JP4083026B2 - Internal combustion engine - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an internal combustion engine provided with a decompression mechanism provided in a camshaft constituting a valve operating mechanism and disposed in a valve operating chamber. The internal combustion engine is used, for example, in an outboard motor.
[0002]
[Prior art]
As an internal combustion engine provided with a decompression mechanism, for example, there is an internal combustion engine for an outboard motor disclosed in Patent Document 1. The two-cylinder internal combustion engine includes a camshaft disposed in a cam chamber formed between a cylinder head and a head cover, an intake valve cam and an exhaust valve cam formed on the camshaft, and the cams are shaken by the cams. A rocker arm to be moved, a decompressor mounted on the camshaft so as to be rotatable in the vertical direction below the exhaust valve cam, and a fuel pump. The decompressor has a decompression cam at its upper part and weights at both sides of its lower part. When the engine speed increases, the decompressor swings so that the weight moves radially outward by centrifugal force.
[0003]
On the other hand, a three-cylinder internal combustion engine for an outboard motor disclosed in Patent Document 2 is provided with a cam shaft that is disposed on a cylinder head and supported by a plurality of bearings, and a cam that is provided on the cam shaft and rocks a rocker arm. And a fuel pump driven via a driven rod that is advanced and retracted by an eccentric cam provided on the cam shaft. The fuel pump is attached to the side of the cylinder head.
[0004]
[Patent Document 1]
Japanese Patent Laid-Open No. 2000-227064 (FIGS. 4 and 5)
[Patent Document 2]
Japanese Patent Laid-Open No. 3-3904
[Problems to be solved by the invention]
Incidentally, when the fuel pump is driven by a cam provided on the cam shaft (hereinafter referred to as a pump cam), as shown in the prior art of Patent Document 2, the driving force of the pump cam is transmitted to the fuel pump. Therefore, a driven rod that is a pump cam follower that abuts an eccentric cam that is a pump cam is provided. However, when the decompressor as in the prior art of Patent Document 1 is provided adjacent to the pump cam, it is necessary to dispose the decompressor and the pump cam so that the swinging decompressor does not interfere with the cam follower. Therefore, the camshaft becomes longer and the valve chamber becomes larger in the axial direction.
[0006]
The present invention has been made in view of such circumstances, and the invention according to claims 1 and 2 is arranged in the valve operating chamber after avoiding interference between the pump cam and the decompression mechanism. It is an object of the present invention to reduce the size of an internal combustion engine by suppressing an increase in the length of a camshaft on which a cam for use and a decompression mechanism are provided, and consequently suppressing an increase in the size of a valve operating chamber in the axial direction.
[0007]
[Means for Solving the Problems and Effects of the Invention]
According to the first aspect of the present invention, a valve operating mechanism that opens and closes an intake valve and an exhaust valve, and a decompression mechanism that opens and closes the intake valve or the exhaust valve during a compression stroke are disposed in the valve operating chamber, and the valve operating chamber is In the internal combustion engine in which the valve chamber forming member to be formed is provided with a fuel pump, the valve mechanism has a cam shaft that rotates in conjunction with a crankshaft and is disposed in the valve chamber, and the camshaft Is provided with a pump cam having a cam surface formed on its peripheral surface that contacts a pump cam follower to drive the fuel pump, and the decompression mechanism. The decompression mechanism is axially connected to the pump cam. And a centrifugal weight that is swingably supported by the camshaft, and the centrifugal weight is disposed on the cam crest side of the pump cam as viewed from the axial direction. The cam shaft When the rotational speed increases, an internal combustion engine which swings in the direction approaching the maximum high of the cam nose relative to the rotational center line of the cam shaft.
[0008]
As a result, when the engine rotational speed increases at the time of starting, the centrifugal weight arranged on the cam crest side swings in the direction approaching the maximum high-order part that is farthest from the rotation center line, so from the axial direction. The swing range until the centrifugal weight overlaps with the cam surface is larger than when the centrifugal weight is placed on a portion other than the cam crest side of the pump cam and swings radially outward. .
[0009]
As a result, according to the first aspect of the present invention, the following effects can be obtained. In other words, the centrifugal weight of the decompression mechanism that is located adjacent to the pump cam in the axial direction and is swingably supported by the cam shaft is arranged on the cam peak portion side of the pump cam as viewed from the axial direction. At the same time, when the rotational speed of the cam shaft increases, the centrifugal weight overlaps with the cam surface as viewed from the axial direction by swinging in the direction approaching the maximum height portion of the cam peak with respect to the rotational center line of the cam shaft. The swing cam range can be increased, so that interference between the centrifugal weight and the pump cam follower is avoided in the set swing range of the centrifugal weight, and the pump cam and decompression mechanism are placed close to each other. Thus, the camshaft can be prevented from becoming longer, and the increase in size in the axial direction of the valve operating chamber can be suppressed, and the internal combustion engine can be made compact.
[0010]
According to a second aspect of the present invention, a valve operating mechanism that opens and closes an intake valve and an exhaust valve and a decompression mechanism that opens and closes the intake valve or the exhaust valve during a compression stroke are disposed in the valve operating chamber, and the valve operating chamber is In the internal combustion engine in which the valve chamber forming member to be formed is provided with a fuel pump, the valve mechanism has a cam shaft that rotates in conjunction with a crankshaft and is disposed in the valve chamber, and the camshaft Is provided with a pump cam having a cam surface formed on its peripheral surface that contacts a pump cam follower to drive the fuel pump, and the decompression mechanism. The decompression mechanism is axially connected to the pump cam. And has a centrifugal weight supported by the cam shaft so as to be movable in the radial direction, and the centrifugal weight moves within a range of the cam surface of the pump cam as viewed from the axial direction. Internal combustion A cough.
[0011]
As a result, when viewed from the axial direction, the centrifugal weight does not protrude outward from the cam surface with which the cam follower contacts.
[0012]
As a result, according to the second aspect of the present invention, the following effects can be obtained. That is, the centrifugal weight of the decompression mechanism that is positioned adjacent to the pump cam in the axial direction and supported by the cam shaft so as to be movable in the radial direction is within the range of the cam surface of the pump cam as viewed from the axial direction. By moving, the centrifugal weight does not protrude outwardly from the cam surface when viewed from the axial direction, so avoid interference between the centrifugal weight and the cam follower within the set swing range of the centrifugal weight. The cam for the pump and the decompression mechanism can be arranged close to each other, the camshaft is prevented from being lengthened, and the enlargement of the valve chamber in the axial direction is suppressed, thereby reducing the size of the internal combustion engine. it can.
[0013]
In this specification, “axial direction” means the direction of the rotation center line of the cam shaft unless otherwise specified.
[0014]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of the present invention will be described below with reference to FIGS.
Referring to FIG. 1, which is a schematic right side view of an outboard motor 1 in which the internal combustion engine according to the present invention is used, the internal combustion engine E is a vertical internal combustion engine in which the rotation center line L1 of the crankshaft is directed in the vertical direction. This is a water-cooled overhead camshaft (OHC) type in-line three-cylinder four-stroke internal combustion engine.
[0015]
The internal combustion engine E includes a cylinder block 2 having first to third cylinders C1 to C3 which are three cylinders arranged side by side in a vertical direction, and a crankcase 3 coupled to a front end portion of the cylinder block 2 by a plurality of bolts. A cylinder head 4 coupled to the rear end portion of the cylinder block 2 by a plurality of head bolts B1 (see FIGS. 3 and 4), and a seal surface 4g (see FIG. 3) at the rear end portion of the cylinder head 4 And a head cover 5 coupled by a plurality of bolts screwed into the screw holes 4h (see FIG. 3) through an annular seal 6 (see FIG. 2) that comes into airtight contact.
[0016]
In this embodiment, the top, bottom, front, back, left and right are based on the hull on which the outboard motor 1 is mounted, and the time when the outboard motor 1 is in the state shown in FIG. The upper part is one in the axial direction A1 (that is, the direction of the rotation center line L2 of the camshaft 31), the lower part is the other in the axial direction A1, and the front is the cylinder of each of the cylinders C1 to C3. One side in the direction A2 of the axis L3, and the rear side is the other side in the cylinder axis direction A2. Further, hereinafter, the side on which the intake valve 43 is disposed with respect to a reference plane that includes the cylinder axis L3 and is parallel to the rotation center line L1 of the camshaft 31 or the crankshaft 9 is the intake side, and the exhaust with respect to the reference plane. The side on which the valve 44 is disposed is referred to as the exhaust side.
