attached can be inserted in the right side portion (outer wall of the cam chain chamber 52) of the cylinder head 10. In the cylinder head 10, a left cam bearing 98 that rotatably supports the left journal 92 of the camshaft 37 via the left ball bearing 40 is integrally formed, and the right journal 94 of the camshaft 37 is A right cam bearing 99 that is rotatably supported via a bearing 41 is integrally formed.

  The left cam bearing 98 has a shallow cup shape opened to the camshaft 37 side (right side), and the outer periphery of the left ball bearing 40 is fitted to the inner periphery thereof to hold it. The left cam bearing 98 is adjacent to the right side of the plug hole 29, and the bottom wall of the left cam bearing 98 constitutes a part of the inner wall of the plug hole 29.

  On the other hand, the right cam bearing 99 is provided substantially above the inner wall 52a of the cam chain chamber 52, has an insertion hole corresponding to the right ball bearing 41, and an outer periphery of the right ball bearing 41 on the inner periphery of the insertion hole. Is fitted and held. Here, the right ball bear rig has an outer diameter larger than the maximum diameter of the left ball bearing 40, each of the cams 38 and 39, and the decompression mechanism 95, and when inserting the cam shaft 37 into the cylinder head 10, The left ball bearing 40 located on the left side of the right ball bearing 41, the cams 38 and 39, and the decompression mechanism 95 can pass through the right cam bearing 99.

  When inserting the camshaft 37 into the cylinder head 10, first, the ball bearings 40, 41 and the decompression mechanism 95 are attached to the camshaft 37 in advance, and the camshaft 37 in this state is inserted into the cylinder head 10 from the right insertion hole 97. Is inserted along the rotation axis C3 so that the left ball bearing 40, the cams 38 and 39, and the decompression mechanism 95 pass through the right cam bearing 99, and then the left ball bearing 40 is inserted into the left cam bearing 98. The bearings 41 are inserted and held in the right cam bearing 99, respectively. Hereinafter, the right end of the camshaft 37 may be referred to as the front end, and the left end may be referred to as the back end.

  Next, the cam driven sprocket 42 is inserted into the cylinder head 10 from above and fastened to the flange member 96. This fastening operation can be performed from the right insertion hole 97. Thereafter, the lid member 101 is attached to the right insertion hole 97 and closed to complete the attachment of the camshaft 37 into the valve operating chamber 32. The end of the right journal 94 of the camshaft 37 protrudes from the right end of the flange member 96 by about half the thickness of the cam-driven sprocket 42, and this protruding portion fits into the central hole of the cam-driven sprocket 42. This facilitates the mounting operation of the cam driven sprocket 42.

  Each of the rocker shafts 46 and 47 is formed with notches 103 corresponding to fastening bolts 102 for fixing the rocker shafts 46 and 47 to the shaft support portions 48 and 49 at both ends of, for example, a circular steel pipe having a predetermined length. Each fastening bolt 102 passes through the shaft support portions 48 and 49 from above and is screwed to the ceiling forming portion 27, and a thread is engraved only at the tip side thereof.

  Each fastening bolt 102 corresponding to the intake-side rocker shaft 46 is offset forward (opposite to the camshaft 37) with respect to the rocker shaft 46, and the intake-side rocker shaft is avoided so as to avoid these fastening bolts 102. The notches 103 having a semicircular cross section along the outer shape of each fastening bolt 102 are formed on the front sides of both end portions of 46. On the other hand, the fastening bolts 102 corresponding to the exhaust-side rocker shaft 47 are offset rearward (opposite to the camshaft 37) with respect to the rocker shaft 47, and the exhaust side so as to avoid the fastening bolts 102. A notch 103 having a semicircular cross section along the outer shape of each fastening bolt 102 is formed on the rear side of both ends of the rocker shaft 47.

The rocker shafts 46 and 47 are inserted into the cylinder head 10 along the axes C4 and C5 from the right side, respectively, like the camshaft 37.
On the right side of the cylinder head 10, an upper right insertion hole 104 that can pass through the rocker shafts 46 and 47 is formed side by side. Referring also to FIG. 4, in the cylinder head 10, left shaft support portions 48 and 49 for integrally inserting and supporting the left end portions of the rocker shafts 46 and 47 are integrally formed. , 47 through which the right end portions of the right shaft support portions 48, 49 are integrally formed.

  The left shaft support portions 48, 49 are provided corresponding to the rocker shafts 46, 47 on the left side of the left cam bearing 98, and extend from the ceiling forming portion 27, which is the base portion of the cylinder head 10, to the G surface. It is provided standing up to. The left shaft support portions 48 and 49 are connected to each other via an intermediate rib 48 a and a left cam bearing 98. Here, the cylinder head 10 is formed with a head fastening portion 105 at each corner for fixing the cylinder head 10 to the crankcase 3 together with the cylinder body 9 using the stud bolt 12. The left shaft support portions 48 and 49 adjacent to each other are connected via an outer rib 48b. The right ends of the left shaft support portions 48 and 49 are left thrust support portions 106 that are in sliding contact with the left ends of the rocker arms 35 and 36.

