Information
-
Patent Grant
-
6318320
-
Patent Number
6,318,320
-
Date Filed
Tuesday, October 5, 199925 years ago
-
Date Issued
Tuesday, November 20, 200123 years ago
-
Inventors
-
Original Assignees
-
Examiners
Agents
- Birch, Stewart, Kolasch & Birch, LLP
-
CPC
-
US Classifications
Field of Search
US
- 123 9027
- 123 9022
- 123 9023
- 123 552
- 123 555
- 123 557
- 123 195 HC
-
International Classifications
-
Abstract
To provide a multi-cylinder engine for a vehicle, in which a pair of cylinder bore rows, each including a plurality of cylinder bores disposed in parallel to each other, are disposed in such a manner as to be perpendicular to a crank shaft disposed substantially in the horizontal direction. Accordingly, a relatively large space can be ensured under a cylinder head. Cam shafts corresponding to cylinder bore rows are disposed over a pair of planes containing the axial lines of cylinder bores constituting the cylinder bore rows, respectively.
Description
BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates to a multi-cylinder engine for a vehicle, in which a pair of cylinder bore rows, each including a plurality of cylinder bores disposed in parallel to each other, are disposed in such a manner as to be perpendicular to a crank shaft disposed substantially in the horizontal direction.
2. Description of Related Art
A multi-cylinder engine of this type has been known, for example, from Japanese Patent Laid-open No. Sho 61-291760. This prior art multi-cylinder engine includes a pair of cylinder bore rows disposed in an approximately V-shape. The pair of cylinder bore rows is generally configured such that a single cam shaft is disposed on an extension of the axial lines of cylinder bores or a pair of cam shafts are disposed on both of the sides of the extension of the axial lines of the cylinder bores. Such a disposition of the cam shaft; however, causes a problem in that the valve system mechanisms containing the cam shafts are disposed in spaces on both sides of the extension of the axial lines of the cylinder bores.
On the other hand, in the case where a V-shaped multi-cylinder engine or a horizontally-opposed type multi-cylinder engine is mounted on a motorcycle in such a manner that the axial line of tile crank shaft extends in the longitudinal direction, it is required to ensure a relatively large space under a cylinder head for increasing the bank angle of the motorcycle and for ensuring a space allowing the driver's feet to extend forwardly under the cylinder head. However, the prior art disposition of the cam shaft fails to obtain a multi-cylinder engine capable of satisfying the above requirement.
SUMMARY OF THE INVENTION
In view of the foregoing, the present invention has been made, and an object of the present invention is to provide a multi-cylinder engine having a pair of cylinder bore rows, which is capable of ensuring a relatively large space under the cylinder head.
To achieve the above object, according to a first aspect of the present invention, a multi-cylinder engine for a vehicle includes a pair of cylinder bore rows, each including a plurality of cylinder bores disposed in parallel to each other. The cylinder bore rows are disposed in such a manner as to be perpendicular to a crank shaft disposed substantially in the horizontal direction. Furthermore, cam shafts corresponding to the cylinder bore rows are offset upwardly from a pair of planes containing the axial lines of the cylinder bores constituting the cylinder bore rows, respectively.
With this configuration, since the cam shaft corresponding to each cylinder bore row is offset upwardly from the plane containing the axial lines of the cylinder bores constituting the cylinder bore row, the valve system mechanism containing the cam shaft is offset upwardly from the axial lines of the cylinder bores. As a result, it is possible to form the cylinder head in such a manner as to ensure a relatively large space under the cylinder head.
According to a second aspect of the present invention, in addition to the configuration of the first aspect of the present invention, the engine is mounted on the motorcycle in such a manner that the cylinder bore rows are opposed to each other with the axial lines of the cylinder bores extending substantially in the horizontal direction- Furthermore, the crank shaft extends in the longitudinal direction of the motorcycle. With this configuration, when the horizontally-opposed type multi-cylinder engine is mounted on the motorcycle with the cylinder heads protruding from both sides of the motorcycle in the width direction, it is possible to ensure a sufficient space allowing the driver's feet to extend forwardly under the cylinder heads, and to set the bank angle of the motorcycle at a relatively large value.
According to a third aspect of the present invention, in addition to the configuration of the first aspect of the present invention, the engine is mounted on the motorcycle in such a manner that the cylinder bore rows are disposed in an approximately V-shape. Furthermore, the crank shaft extends in the longitudinal direction of the motorcycle. With this configuration, when the V-shaped multi-cylinder engine having the V-shape opened upwardly is mounted on the motorcycle, it is possible to set the width of the multi-cylinder engine along the width direction of the motorcycle at a relatively small value, and hence make the V-shaped multi-cylinder engine compact.
According to a fourth aspect of the present invention, in addition to the configuration of the invention described in any of the first through third aspects of the present invention, cams for directly opening/closing intake valves and exhaust valves disposed in cylinder heads for each of the cylinder bores are provided on the cam shafts, respectively. With this configuration, it is possible to simplify the configuration of the valve system mechanism driving the intake valves and exhaust valves.