[0017]
Pistons 7 fitted to the respective cylinders C1 to C3 so as to be capable of reciprocating are connected to a crankshaft 9 via connecting rods 8. The crankshaft 9 is accommodated in a crank chamber 10 formed by the front portion of the cylinder block 2 and the crankcase 3 and is rotatably supported by the cylinder block 2 and the crankcase 3 via a main bearing. A recoil starter 13 having a crank pulley 11, a flywheel 12 constituting a flywheel magneto, and a starter knob 13 a as a starting device is sequentially provided upward at an upper end portion 9 a of the crankshaft 9 protruding upward from the crank chamber 10. It is done.
[0018]
The cylinder block 2 is coupled to the mount case portion 14a of the engine lower case 14 in which the mount case portion 14a and the undercase portion 14b are integrally formed, and the upper end portion of the extension case 15 is coupled to the lower end portion of the engine lower case 14 so as to extend the extension. A gear case 16 is coupled to the lower end of the case 15. The lower part of the internal combustion engine E and the mount case part 14a are covered by an under case part 14b of the engine lower case 14, and the upper part of the internal combustion engine E is coupled to the upper peripheral edge of the engine lower case 14 via a seal. The entire internal combustion engine E is disposed in an engine room formed by the undercase portion 14b and the engine upper cover 17. The engine lower case 14 may be configured by a mount case portion 14a and an undercase portion 14b which are separate bodies.
[0019]
A drive shaft 18 coupled to the crankshaft 9 at its lower end passes through the engine lower case 14 and in the gear case 16 via a forward / reverse switching device 19 comprising a bevel gear mechanism and a clutch mechanism 20 Combined with The power of the internal combustion engine E is transmitted from the crankshaft 9 to the propeller 21 via the drive shaft 18, the forward / reverse switching device 19 and the propeller shaft 20, and the propeller 21 is rotationally driven.
[0020]
A stern bracket 22 for detachably attaching the outboard motor 1 to the hull supports a swivel case 24 swingable in the vertical direction via a tilt shaft 23, and a pipe-like support portion of the swivel case 24. A swivel shaft 26 is rotatably fitted to 24a. The swivel shaft 25 is coupled to the engine lower case 14 via a mount rubber at the upper end thereof, and is coupled to the extension case 15 via a mount rubber at the lower end thereof. Then, by operating a steering handle (not shown) coupled to the swivel shaft 25 to the left and right, the outboard motor 11 is swung left and right about the swivel shaft 25 as a central axis, and steering is performed.
[0021]
Referring also to FIG. 2, in the valve operating chamber 30 formed by the cylinder head 4 and the head cover 5, there is a valve operating mechanism V that has one cam shaft 31 and opens and closes the intake valve 43 and the exhaust valve 44. Decompression mechanisms D1 to D3 for reducing the compression pressure in the cylinders C1 to C3 during the compression stroke at the start of the internal combustion engine E are arranged. Here, the cylinder head 4 and the head cover 5 are valve chamber forming members that form the valve chamber 30.
[0022]
A cam shaft 31 having a rotation center line L2 parallel to the rotation center line L1 (see FIG. 1) of the crankshaft 9 is rotatably supported by the cylinder head 4 in the valve operating chamber 30. The cam shaft 31 passes through the upper wall 4a, which is one end wall of the cylinder head 4 in the axial direction A1, in a state of being sealed by the oil seal 32. A pulse generator 33 and a cam pulley 34 for detecting the rotational position of the cam shaft 31 are sequentially provided upward at an upper end portion 31a of the cam shaft 31 protruding upward from the valve operating chamber 30. The camshaft 31 is moved to the crankshaft 9 by the power of the crankshaft 9 transmitted through the transmission mechanism including the crank pulley 11, the cam pulley 34, and the timing belt 35 spanned between the pulleys 11 and 34. In conjunction with this, it is rotationally driven in the rotational direction A0 (see FIGS. 4 and 6) at half the rotational speed.
[0023]
The pulse generator 33 includes a magnetic body 33a (see FIG. 3) provided on the inner peripheral surface of the cam pulley 34 made of a non-magnetic material, and a coil fixed to the upper wall 4a around the upper end 31a. Unit 33b. The coil unit 33b has three pickup coils that are arranged at equal intervals in the circumferential direction and that sequentially face the magnetic body 33a according to the rotation of the cam shaft 31, and the first to third output signals are output from these pickup coils. The ignition timings of the cylinders C1 to C3 are respectively determined.
[0024]
A lower wall 4b, which is the other end wall of the cylinder head 4 in the axial direction A1, has a rotating shaft 37a connected to the lower end portion of the cam shaft 31 by a connecting portion 36 and driven by the cam shaft 31. A trochoid type oil pump 37 is coupled by a plurality of bolts B2 penetrating the pump body 37b and the pump cover 37c. The lubricating oil stored in the oil pan 38 attached to the lower end portion of the engine lower case 14 passes through the suction pipe 39b provided with the oil strainer 39a, the cylinder block 2 and the cylinder head 4 and the suction oil passage. It is sucked into the oil pump 37 through. Further, the lubricating oil discharged from the oil pump 37 flows into the main gallery through the discharge oil passage formed in the cylinder head 4 and the cylinder block 2 and further through the oil filter, and the main bearing and the like from the main gallery. Supplied to each lubrication point.
[0025]
The internal combustion engine E will be further described with reference to FIGS.
The first to third cylinders C1 to C3 constitute a cylinder row that is continuously located in the axial direction A1. The cylinder row is a second cylinder C2 as an intermediate cylinder located in the middle in the axial direction A1, and the second cylinder C2 is located at both ends in the axial direction A1 of the cylinder row and sandwiches the second cylinder C2. The first and third cylinders C1 and C3 are a pair of end cylinders adjacent to the second cylinder C2, that is, adjacent to the second cylinder C2.
[0026]
Referring also to FIG. 4, one intake that guides intake air from an intake device (not shown) attached to the right wall 4 c that is the intake side wall of the cylinder head 4 to a combustion chamber 40 formed in the cylinder head 4. A port 41 and one exhaust port 42 that guides the combustion gas discharged from the combustion chamber 40 to an exhaust passage (not shown) formed in the cylinder block 2 are formed for each of the cylinders C1 to C3. The intake device includes a carburetor as a fuel supply device that is provided for each of the cylinders C1 to C3 and supplies fuel to the sucked intake air, and an intake manifold that guides the formed air-fuel mixture to the intake port 41. Prepare.
[0027]
Further, the cylinder head 4 is slidably provided with an intake valve 43 for opening and closing the intake port of the intake port 41 and an exhaust valve 44 for opening and closing the exhaust port of the exhaust port 42 for each of the cylinders C1 to C3. The intake valve 43 and the exhaust valve 44 belonging to each of the cylinders C1 to C3 are always urged in the valve closing direction by the resilient force of the valve spring 46.
[0028]
The air-fuel mixture sucked into the combustion chamber 40 from the intake port 41 during the intake stroke toward the bottom dead center when the intake valve 43 is opened is compressed by the piston 7 toward the top dead center during the compression stroke. After that, the piston 7 that is ignited and burned by the spark plug 45 attached above each exhaust valve 44 on the exhaust side of the cylinder head 4 and goes to the bottom dead center by the pressure of the combustion gas in the expansion stroke is connected to the connecting rod 8. Through which the crankshaft 9 is driven to rotate. The combustion gas is discharged as exhaust gas from the combustion chamber 40 to the exhaust port 42 in the exhaust stroke toward the top dead center of the piston 7, and the exhaust gas from each exhaust port 42 is collected in the exhaust passage and then exhausted. Through the outboard motor 1.
[0029]
The valve mechanism V includes a cam shaft 31 extending over three cylinders C1 to C3 in the valve chamber 30, intake cams 47, 49, 51 provided on the cam shaft 31 and belonging to the cylinders C1 to C3, and exhaust. A set of valve cams for each of the first to third cylinders C1 to C3 comprising cams 48, 50 and 52, and a pair of rocker shafts provided on the cylinder head 4 at a position closer to the head cover 5 than the cam shaft 31 As the cam follower driven by the intake cams 47, 49, 51 and the exhaust cams 48, 50, 52, the two rocker shafts 53, 54 swing respectively. An intake rocker arm 55, 57, 59 and an exhaust rocker arm 56, 58, 60 are movably supported, and these components of the valve mechanism V are arranged in the valve chamber 30.