  On the other hand, the right shaft support portions 48 and 49 are provided corresponding to the rocker shafts 46 and 47 on the right side of the right cam bearing 99, and extend from the ceiling forming portion 27 of the cylinder head 10 to the G plane. It is provided standing up to. The right shaft support portions 48 and 49 are connected to each other via an intermediate rib 49a and a left cam bearing 98, and also connected to the adjacent head fastening portion 105 via an outer rib 49b. On the left side of the right shaft support portions 48 and 49, a right thrust support portion 107 that slides on the right end of each rocker arm 35 and 36 is projected.

  When inserting the rocker shafts 46 and 47 into the cylinder head 10, first, they are inserted into the cylinder head 10 from the upper right insertion holes 104 along the axes C 4 and C 5, and the left ends of the rocker shafts 46 and 47 are inserted. Are inserted and held in the left shaft support portions 48 and 49, and the right end portion is inserted and held in the right shaft support portions 48 and 49, respectively. In this state, by inserting the fastening bolts 102 into the shaft support portions 48 and 49 from above, the movement of the rocker shafts 46 and 47 in the axial direction and the rotation around the axial line are regulated and the fastening of each fastening By tightening the bolts 102 into the cylinder head 10, the rocker shafts 46 and 47 are fixedly held by the shaft support portions 48 and 49 by these fastening forces. Thereafter, the plugs 108 are attached to the upper right insertion holes 104 to close them, whereby the attachment of the rocker shafts 46 and 47 to the cylinder head 10 is completed.

  Here, each fastening bolt 102 reaches from the G surface of the cylinder head 10 to the ceiling forming portion 27 which is the base thereof, and is tightened thereto, whereby the shaft support portions 48 and 49 of the cylinder head 10 made of aluminum die cast. Are reinforced by steel fastening bolts 102. As a result, the reaction force against the rocker arms 35 and 36 and the rocker shafts 46 and 47 generated when the valve is driven can be received even at a deep position of the cylinder head 10 via the fastening bolts 102. It becomes easy to disperse to the whole, and the support rigidity of each rocker shaft 46, 47 can be kept good.

  The camshaft 37 has a hollow shape by having the camshaft oil passage 111 on the rotation axis C3. The camshaft oil passage 111 is formed from the front end (right end) of the camshaft 37 to, for example, between the cams 38 and 39. On the back side (left side) of the oil passage 111 in the camshaft, for example, an oil hole 112 that opens on the outer peripheral surface between the cams 38 and 39 is formed. On the other hand, the upper end of the cylinder oil passage 77 is opened at the inner periphery of the lower end of the right insertion hole 97 of the cylinder head 10, and the cylinder oil passage 77 and the cam shaft oil passage 111 are connected to the lid member 101. The oil can be supplied to each oil supply location of the camshaft 37 by communicating with each other via the in-lid oil passage 113 formed therein. Hereinafter, the portion formed on the right side of the cylinder head 10 in the cylinder oil passage 77 may be referred to as a head oil passage 77a.

The lid member 101 has a circular shape in a side view like the right insertion hole 97, and a boss portion 114 protrudes toward the camshaft 37 on the left side of the center portion, and the tip of the boss portion 114 is a thrust receiving member. It contacts the front end of the camshaft 37 via 115. The lid member 101 oil-tightly closes the right insertion hole 97 through an O-ring 101a that is in close contact with the inner periphery of the right insertion hole 97.
Referring to FIGS. 10A and 10B together, the thrust receiving member 115 includes a perforated disk-shaped thrust receiving body 116 and the right side (the lid member 101 side) from the inner periphery of the thrust receiving body 116. And a cylindrical collar portion 117 protruding toward the surface. The collar portion 117 is inserted inside the tip end of the boss portion 114, and the outer periphery of the collar portion 117 and the inner periphery of the boss portion 114 are fitted so that they can be relatively moved in the axial direction of the camshaft 37.

  The lid member 101 and the thrust receiving member 115 are connected to each other via a spring pin 118 that vertically penetrates the boss portion 114 and the collar portion 117 while the boss portion 114 and the collar portion 117 are fitted to each other. The spring pin 118 has a C-shaped cross section, and has a predetermined gap between both side edges facing each other in the circumferential direction, and the both side edges are, for example, formed in a corrugated shape. On the other hand, boss side insertion holes through which the spring pins 118 are elastically reduced in diameter are formed above and below the boss portions 114, and the collar side on which the spring pins 118 are loosely fitted above and below the collar portions 117. An insertion hole is formed.