[0030]
The cam shaft 31 is rotatably supported by the plurality of journals 61 to 63 on the same number of bearings 64 to 66 provided in the valve operating chamber 30 as the journals 61 to 63. The plurality of journals 61 to 63 of the camshaft 31 are located at the uppermost part of the valve operating chamber 30 and are formed at positions close to the upper end 31a, and at the lowermost part of the valve operating chamber 30. And a second end journal 63 formed at a position overlapping the lower end 31b of the camshaft 31 in the axial direction A1 and the intermediate between the first and second end journals 61 and 63 in the axial direction A1. And an intermediate journal 62 having an outer diameter larger than both end journals 61 and 63. The plurality of bearings 64 to 66 are integrally formed on the upper wall 4a to support the first end journal 61, and provided on the lower wall 4b to support the second end journal 63. The second end bearing 66 and the intermediate bearing 65 that supports the intermediate journal 62 and is positioned between the both end bearings 64 and 66 in the axial direction A1.
[0031]
The first end bearing 64 and the intermediate bearing 65 are formed of a protrusion that is integrally formed with the cylinder head 4 and protrudes toward the head cover 5, and is provided at a position that overlaps the connecting portion 36 in the axial direction A1. 66 is formed of a cylindrical protrusion 37d that is integrally formed with the pump body 37b and is inserted into the valve operating chamber 30 through the through hole 4e of the lower wall 4b. The bearings 64 to 66 are formed with bearing holes 64b, 65b and 66b into which the journals 61 to 63 supported corresponding to the bearings 64 to 66 are slidably inserted.
[0032]
The cam shaft 31 is a flange that is a restricting portion having a contact surface 67a that contacts the valve chamber end surface 64a in the axial direction A1 of the first end bearing 64 at a position adjacent to the first end journal 61. 67 and a restricting portion having a contact surface 68a in contact with the valve chamber end surface 66a in the axial direction A1 of the second end bearing 66 as a specific bearing at a position adjacent to the second end journal 63. A pump cam 68 formed of a disc-shaped eccentric cam is integrally formed with each other. The flange 67 and the pump cam 68 for driving the fuel pump 74 are in contact with the first and second end bearings 64 and 66, respectively, to restrict the movement of the cam shaft 31 in the axial direction A1. Specifically, when the flange 67 contacts the end surface 64a, the upward movement of the cam shaft 31 is prevented, and when the pump cam 68 contacts the end surface 66a, the downward movement of the cam shaft 31 is prevented. Be blocked.
[0033]
Further, in the camshaft 31, between the flange 67 and the pump cam 68 in the axial direction A1, the intake air belonging to the first cylinder C1 which is one of the end cylinders and is located at the top of the cylinder row. The cam 47 and the exhaust cam 48, the other end cylinder, and the intake cam 51 and the exhaust cam 52 belonging to the third cylinder C3 located at the bottom of the cylinder row, and the intake cam belonging to the second cylinder C2 49 and the exhaust cam 50 are integrally formed on the camshaft 31, respectively.
[0034]
As representatively shown in FIG. 4, the intake cams 47, 49, 51 and the exhaust cams 48, 50, 52 respectively close the intake valve 43 and the exhaust valve 44 that are urged by the valve spring 46. It has a cam surface formed by base circle portions Mi and Me to be maintained and cam peak portions Ni and Ne that define the opening and closing timing and lift amount of the intake valve 43 and the exhaust valve 44.
[0035]
In each of the cylinders C1 to C3, the exhaust valve 44 is opened and closed below the exhaust cams 48, 50, and 52 located below the intake cams 47, 49, and 51 during the compression stroke when the internal combustion engine E is started by the recoil starter 13. Decompression mechanisms D1 to D3 are provided. The decompression mechanisms D1 to D3 open the exhaust valve 44 with a slight decompression lift amount by the decompression cam 92 described later, and discharge the compressed intake air in the cylinders C1 to C3 to the exhaust port 42 to reduce the compression pressure. The operation, that is, the decompression operation is performed.
[0036]
The intake cams 47 and 49, the exhaust cams 48 and 50, and the decompression mechanisms D1 and D2 of the first and second cylinders C1 and C2 are located above the intermediate journal 62 and between the first end journal 61 and the intermediate journal 62. The intake cam 51, the exhaust cam 52, and the decompression mechanism D3 of the third cylinder C3 are positioned below the intermediate journal 62 and between the intermediate journal 62 and the second end journal 63. 1 to 3, the portions near the decompression mechanisms D1 to D3 of the camshaft 31 are depicted as views seen from an angle different from the portions of the surrounding camshaft 31. 6, the cam shafts 31 are arranged at equal intervals in the rotation direction A0.
[0037]
Therefore, among the intake cam 49, the exhaust cam 50 and the decompression mechanism D2 belonging to the second cylinder C2, one of the intake cam 49 positioned closest to the first cylinder C1 and a pair of adjacent cylinders adjacent to the second cylinder C2. The inter-cylinder portion of the camshaft 31 formed between the intake cam 47, the exhaust cam 48 and the decompression mechanism D1 that are located closest to the second cylinder C2 of the first cylinder C1 as adjacent cylinders. A bearing for rotatably supporting the camshaft 31 is not disposed in 31c, and therefore no journal is formed.
[0038]
Further, the intake cam 49, the exhaust cam 50 and the decompression mechanism D2 belonging to the second cylinder C2 are adjacent to and immediately below the decompression mechanism D1 of the intake cam 47, the exhaust cam 48 and the decompression mechanism D1 belonging to the first cylinder C1. Among them, an intake cam 49 is provided. Therefore, the portion of the cam shaft 31 that is provided adjacent to the decompression mechanism D1 of the first cylinder C1 in the axial direction A1 is the intake cam 49 of the second cylinder C2, and the centrifugal weight 91 and the intake cam 49 of the decompression mechanism D1. Are arranged close to each other in the axial direction A1.
[0039]
On the other hand, among the intake cam 49, the exhaust cam 50, and the decompression mechanism D2 belonging to the second cylinder C2, the decompression mechanism D2 located closest to the third cylinder C3 and the second neighboring cylinder as the other neighboring cylinder of the pair of neighboring cylinders. The inter-cylinder portion 31d of the cam shaft 31 located between the intake cam 51 belonging to the three cylinders C3, the exhaust cam 52 and the intake cam 51 located closest to the second cylinder C2 of the decompression mechanism D3 includes an intermediate journal. 62 is formed, and an intermediate bearing 65 is disposed.
[0040]
The intake cam 51, the exhaust cam 52, and the decompression mechanism D3 belonging to the third cylinder C3 include a second end bearing 66 and an intermediate bearing 65 that is a bearing adjacent to the second end bearing 66 in the axial direction A1. It is arranged between. The decompression mechanism D3 of the intake cam 51, the exhaust cam 52, and the decompression mechanism D3 is adjacent to the pump cam 68 on the opposite side to the second end bearing 66 in the axial direction A1 with respect to the pump cam 68. Arranged.
[0041]
The intake cam 49 of the second cylinder C2 is configured so that the intake cam 47 of the first cylinder C1 and the intake cam 51 of the third cylinder C3 are separated from the position in the axial direction A1 by half. Similarly, the exhaust cam 50 of the second cylinder C2 is located closer to 47 than the position that bisects the interval in the axial direction A1 between the exhaust cam 48 of the first cylinder C1 and the exhaust cam 52 of the third cylinder C3. Is located closer to the exhaust cam 48 of the first cylinder C1. In the second cylinder C2, the decompression mechanism D2 is disposed in the space in the axial direction A1 formed by providing the intake cam 49 and the exhaust cam 50 at positions displaced toward the first cylinder C1 as described above. .
[0042]
The cam shaft 31 is attached to the cylinder head 4 as follows. First, the camshaft 31 to which the decompression mechanisms D1 to D3 are mounted is formed in a through hole 4e having an inner diameter larger than the outer diameter of the intermediate journal 62 from the lower side to the upper side, and is formed in a shaft support portion 69 to be described later. The journal 62 is sequentially inserted into a through hole 69 a having a diameter larger than the outer diameter of the journal 62, a bearing hole 65 b of the intermediate bearing 65, and a bearing hole 64 b of the first end bearing 64. The oil pump 37 is inserted so that the second end journal 63 is inserted into the bearing hole 66b of the second end bearing 66 in a state where the contact surface 67a of the flange 67 is in contact with the first end bearing 64. Is coupled to the lower wall 4b.
[0043]
2 to 5, each rocker shaft 53, 54 has a through hole 4f, 4g formed in the lower wall 4b, and the cylinder head 4 in the middle in the axial direction A1 between the lower wall 4b and the intermediate bearing 65. Are inserted into a pair of through-holes 69f and 69g (see FIGS. 3 and 5) formed in a shaft support portion 69 formed of a protruding portion that protrudes toward the head cover 5, and further includes an intermediate bearing 65 and a Inserted upward from the openings of the through holes 4f and 4g in the lower wall 4b so as to be inserted through a pair of through holes 65f and 65g; 64f and 64g respectively formed in the one end bearing 64. Then, as shown in FIG. 4, the rocker shaft is inserted into the rocker shaft 53 by a bolt B3 that passes through the notches 53a and 54a formed in the portions of the rocker shafts 53 and 54 inserted into the intermediate bearing 65 and is screwed into the intermediate bearing 65. The rotation of the rockers 53 and 54 is restricted, and the rocker shafts 53 and 54 are further prevented from being removed.
[0044]
2 to 4, at one end portion of each intake rocker arm 55, 57, 59, a distal end portion 43a of the valve stem of the intake valve 43 (note that a distal end portion 43a against which the intake rocker arm 57 abuts is denoted by reference numeral 43A. Adjustment screws 55a, 57a, 59a having a tip portion (only the tip portion 57a1 is shown in FIG. 4) as an action portion that abuts on the abutting portion constituted by Slippers 55b, 57b, and 59b as contact portions that contact the intake cams 47, 49, and 51 are provided at the end, and further formed between the adjusting screws 55a, 57a, and 59a and the slippers 55b, 57b, and 59b. There are provided fulcrum portions 55c, 57c, 59c in which through holes through which the intake rocker shaft 53 is inserted are formed.
[0045]
On the other hand, one end portion of each exhaust rocker arm 56, 58, 60 is constituted by a tip end portion 44a of the valve stem of the exhaust valve 44 (note that the tip end portion 44a with which the exhaust rocker arm 58 abuts is indicated by reference numeral 44A for convenience). Adjustment screws 56a, 58a, 60a having a tip portion (only the tip portion 58a1 is shown in FIG. 4) as an action portion that abuts against the abutting portion are provided, and an exhaust cam is provided at the other end portion. Slippers 56b, 58b, and 60b are provided as contact portions that come into contact with 48, 50, and 52, and formed between the adjusting screws 56a, 58a, and 60a and the slippers 56b, 58b, and 60b, and the exhaust rocker shaft 54 is inserted therethrough. The fulcrum portions 56c, 58c, and 60c in which through holes are formed are provided.
[0046]
The intake rocker shaft 53 and the exhaust rocker shaft 54 are positioned to define the positions in the axial direction A1 of the intake rocker arms 55, 57, 59 and the exhaust rocker arms 56, 58, 60 belonging to the cylinders C1 to C3, respectively. A collar 70 and a positioning spring 71 are fitted.
[0047]
The intake rocker arm 57 and the exhaust rocker arm 58 belonging to the second cylinder C2 are respectively positioned closer to the decompression mechanism D2 in the axial direction A1 from the slippers 57b and 58b, here in the positions biased downward from the slippers 57b and 58b. It is a specific rocker arm having the tip of 58a. Among them, the exhaust rocker arm 58 is provided at a position where the tip of the adjusting screw 58a and the decompression mechanism D2 overlap in the axial direction A1. Further, the tip end portion 57a1 of the adjusting screw 57a of the intake rocker arm 57 and the tip end portion 43A of the intake valve 43 and the exhaust cam 50 are provided at positions where they overlap in the axial direction A1. Therefore, in each of the intake rocker arm 57 and the exhaust rocker arm 58, the straight line connecting the slippers 57b, 58b and the tip of the adjustment screws 57a, 58a is inclined upward with respect to the intake rocker shaft 53 and the exhaust rocker shaft 54. Will be.
[0048]
Further, the exhaust cam 50 as a specific valve cam that opens and closes the exhaust valve 44 belonging to the second cylinder C2 and opened and closed by the decompression mechanism D2 via the exhaust rocker arm 58 is the tip of the exhaust valve 44 belonging to the second cylinder C2. The decompression mechanism D2 occupies a position overlapping with the tip end portion 44A in the axial direction A1. The decompression mechanism D2 is provided at a position that does not overlap with the tip portion 44A in the axial direction A1 and above the tip end portion 44A in the axial direction A1. Therefore, here, the second cylinder C2 is a specific cylinder.
[0049]
When the intake cams 47, 49, 51 and the exhaust cams 48, 50, 52 rotate together with the cam shaft 31, the intake cams 47, 49, 51 and the exhaust cams 48, 50, 52 become the intake cams 47, 49, 51. And the intake valve 43 and the exhaust valve 44 of each cylinder C1 to C3 through the intake rocker arms 55, 57, 59 and the exhaust rocker arms 56, 58, 60 swung by the exhaust cams 48, 50, 52. Open and close at position.
[0050]
2 and 3, a part of the lubricating oil of the main gallery is inserted into the insertion hole formed in the uppermost fastening boss S1 formed on the exhaust side of the cylinder head 4 and the insertion. An annular oil passage K1 formed between the head bolt B1 inserted through the hole and an oil passage K2 formed in the cylinder head 4 is formed on the first end bearing 64 and sealed by a lid 72. Into the small volume oil chamber K3. The lubricating oil in the oil chamber K3 passes through oil passages K4, K5 (see FIG. 5) constituted by the hollow portions of the rocker shafts 53, 54 and small holes formed in the rocker shafts 53, 54 in the radial direction. Are supplied to sliding portions of the intake rocker arms 55, 57, 59 and the exhaust rocker arms 56, 58, 60 and the intake rocker shaft 53 and the exhaust rocker shaft 54, and the peripheral wall surface of the bearing hole 64b of the first end bearing 64 Small holes formed in the intake rocker shaft 53 and the intermediate bearing 65 from the oil passage K4 are supplied to the sliding portions of the first end bearing 64 and the first end journal 61 through the oil passage K6 that opens to the bottom. And is supplied to the sliding portion between the intermediate bearing 65 and the intermediate journal 62. The through hole 4g where the lower ends of the oil passages K4 and K5 are opened is closed by the pump body 37b of the oil pump 37.
[0051]
Further, the lubricating oil that has flowed out of the small holes flows into the valve operating chamber 30 from the sliding portions, and the intake cams 47, 49, 51 and the exhaust cams 48, 50, 52 and the intake rocker arms 55, 57, 59 and the rocker portions of the exhaust rocker arms 56, 58 and 60, the sliding portions of the decompression mechanisms D1 to D3, the sliding portion of the second end bearing 66 and the second end journal 63, etc. are lubricated. After that, the bottom wall 4b and the bottom wall of the head cover 5 gather at the bottom wall of the valve train chamber 30. The lubricating oil on the bottom wall below the valve operating chamber 30 passes through oil passages K7 and K8 formed in the cylinder head 4 and the cylinder block 2 and an oil pipe 73 connected to the head cover 5, and then enters the engine lower case 14. The oil gathers in the formed oil passage K9 and returns to the oil pan 38 through the return oil pipe.
[0052]
Referring to FIGS. 2, 3, and 5, a fuel pump 74 for pumping fuel to the carburetor is a positive displacement pump that performs a pumping action by a pump cam 68, and is provided on the right wall 4 c of the cylinder head 4. It is fixed to the mounting seat formed on the outer surface with bolts B4.
[0053]
In the cam shaft 31, the pump cam 68 is positioned adjacent to the upper end of the second end journal 63 positioned at the lowermost portion of the valve operating chamber 30, and the decompression mechanism D3 is further disposed adjacent to the upper end of the second end journal 63. Exhaust cams 52 are sequentially positioned adjacent to above mechanism D3. Referring to FIGS. 5 and 6, the pump cam 68 is an eccentric cam having a center F at a position eccentric from the rotation center line L2 toward the intake side by a predetermined eccentric amount and having a radius R. A cam surface 68b is formed on the circumference. A portion where the distance from the rotation center line L2 to the cam surface 68b is equal to or greater than the radius R constitutes the cam peak portion Np of the pump cam 68.