Then, by inserting the spring pin 118 into the boss portion 114 and the collar portion 117 so as to pass through them, the lid member 101 and the thrust receiving member 115 are connected via the spring pin 118. At this time, the thrust receiving member 115 is movable in the axial direction of the camshaft 37 within a range of play between the collar side insertion hole and the spring pin 118.
Further, a coil spring 115a is contracted in the boss portion 114, and the thrust receiving member 115 is urged toward the camshaft 37 with respect to the lid member 101 by the elastic force of the coil spring 115a.

  When the lid member 101 is attached to the cylinder head 10 with the boss portion 114 and the collar portion 117 connected by the spring pin 118 as described above, the thrust receiving member 115 elastically contacts the front end of the camshaft 37. . That is, the camshaft 37 is urged toward the back end by the elastic force of the coil spring 115a and the movement toward the front end is restricted, so that the front end of the camshaft 37 is supported by the lid member 101 in the thrust direction. It becomes a state. At this time, the thrust receiving member 115 comes into contact with the front end of the cam shaft 37 at the inner peripheral position of the cam driven sprocket 42.

As shown in FIG. 8, an oil passage forming portion 119 extending vertically is formed below the base end side of the boss portion 114 of the lid member 101, and the oil passage forming portion 119 is vertically moved along the oil passage forming portion 119. An extending vertical oil passage 120 is formed. A hollow portion 121 that opens to the camshaft 37 side is formed in the boss portion 114, and the hollow portion 121 and the vertical oil passage 120 communicate with each other, so that, for example, L in the lid member 101 is viewed from the front of the cylinder. The in-lid oil passage 113 that is bent in a letter shape is formed.
The lower end of the in-lid oil passage 113 opens to the outer periphery of the lower end of the lid member 101, and this lower end opening 86 is located inside the head at the inner periphery of the lower end of the right insertion hole 97 when the lid member 101 is attached to the cylinder head 10. By facing the upper end opening of the oil passage 77a, the in-head oil passage 77a and the in-lid oil passage 113 communicate with each other.

Further, when the lid member 101 is attached to the cylinder head 10, the opening at the tip of the boss 114 of the in-lid oil passage 113 is connected to the opening at the front end of the cam shaft 37 of the in-shaft oil passage 111 via the thrust receiving member 115. The camshaft oil passage 111 and the lid oil passage 113 communicate with each other.
That is, by attaching the lid member 101 to the cylinder head 10, the head internal oil passage 77 a and the camshaft internal oil passage 111 communicate with each other via the lid internal oil passage 113. Engine oil pumped to the oil passage 77 is supplied to each oil supply location of the camshaft 37 through the in-lid oil passage 113 and the camshaft oil passage 111. At this time, since the contact position between the thrust receiving member and the camshaft 37 is the inner peripheral position of the cam driven sprocket 42, the cam driven sprocket 42 can be lubricated by the oil overflowing from the corresponding contact position. The spring pin 118 has a sufficiently small diameter with respect to the oil passage cross-sectional area, and does not hinder the oil flow to the camshaft 37 (see FIG. 10B).

  As described above, the exhaust purification secondary air supply apparatus in the above embodiment includes at least two exhaust valves 26, an exhaust port 23 that guides exhaust from each exhaust valve 26, and an upstream side of the exhaust port 23. Applied to the cylinder head 10 including a separation partition wall 23c that separates the exhaust gas into an upstream exhaust passage 23a corresponding to each exhaust valve 26 and a secondary air supply passage 81 that supplies secondary air to the exhaust port 23. The secondary air supply passage 81 is opened downstream of the exhaust port 23 immediately after the separation partition wall 23c and is formed in parallel with at least one of the exhaust valves 26.

According to this configuration, since the secondary air supply passage 81 is opened immediately downstream of the separation partition wall 23c of the exhaust port 23, the secondary air supply opening and each exhaust valve 26 can be made as close as possible. The secondary air can be positively introduced into the exhaust port 23 by effectively utilizing the negative pressure associated with the opening and closing of each exhaust valve 26.
In addition, the secondary air supply passage 81 and the exhaust valve 26 insertion hole can be easily processed in the same process, and the number of processing steps of the cylinder head 10 can be reduced. The valve 26 can be disposed adjacently, and the exhaust purification performance can be improved by mixing the exhaust and the secondary air at a high temperature.

  Further, in the exhaust purification secondary air supply device, the reed valve 90 that controls the flow of air to the secondary air supply passage 81 almost directly above the secondary air supply passage 81 in the cylinder head 10. An air introduction passage 91 to the valve is disposed in the front-rear direction of the cylinder head 10, and the secondary air supply passage 81 is inclined forward at the front portion of the cylinder head 10. By arrange | positioning, the reed valve 90, the air introduction channel | path 91, and the secondary air supply channel | path 81 can be arrange | positioned in the high place of the engine 1, and can improve the protection property from a flying stone etc.