[0054]
Referring to FIG. 5, the fuel pump 74 includes a housing 75 that forms a pump chamber 76, a diaphragm 77, and an operating rod 78 as an operating part coupled to the diaphragm 77.
[0055]
In a housing 75 configured by stacking three members 75a, 75b, and 75c, a bolt B4 for attaching the fuel pump 74 to the mounting seat is inserted into the member 75a located closest to the cylinder head 4. And a cylindrical guide portion 75a2 projecting into the valve operating chamber 30 from a through hole 4e formed in the right wall 4c.
[0056]
The actuating rod 78 is formed with a first rod 78a coupled to the diaphragm 77 and a bottomed insertion hole into which the first rod 78a is inserted. The actuating rod 78 is coupled to the first rod 78a in a movable manner by a coupling pin 78c. And the second rod 78b. The second rod 78b is slidably inserted into the guide hole 75a3 on the inner side of the guide portion 75a2, and the tip portion 78b1 projects from the tip opening of the guide portion 75a2 and faces the valve operating chamber 30, and serves as a cam follower for the pump. A contact portion with which the swing arm 79 contacts is configured. The actuating rod 78 is biased in a direction protruding from the guide portion 75a2 by the push spring 78e so that the tip end portion 78b1 is always pressed against the swing arm 79.
[0057]
The guide portion 75a2 and the operating rod 78 are located above the second end journal 63, the pump cam 68, and the lowest head bolt B1b or the lowest fastening boss portion S2 through which the head bolt B1b is inserted. Alternatively, it is disposed closer to the exhaust cam 52 in the axial direction A1 and upwards from the bottom wall of the valve operating chamber 30 where the lubricating oil after lubricating the lubricating portion in the valve operating chamber 30 such as the valve operating mechanism V gathers. Alternatively, it is located sufficiently away from the lower wall 4b toward the exhaust cam 52 in the axial direction A1.
[0058]
The swing arm 79, which is driven by the pump cam 68 and transmits the driving force to the operating rod 78 of the fuel pump 74, has a through hole through which the intake rocker shaft 53 is inserted, and can swing on the intake rocker shaft 53 A fulcrum part 79c supported by the pump cam 68, a contact part 69b that contacts the cam surface 68b of the pump cam 68, and an action part 79a that contacts the tip part 78b1 of the operating rod 78.
[0059]
When the camshaft 31 rotates, the pump cam 68 that rotates integrally with the camshaft 31 drives the operating rod 78 via the swing arm 79 that is swung by the pump cam 68. To reciprocate. Due to this reciprocation, the diaphragm 77 bends so as to increase or decrease the volume of the pump chamber 76, and when the volume increases, the fuel flowing through the piping from the fuel tank and flowing in through the suction check valve is sucked into the pump chamber 76, When the volume decreases, the fuel discharged from the pump chamber 76 through the discharge check valve is pumped to the carburetor through a pipe.
[0060]
Here, the action portion 79a of the swing arm 79 contacts the tip end portion 78b1 of the operating rod 78 at a position that is biased closer to the decompression mechanism D3 than the contact portion 79b in the axial direction A1. More specifically, the action portion 79a is positioned above the pump cam 68 and the contact portion 79b, and has a position overlapping the swing center line L4 or the shaft support portion 69 of the decompression mechanism D3 in the axial direction A1. Occupy. Therefore, the swing arm 79 is in contact with the pump cam 68 so as to avoid interference with the lowest head bolt B1b at the position overlapping with the axial direction A1 and the boss portion S2 formed in the cylinder head 4. From the part 79b toward the action part 79a, the head bolt B1b and the boss part S2 are inclined upwardly through their upper part or near the uppermost part, or closer to the center in the axial direction A1 of the valve operating chamber 30 Inclined to extend.
[0061]
The decompression mechanisms D1 to D3 will be described with reference to FIGS. 2, 3, and 6 to 10. FIG.
The decompression mechanisms D1 to D3 belonging to the respective cylinders C1 to C3 have the same specifications in all points. As shown in FIG. 6, the decompression cams 92 of the decompression mechanisms D1 to D3 adjacent in the rotational direction A0 of the camshaft 31 are used. Are arranged at positions where the cam angle is 120 ° (240 ° crank angle). 2 and 3, each decompression mechanism D1 to D3 is located adjacent to and below the exhaust cams 48, 50, 52 where the slippers 56b, 58b, 60b of the exhaust rocker arms 56, 58, 60 are in contact. The cam shaft 31 is disposed on the shaft portion 80.
[0062]
Hereinafter, the decompression mechanism D3 will be mainly described with reference to FIGS. 7 to 10, but the reference numerals of the members corresponding to the decompression mechanisms D1 and D2 are shown in parentheses.
From the lower end portion 52a of the exhaust cam 52 (48, 50) to the shaft portion 80 just below it, a support surface comprising a plane parallel to the rotation center line L2 and included in the plane P1 perpendicular to the swing center line L4 described later. A first notch 81 having 81a is formed. Further, in the shaft portion 80, the shaft portion 80 extends downward from the first notch portion 81 from a position overlapping with the lower portion of the first notch portion 81 in the axial direction A1, and is perpendicular to the plane P1 and parallel to the rotation center line L2. A second notch 82 having a stopper surface 82a made of an included plane is formed.
[0063]
As shown in FIGS. 7A and 8, in the shaft portion 80, a pair of projecting portions 83a and 83b projecting radially outward in parallel to the plane P1 are provided above the second notch portion 82. A holding portion 83 is integrally formed on the cam shaft 31, and a circular portion as a support portion for supporting a centrifugal weight 91, which will be described later, to be swingable with respect to the cam shaft 31 is provided on each of the protruding portions 83a and 83b. A columnar pin 84 is slidably inserted.
[0064]
Referring also to FIG. 10, each decompression mechanism D1 to D3 includes a decompression member 90 made of a single metal member integrally formed by metal injection and a return spring 95 made of a torsion coil spring. The decompression member 90 swings integrally with the centrifugal weight 91 supported by the pin 84 held by the holding portion 83 and swings integrally with the centrifugal weight 91 and contacts the slipper 60b (56b, 58b) at the start. And a decompression cam 92 that opens the exhaust valve 44, and a plate-like arm 93 that connects the centrifugal weight 91 and the decompression cam 92.
[0065]
The return spring 95 is disposed between the pair of protrusions 83a and 83b. When the internal combustion engine E is started, the elastic force of the return spring 95 is the moment that the centrifugal weight 91 occupies an operating position (see FIG. 7A) described later until the engine rotational speed reaches a predetermined rotational speed. It is set to the value that acts on 91.
[0066]
The centrifugal weight 91 is composed of a pair of base portions 91a and 91b positioned outside the projecting portions 83a and 83b in the direction of the swing center line L4, and a block-shaped weight main body 91c connected to the base portions 91a and 91b. Is done. A pin 84 is slidably inserted into each base 91a, 91b.
[0067]
The flat portion 91c1 facing the cam shaft 31 of the weight main body 91c is formed with a contact portion 91c2 made of a protrusion, and the outer peripheral surface 91c3 facing outward in the radial direction of the weight main body 91c is shown in FIG. As is well shown in FIG. 2, it is substantially composed of a part of a cylindrical surface. The contact portion 91c2 is in contact with the stopper surface 82a of the second cutout portion 82, thereby defining an operation position for performing the decompression operation of the centrifugal weight 91 (or the decompression member 90). On the other hand, a contact portion 93a is formed on the lower surface of the arm 93, and the corresponding contact portion 93a is in contact with the stopper surface 80a1 of the step portion 80a that is the lower side wall of the first notch 81 adjacent to the support surface 81a. Thus, the release position where the centrifugal weight 91 (or the decompression member 90) swings most radially outward to release the decompression operation is defined.
[0068]
The decompression cam 92 provided at the tip of the arm 93 has a cam surface 92a protruding in the direction of the swing center line L4, and a support surface 81a on the opposite side of the cam surface 92a in the direction of the swing center line L4. It has a contact surface 92b that makes surface contact, and slides on the support surface 81a when the centrifugal weight 91 swings. When the decompression member 90 occupies the operating position, the decompression cam 92 protrudes radially from the base circle portion Me of the exhaust cam 52 (48, 50) at a maximum height H (see FIG. 8). The predetermined height H defines the lift amount of the exhaust valve 44 during the decompression operation, that is, the decompression lift amount.
[0069]
Next, the operation of the decompression mechanism D3 (D1, D2) will be described. Referring to FIGS. 7A and 7B, when the internal combustion engine E is stopped and the camshaft 31 is not rotating, the center of gravity G of the decompression member 90 includes the rotation center line L2 rather than the oscillation center line L4. Since the decompression member 90 is located near the plane P3 parallel to the plane P2, the decompression member 90 has a moment in the clockwise direction around the oscillation center line L4 in FIG. The moment in the counterclockwise direction due to the elastic force of 95 acts, the contact portion 91c2 of the centrifugal weight 91 contacts the stopper surface 82a, and the decompression member 90 occupies the operating position.
[0070]
In order to start the internal combustion engine E, the recoil starter 13 is operated by pulling a starter knob 13a (see FIG. 1) coupled to a rope wound around the reel of the recoil starter 13, and the crankshaft 9 rotates. . At this time, since the engine rotation speed is equal to or lower than the predetermined rotation speed, the decompression member 90 occupies the operating position.
[0071]
Therefore, when the cylinder C3 (C1, C2) is in the compression stroke, the decompression cam 92 protruding radially outward from the base circle portion Me of the exhaust cam 52 (48, 50) is connected to the exhaust rocker arm 60 (56, 58). ), The exhaust rocker arm 60 (56, 58) is swung in contact with the slipper 60b (56b, 58b), and the exhaust valve 44 is opened with the decompression lift amount. At this time, the compressed intake air in the cylinder C3 (C1, C2) is discharged to the exhaust port 42, the compression pressure in the cylinder C3 (C1, C2) is reduced, and the piston 7 easily overcomes the top dead center. As a result, the operation force of the recoil starter 13 is reduced.
[0072]
Thereafter, when the engine rotational speed increases and exceeds the predetermined rotational speed, the moment due to the centrifugal force acting on the decompression member 90 overcomes the moment due to the elastic force of the return spring 95. At this time, if the slipper 60b (56b, 58b) is not in contact with the decompression cam 92, the decompression member 90 starts swinging due to a moment due to centrifugal force and moves radially outward, and the arm 93 is supported by the support surface. It slides on 81a and swings until the contact portion 93a of the arm 93 contacts the stopper surface 80a1, and occupies the release position shown in FIG.
[0073]
In this release position, the decompression cam 92 moves in the axial direction A1 from the position overlapping the exhaust cam 52 (48, 50) in the axial direction A1 of the first notch 81 and does not contact the slipper 60b (56b, 58b). The decompression operation is canceled. Therefore, when the cylinder C3 (C1, C2) is in the compression stroke, the slipper 60b (56b, 58b) contacts the base circle portion Me of the exhaust cam 52 (48, 50), so that the exhaust valve 44 is closed. Yes, intake air is compressed with normal compression pressure. Thereafter, the engine speed of the internal combustion engine E gradually increases, and after the complete explosion state, shifts to the idling operation.
[0074]
Referring to FIGS. 2 and 3, the swing center line L4 of the decompression mechanisms D1 and D3 belonging to the first and third cylinders C1 and C3 is located below the exhaust rocker arms 56 and 60, and the decompression mechanisms D1, The entire D3 is positioned below the lower end of the exhaust cams 48 and 52. The swing center line L4 of the decompression mechanism D2 belonging to the second cylinder C2 is located within the axial range defined by the position of the slipper 58b of the exhaust rocker arm 58 and the adjusting screw 58a in the axial direction A1. Further, the distal end portion 44A of the exhaust valve 44 occupies a position overlapping the centrifugal weight 91 of the decompression mechanism D2 in the axial direction A1, and further, the decompression mechanism D2 extends from the decompression cam 92 to more than half of the centrifugal weight 91. The portion occupies a position overlapping the exhaust rocker arm 58 in the axial direction A1.
[0075]
The decompression mechanism D3 belonging to the third cylinder C3 includes a pin 84, a part of the arm 93, and a part of the centrifugal weight 91, which are part of the decompression mechanism D3, which are housed in the through hole 69a of the shaft support part 69. Occupies a position overlapping the shaft support 69 in the direction A1. Further, as shown in FIGS. 2 and 3, the decompression mechanism D3 is disposed on the opposite side of the pump end 68 from the second end bearing 66 and the second end journal 63 in the axial direction A1. The cam 68 is positioned adjacent to and above the axial direction A1.
[0076]
Referring to FIGS. 5 and 6, in the decompression mechanism D3, the swing center line L4 of the centrifugal weight 91 connects the rotation center line L2 and the maximum height portion Np1 of the cam peak portion Np when viewed from the axial direction A1. The camshaft 31 is swingably supported so as to be orthogonal to the reference straight line L5 and so that the reference straight line L5 is substantially symmetrical with the centrifugal weight 91. The centrifugal weight 91 includes the center of gravity G and the cam mountain side of the pump cam 68 or the side where the center F of the pump cam 68 is located with respect to the rotation center line L2 when viewed from the axial direction A1. Placed in. Here, the cam peak portion side means a side where the cam peak portion Np or the maximum high-position portion Np1 is located with respect to a plane including the rotation center line L2 and orthogonal to the reference straight line L5.
[0077]
Therefore, when the rotational speed of the camshaft 31 increases and the centrifugal weight 91 swings from the operating position to the release position, the centrifugal weight 91 is viewed from the axial direction A1, and the rotational centerline of the camshaft 31 The reference straight line L5 oscillates in a direction approaching the maximum high level portion Np1 of the cam peak Np with respect to L2, and more specifically, the reference straight line L5 is the same direction as the direction in which the maximum high level Np1 of the cam peak Np is located. Oscillates in the extending direction.
[0078]
Moreover, as shown in FIGS. 6 and 7, the outer peripheral surface 91c3 of the centrifugal weight 91, which is the outermost position in the radial direction of the camshaft 31 in the decompression mechanism D3, is at the operating position at the release position. Occupies substantially the same radial position as the portion of the centrifugal weight 91 located at the maximum outer side in the radial direction. Therefore, the decompression mechanism D3 is configured so that the entire centrifugal weight 91 and further the entire decompression mechanism D3 are within the projection range parallel to the axial direction A1 of the pump cam 68, that is, viewed from the axial direction A1, It swings within the range of the cam surface 68b of the pump cam 68 or within the range overlapping the pump cam 68. Then, the entire centrifugal weight 91 swings so as to be at least inside the cam peak portion Np formation range on the cam peak portion side.
[0079]
Next, operations and effects of the embodiment configured as described above will be described.
A restricting portion that contacts the second end bearing 66 that supports the second end journal 63 of the cam shaft 31 and prevents the cam shaft 31 from moving downward is a pump cam 68 that drives the fuel pump 74, The decompression mechanism D3 belonging to the third cylinder C3 in the lowermost part of the cylinder row is disposed above the pump cam 68 on the side opposite to the second end bearing 66 in the axial direction A1, thereby Since the cam 68 also serves as the restricting portion, a space in the axial direction A1 is formed along the cam shaft 31 as compared with the case where the cam for the pump and the restricting portion are separately provided on the cam shaft. The decompression mechanism D3 is disposed adjacent to the pump cam 68 in the direction A1, and the decompression mechanism D3 can be disposed close to the pump cam 68, so that the pump cam 68 and the decompression mechanism D3 are provided. The camshaft 31 is restrained from becoming longer, and the valve 30 size is suppressed, it is possible to compact the internal combustion engine E in the axial direction A1.
[0080]
The three journals 61, 62, 63 supporting the three journals 61, 62, 63 of the camshaft 31 are in contact with the second end bearing 66 out of the three bearings 64, 65, 66 of the same number as the journals 61, 62, 63. The restricting portion that prevents the movement of the cam shaft 31 is a pump cam 68 that drives the fuel pump 74, and belongs to the pump cam 68 and the third cylinder C3 between the second end bearing 66 and the intermediate bearing 65. The intake cam 51, the exhaust cam 52, and the decompression mechanism D3 are disposed. The exhaust cam 52 is disposed on the side opposite to the second end bearing 66 and adjacent to the pump cam 68, so that one cylinder is used. Compared with the case where the pump cam and the restricting portion are separately provided between the second end bearing 66 and the intermediate bearing 65 located with a certain third cylinder C3 interposed therebetween, the camshaft 31 in the axial direction A1 The intake cam 51, the exhaust cam 52, and the decompression machine are formed close to the pump cam 68. Since the structure D3 can be arranged, the camshaft 31 on which the pump cam 68 and the decompression mechanism D3 are provided is suppressed from being lengthened in this respect, and the enlargement of the valve operating chamber 30 is suppressed. The internal combustion engine E can be made compact.