The present invention is not limited to the above-described embodiments, and can be applied to, for example, a cylinder tilted rearward or left and right, for example, a cylinder disposed substantially horizontally toward the front rather than a forward tilted cylinder. Moreover, the structure which inserts a cam shaft from the left side of a cylinder head may be sufficient, and the insertion direction is not limited to the left-right direction. Furthermore, the present invention can be applied to a DOHC (double overhead camshaft) type engine as well as a multi-cylinder engine such as a parallel or V-type engine or a vertically mounted engine having a crankshaft along the vehicle longitudinal direction. .
The configuration in the above embodiment is an example of the present invention, and it goes without saying that various modifications can be made without departing from the gist of the present invention.

It is a left view of the engine in the Example of this invention. It is a right view of the said engine. It is an expanded sectional view of the above-mentioned engine. It is a top view in the cylinder head of the engine. It is an expanded sectional view around the oil pump of the engine. FIG. 2 is an enlarged view around a cylinder head in FIG. 1. It is explanatory drawing of the exhaust port of the said engine, (a) shows the thing of this Example, (b) shows the modification of this Example. FIG. 4 is an enlarged view around a cylinder head in FIG. 3. It is A arrow directional view of FIG. It is explanatory drawing of a part of lid member attached to the said cylinder head, and the thrust receiving member attached to this, (a) is a disassembled perspective view, (b) is BB sectional drawing of (a). It is a left view of the vehicle in the Example of this invention.

Explanation of symbols

1 Engine 10 Cylinder head 23, 23 'Exhaust port 23a Upstream exhaust passage (exhaust passage)
23c Separation partition 26 Exhaust valve 81 Secondary air supply passage 90 Reed valve (valve)
91 Air introduction passage

Claims (4)

One camshaft (37), at least two exhaust valves (26), an exhaust port (23) for guiding exhaust from each exhaust valve (26), and an upstream side of the exhaust port (23) A separation partition wall (23c) that separates into an exhaust passage (23a) corresponding to each exhaust valve (26), and a secondary air supply passage (81) that supplies secondary air to the exhaust port (23), The stem (25a) of the intake valve (25) and the stem (26a) of each exhaust valve (26) sandwiching the cam shaft (37) are viewed from the side of the cylinder as viewed from the axial direction of the cam shaft (37). The cylinder of the SOHC engine that extends in a V shape and the power of the cam shaft (37) is transmitted to the intake valve (25) and the exhaust valves (26) via the rocker arms (35, 36). Exhaust of the head (10) In the secondary air supply device for reduction,
The secondary air supply passage (81) opens downstream of the exhaust port (23) immediately after the separation partition wall (23c) and is formed in parallel with at least one of the exhaust valves (26).
The cylinder head (10) expands along the stem (25a, 26a) of the intake valve (25) and each exhaust valve (26) in a side view of the cylinder, while the intake valve (25) and each exhaust valve (26). ) Extends upward from the stem tip in the cylinder axial direction,
When viewed from the top of the cylinder, a passage forming portion (84) formed in the cylinder head (10) in the secondary air supply passage (81) and a valve spring (26b) of each exhaust valve (26) At least a part of the valve accommodating part (82) accommodating the reed valve (90) for controlling the flow of air to the secondary air supply passage (81) is disposed,
The passage forming portion (84) is formed up to the upper end (G) of the cylinder head (10),
The secondary air supply device for exhaust purification, wherein the passage forming portion (84) and the valve spring (26b) of each exhaust valve (26) overlap each other at least partially in a side view of the cylinder. The secondary air supply passage (81) is disposed to be inclined forward in the front portion of the cylinder head (10);
On the front wall of the valve chamber of the cylinder head (10), there is formed a spring accommodating portion (85) which is changed into a convex trapezoidal shape so as to avoid the valve spring (26b) of each exhaust valve (26). The secondary air supply device for exhaust purification according to claim 1, wherein the passage forming portion (84) is formed over the upper and lower sides of the left and right central portion of the spring accommodating portion (85).   The exhaust port (23) is formed to be curved to one side of the cylinder head (10), and the separation partition wall (23c) is also formed to be curved along the exhaust port (23). The secondary air supply device for exhaust purification according to claim 1 or 2, wherein the secondary air supply passage (81) opens downstream immediately after the separation partition wall (23c). An air introduction passage to the reed valve (90) is arranged in the front-rear direction of the cylinder head (10);
When viewed from above, an arm portion extending toward the stem tip of each exhaust valve (26) in the rocker arm (36) for each exhaust valve (26) is provided avoiding the valve housing portion (82). The secondary air supply device for exhaust purification according to any one of claims 1 to 3, wherein the secondary air supply device is for exhaust purification.

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