[0081]
In addition, the connecting portion 36 that connects the cam shaft 31 and the rotating shaft 37a of the oil pump 37 is provided at a position overlapping the second end journal 63 and the second end bearing 66 in the axial direction A1. However, the lengthening of the camshaft 31 can be suppressed.
[0082]
The centrifugal weight 91 of the decompression mechanism D3, which is positioned adjacent to the pump cam 68 in the axial direction A1 and supported by the cam shaft 31 so as to be swingable, is the cam crest of the pump cam 68 when viewed from the axial direction A1. When the rotational speed of the camshaft 31 increases, the camshaft 31 approaches the maximum height portion Np1 of the cam nose Np relative to the rotational centerline L2 of the camshaft 31, preferably the rotational centerline L2 The centrifugal weight 91 disposed on the cam crest side is pivoted in the direction in which the reference straight line L5 extends, which is the same direction as the direction in which the maximum high position portion Np1 of the cam crest Np is located. Since it oscillates toward the highest position Np1 that is farthest from the line L2, the oscillating range until the centrifugal weight 91 overlaps the cam surface 68b of the pump cam 68 when viewed from the axial direction A1 is the centrifugal weight. Is arranged on the portion other than the cam peak side of the pump cam Since it can be larger than the one that swings outward, the interference between the centrifugal weight 91 and the swing arm 79 is avoided in the set swing range of the centrifugal weight 91, and the pump cam 68 and decompressor The mechanism D3 can be disposed close to the camshaft 31 and the camshaft 31 can be prevented from being lengthened, and the valve chamber 30 can be prevented from being enlarged in the axial direction A1, thereby reducing the size of the internal combustion engine E. it can.
[0083]
The centrifugal weight 91 of the decompression mechanism D3, which is positioned adjacent to the pump cam 68 in the axial direction A1 and supported by the cam shaft 31 so as to be movable in the radial direction, is viewed from the axial direction A1. Since the centrifugal weight 91 does not protrude outward from the cam surface 68b when viewed in the axial direction A1 by moving within the range of the cam surface 68b, the centrifugal weight 91 has a set swing range. After avoiding interference between the centrifugal weight 91 and the swing arm 79, the pump cam 68 and the decompression mechanism D3 can be arranged close to each other, and the camshaft 31 is prevented from being lengthened, and consequently the valve operating chamber. The increase in size in the 30 axial direction A1 is suppressed, and the internal combustion engine E can be made compact.
[0084]
Furthermore, the entire centrifugal weight 91 is swung so as to be within the formation range of the cam crest Np determined by the operating angle of the cam crest Np, thereby preventing the pump cam 68 from being enlarged in the radial direction. Can
[0085]
The decompression mechanism D3 is located adjacent to the second end journal 63 and drives the operating rod 78 of the fuel pump 74 via the swing arm 79, and the exhaust valve 44 opened and closed by the decompression mechanism D3. The swing arm 79 is positioned between the exhaust cam 52 that opens and closes the exhaust cam 52 and the contact portion 79b that contacts the pump cam 68 and the position that is biased closer to the exhaust cam 52 than the contact portion 79b in the axial direction A1. By having the action portion 79a that abuts against the abutment portion 78b1 of the rod 78, the guide rod 75a2 of the fuel pump 74 that faces the valve operating chamber 30 as well as the guide rod 75a2 that faces the valve operating chamber 30 can be moved in the axial direction A1. 4b, and can avoid interference with the head bolt B1b, the boss portion S2, etc. in the position overlapping the pump cam 68 in the axial direction A1, so that the cam shaft 31 becomes longer and Fuel pump 74 to cylinder It is suppressed that protrudes from de 4 axially A1, it is compact internal combustion engine E.
[0086]
The valve mechanism V is provided on the camshaft 31 for each of the cylinders C1 to C3 and opens and closes the intake valve 43 and the exhaust valve 44 via the intake rocker arms 55, 57, 59 and the exhaust rocker arms 56, 58, 60, respectively. 47, 49, 51 and exhaust cams 48, 50, 52, an exhaust cam 50 that opens and closes an exhaust valve 44 that belongs to a second cylinder C2 that is an intermediate cylinder constituting the cylinder row and that is opened and closed by a decompression mechanism D2. The exhaust rocker arm 58 driven by the exhaust cam 50 is provided at a position where it does not overlap the tip 44A of the exhaust valve 44 in the axial direction A1, and the decompression mechanism D2 is provided at a position where it overlaps the tip 44A in the axial direction A1. More specifically, the swing center line L4 of the decompression mechanism D2 is positioned within the axial range defined by the position of the slipper 58b of the exhaust rocker arm 58 and the adjustment screw 58a in the axial direction A1. , And the tip of the exhaust valve 44 The portion 44A occupies a position overlapping with the centrifugal weight 91 of the decompression mechanism D2 in the axial direction A1, and further, the decompression mechanism D2 has a major portion, that is, a portion extending from the decompression cam 92 to more than half of the centrifugal weight 91, and the exhaust rocker arm 58. By occupying a position that overlaps in the axial direction A1, the exhaust cam 50 is not constrained by the position in the axial direction A1 of the distal end 44A with which the exhaust rocker arm 58 abuts, and does not overlap with the distal end 44A in the axial direction A1. The decompression mechanism D2 is disposed at a position overlapping with the tip 44A in the axial direction A1 by using the space in the axial direction A1 of the camshaft 31 formed by the deviation up to the tip 44A. Therefore, a sufficient space for arranging the decompression mechanism D2 is secured, and the camshaft 31 extending over the three cylinders C1, C2, and C3 is prevented from being lengthened. Large in direction A1 Molding is suppressed and the internal combustion engine E can be made compact.
[0087]
The exhaust cam 50 belonging to the second cylinder C2 is biased toward the first cylinder C1 with respect to the tip 44A, and is between the intake cam 49 belonging to the second cylinder C2 and the decompression mechanism D1 belonging to the first cylinder C1. In the inter-cylinder portion 31c of the camshaft 31 formed on the camshaft 31, since there is no bearing supporting the camshaft 31, a space in the axial direction A1 is formed in the camshaft 31 as much as there is no bearing. Since the exhaust cam 50 can be biased with respect to the tip end portion 44A, the longer shaft of the cam shaft 31 and the enlargement of the valve operating chamber 30 can be further suppressed, and the internal combustion engine E can be made more compact. Can do.
[0088]
The camshaft 31 is provided with an intake cam 49 belonging to the second cylinder C2 adjacent to the decompression mechanism D1 belonging to the first cylinder C1, so that an intake cam 47 belonging to both cylinders C1, C2, such as a journal, 49. Since there is no portion that prevents the exhaust cams 48, 50 or the decompression mechanisms D1, D2 from being arranged close to each other, a sufficient space for providing the decompression mechanisms D1, D2 can be formed. In this respect as well, the longer shaft of the camshaft 31 and the larger size of the valve operating chamber 30 are further suppressed, and the internal combustion engine E can be further downsized.
[0089]
An inter-cylinder portion 31d of the cam shaft 31 between the decompression mechanism D2 belonging to the second cylinder C2 and the intake cam 47 belonging to the third cylinder C3 is provided with an intermediate bearing 65, so that the intake cams 47, 49, 51 In addition, since the deformation of the camshaft 31 due to the load acting on the exhaust cams 48, 50, 52 is more reliably prevented, a stable operation of the valve mechanism V can be ensured even during high speed operation of the internal combustion engine E. .
[0090]
Hereinafter, an example in which a part of the configuration of the above-described embodiment is changed will be described with respect to the changed configuration.
In the embodiment, the intermediate bearing 65 is provided between the second cylinder C2 and the third cylinder C3. However, the intermediate bearing 65 may be provided between the first cylinder C1 and the second cylinder C2, in which case The intake cam 49, the exhaust cam 50 and the decompression mechanism D2 belonging to the second cylinder C2 have the same shape and arrangement as those of the first cylinder C1, and the intake rocker arm 59 and the exhaust rocker arm 60 belonging to the third cylinder C3 serving as a specific cylinder. Is composed of the specific rocker arm, and its intake cam 51, exhaust cam 52 and decompression mechanism D3 have the same shape and arrangement as the intake cam 49, exhaust cam 50 and decompression mechanism D2 belonging to the second cylinder C2 in the above embodiment. It becomes.
[0091]
The valve cam that is opened and closed by the decompression mechanisms D1 to D3 may be the intake valve 43 instead of the exhaust valve 44. In this case, the specific valve cam becomes the intake cam.
[0092]
For the third cylinder C3, when the decompression mechanism D3 opens and closes the intake valve 43, the decompression mechanism D3 is arranged adjacent to the lower side of the intake cam 51, the exhaust rocker arm 60 is constituted by the specific rocker arm, and the intermediate bearing 65 Between the second end bearing 66 and the second end bearing 66, an exhaust cam 52 may be disposed adjacent to and above the pump cam 68, a decompression mechanism D3 above the exhaust cam 52, and an intake cam 51 above the exhaust cam 52.
[0093]
Of the intake cam 51 and the exhaust cam 52 belonging to the third cylinder C3, it depends on the arrangement of the intake valve 43 and the exhaust valve 44 and when the intake valve 43 is opened and closed by a decompression mechanism D3 provided below the intake cam. The intake valve 43 or the exhaust valve 44 may be disposed adjacent to the pump cam 68 on the opposite side of the second end bearing 66 in the axial direction A1 with respect to the pump cam 68.
[0094]
In the embodiment, the centrifugal weight 91 is supported by the camshaft 31 so as to be swingable and moves radially outward. However, the centrifugal weight 91 slides without swinging radially outward of the camshaft 31. It may be a thing.
[0095]
The fuel pump 74 may be attached to the head cover 5 which is a valve operating chamber forming member that forms the valve operating chamber 30 together with the cylinder head 4. The specific bearing may be the first end bearing 64 or the intermediate bearing 65 instead of the second end bearing 66.
[0096]
The internal combustion engine may be a single cylinder internal combustion engine or a multi-cylinder internal combustion engine other than three cylinders. The internal combustion engine may not be a vertical internal combustion engine, and may be used for a vehicle such as a vehicle or a stationary machine in addition to the outboard motor.
[Brief description of the drawings]
FIG. 1 is a schematic right side view of an outboard motor using an internal combustion engine according to the present invention, showing an embodiment of the present invention.
FIG. 2 is a cross-sectional view taken along the line II-II in FIG.
FIG. 3 is a rear view of the cylinder head when the head cover of the internal combustion engine of FIG. 1 is removed.
4 is a cross-sectional view taken along arrows IVa-IVa in FIG. 3, and the vicinity of the tip of the intake valve of the intake rocker arm is a cross-sectional view taken in the direction of arrows IVb-IVb in FIG. FIG. 4 is a cross-sectional view taken along the arrow IVc-IVc in FIG.
5 is a cross-sectional view of the cylinder head and a part of the fuel pump as viewed in the direction of the arrow Va-Va in FIG. 3, and the camshaft and the swing arm are as viewed in the direction of the arrow Vb-Vb in FIG. It is sectional drawing.
6 corresponds to a cross-sectional view taken along line VI-VI in FIG. 3, and is a view for explaining the arrangement of the decompression mechanism in the rotation direction of the camshaft.
7 is a partial side view taken along arrow VII-VII in FIG. 6, wherein (A) shows a state where the decompression mechanism is in the operating position, and (B) shows a state where the decompression mechanism is in the release position.
8 is a cross-sectional view taken along arrow VIII-VIII in FIG.
9 is a cross-sectional view taken along arrow IX-IX in FIG.
10A is a side view of a decompression member of the decompression mechanism, FIG. 10B is a view from the direction of arrow B in FIG. 10A, and FIG. 10C is a view from the direction of arrow C in FIG. (D) is a D arrow view of (A).
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Outboard motor, 2 ... Cylinder block, 3 ... Crank case, 4 ... Cylinder head, 5 ... Head cover, 6 ... Seal, 7 ... Piston, 8 ... Connecting rod, 9 ... Crankshaft, 10 ... Crank chamber, 11 ... Crank Pulley, 12 ... Flywheel, 13 ... Recoil starter, 14 ... Engine lower case, 15 ... Extension case, 16 ... Gear case, 17 ... Engine upper cover, 18 ... Drive shaft, 19 ... Forward / reverse switching device, 20 ... Propeller shaft, 21 ... propeller, 22 ... stern bracket, 23 ... tilt axis, 24 ... swivel case, 25 ... swivel axis,
30 ... Valve chamber, 31 ... Cam shaft, 31c, 31d ... Inter-cylinder part, 32 ... Oil seal, 33 ... Pulse generator, 34 ... Cam pulley, 35 ... Timing belt, 36 ... Connecting part, 37 ... Oil pump, 38 ... oil pan, 39a ... oil strainer, 39b ... intake pipe, 40 ... combustion chamber, 41 ... intake port, 42 ... exhaust port, 43 ... intake valve, 44 ... exhaust valve, 44A ... tip, 45 ... spark plug, 46 ... Valve spring, 47,49,51 ... Intake cam, 48,50,52 ... Exhaust cam, 53,54 ... Rocker shaft, 55-60 ... Rocker arm, 61-63 ... Journal, 64-66 ... Bearing, 67 ... Flange , 68 ... Pump cam, 69 ... Shaft support, 70 ... Collar, 71 ... Spring, 72 ... Lid, 73 ... Oil pipe, 74 ... Fuel pump, 75 ... Housing, 76 ... Pump chamber, 77 ... Diaphragm, 78 ... Actuation Rod, 79 ... Swing arm, 80 ... Shaft, 81, 82 ... Notch, 83 ... Holding part, 84 ... Pin,
90 ... Decompression member, 91 ... Centrifugal weight, 92 ... Decompression cam, 93 ... Arm, 95 ... Return spring,
E ... Internal combustion engine, C1-C3 ... Cylinder, L1, L2 ... Rotation center line, L3 ... Cylinder axis, L4 ... Oscillation center line, L5 ... Reference straight line, B1-B4 ... Bolt, A0 ... Rotation direction, A1 ... Axis Direction, A2 ... Cylinder axial direction, V ... Valve operated mechanism, D1-D3 ... Decompression mechanism, Mi, Me ... Base circle, Ni, Ne, Np ... Cam crest, Np1 ... Maximum high part, S1, S2 ... Boss Part, K1, K2, K4 to K8 ... oil passage, K3 ... oil chamber, F ... center, R ... radius, P1-P3 ... plane, H ... height.

Claims (2)

A valve operating mechanism that opens and closes the intake valve and the exhaust valve and a decompression mechanism that opens and closes the intake valve or the exhaust valve during the compression stroke are disposed in the valve operating chamber, and a valve operating chamber forming member that forms the valve operating chamber In an internal combustion engine provided with a fuel pump,
The valve mechanism has a cam shaft that rotates in conjunction with a crankshaft and is disposed in the valve chamber. The cam surface is in contact with a cam follower for driving the fuel pump. Is provided on the peripheral surface of the pump cam and the decompression mechanism, and the decompression mechanism is positioned adjacent to the pump cam in the axial direction and is swingably supported by the cam shaft. The centrifugal weight is disposed on the cam peak side of the pump cam as viewed from the axial direction, and when the rotational speed of the cam shaft increases, the rotation center line of the cam shaft In contrast, the internal combustion engine swings in a direction approaching the maximum height portion of the cam peak portion. A valve operating mechanism that opens and closes the intake valve and the exhaust valve and a decompression mechanism that opens and closes the intake valve or the exhaust valve during the compression stroke are disposed in the valve operating chamber, and a valve operating chamber forming member that forms the valve operating chamber In an internal combustion engine provided with a fuel pump,
The valve mechanism has a cam shaft that rotates in conjunction with a crankshaft and is disposed in the valve chamber. The cam surface is in contact with a cam follower for driving the fuel pump. Is provided on the peripheral surface of the pump cam and the decompression mechanism. The decompression mechanism is located adjacent to the pump cam in the axial direction and is supported by the cam shaft so as to be movable in the radial direction. An internal combustion engine having a centrifugal weight that is moved within a range of the cam surface of the pump cam as viewed in the axial direction.

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