According to a fifth aspect of the present invention, in addition to the configuration of the fourth aspect of the present invention, the cam shafts common to the intake valves and the exhaust valves are disposed for the cylinder bore rows, respectively. With this configuration, since the cam shaft may be provided for each cylinder bore row, it is possible to make the cylinder head compact.
Further scope of applicability of the present invention will become apparent from the detailed description given hereinafter. However, it should be understood that the detailed description and specific examples, while indicating preferred embodiments of the invention, are given by way of illustration only, since various changes and modifications within the spirit and scope of the invention will become apparent to those skilled in the art from this detailed description.
BRIEF DESCRIPTION OF THE DRAWINGS
The present invention will become more fully understood from the detailed description given hereinbelow and the accompanying drawings which are given by way of illustration only, and thus are not limitative of the present invention, and wherein:
FIG. 1
is a side view of a horizontally-opposed type engine mounted on a motorcycle;
FIG. 2
is a front view in the direction of the arrow
2
of
FIG. 1
;
FIG. 3
is an enlarged sectional view taken on line
3
—
3
of
FIG. 1
;
FIG. 4
is a sectional view taken on line
4
—
4
of
FIG. 3
;
FIG. 5
is an enlarged view taken on line
5
—
5
of
FIG. 4
;
FIG. 6
is an enlarged view taken on line
6
—
6
of
FIG. 4
;
FIG. 7
is an enlarged sectional view taken on line
7
—
7
of
FIG. 4
;
FIG. 8
is an enlarged view taken on line
8
—
8
of
FIG. 4
;
FIG. 9
is an enlarged sectional view taken on line
9
—
9
of
FIG. 4
;
FIG. 10
is a sectional view taken on line
10
—
10
of
FIG. 8
;
FIG. 11
is a sectional view taken on line
11
—
11
of
FIG. 3
;
FIG. 12
is a sectional view taken on line
12
—
12
of
FIG. 11
;
FIG. 13
is a schematic view from the rear side of a mission case;
FIG. 14
is an enlarged sectional view taken on line
14
—
14
of
FIG. 13
; and
FIG. 15
is a front view illustrating a simplified V-shaped multi-cylinder engine according to a second embodiment of the present invention.
DESCRIPTION OF THE PREFERRED EMBODIMENTS
Hereinafter, one embodiment of the present invention will be described with reference to the accompanying drawings.
FIGS. 1
to
14
show one embodiment of the present invention. Referring first to
FIGS. 1 and 2
, a four-cycle/multi-cylinder (e.g., six-cylinder) horizontally-opposed type engine is mounted on a motorcycle. An engine main body E of the engine includes a left engine block B
L
disposed on the left side when the motorcycle is directed forwardly in the running direction thereof, and a right engine block B
R
disposed on the right side in when the motorcycle is directed forwardly in the running direction thereof.
Referring particularly to
FIGS. 3 and 4
, the left engine block B
L
includes a left cylinder block
23
L
and a left cylinder head
24
L
connected to the left cylinder block
23
L
. The left cylinder block
23
L
has a left side cylinder bore row
22
L
including a plurality (e.g., three) of cylinder bores
21
L
disposed in parallel. The left cylinder head
24
L
has combustion chambers
26
L
each of which is formed between the associated one of the cylinder bores
21
L
and a piston
25
L
slidably fitted in the cylinder bore
21
L
. A left crank case
27
L
is formed integrally with the side, opposed to the left cylinder head
24
L
, of the cylinder block
23
L
. The right engine block B
R
includes a right cylinder block
23
R
and a right cylinder head
24
R
connected to the right cylinder block
23
R
. The right cylinder block
23
R
has a right side cylinder bore row
22
R
including a plurality (e.g., three) of cylinder bores
21
R
disposed in parallel. The right cylinder head
24
R
has combustion chambers
26
R
each of which is formed between the associated one of the cylinder bores
21
R
and a piston
25
R
slidably fitted in the cylinder bore
21
R
. A right crank case
27
R
is formed integrally with the side, opposed to the right cylinder head
24
R
, of the cylinder block
23
R
.
The left and right engine blocks B
L
and B
R
are opposed to each other with the axial lines of the cylinder bores
21
L
and
21
R
directed substantially in the horizontal direction. The left crank case
27
L
of the left engine block B
L
is fastened to the right crank case
27
R
of the right engine block B
R
in such a manner as to form a crank chamber
28
therebetween.
The pistons
25
L
and
25
R
in the left and right engine blocks B
L
and B
R
are commonly connected to a crank shaft
29
via connecting rods
30
L
and
30
R
, respectively. The crank shaft
29
is disposed such that one end side is located on the front side of the motorcycle in the longitudinal direction of the motorcycle and the axial line of the crank shaft
29
extends in the longitudinal direction of the motorcycle. The crank shaft
29
is supported by one of the left and right crank cases
27
L
and
27
R
(left crank case
27
L
in this embodiment). To be more specific, the crank shaft
29
is rotatably supported by journal walls
31
integrally formed on the left crank case
27
L
at a plurality of locations spaced in the axial direction of the crank shaft
29
. Furthermore, bearing caps
32
are fastened to the journal walls
31
with a pair of bolts
33
, respectively.
Each of the cylinder bores
21
R
constituting the cylinder bore row
22
R
on the right engine block B
R
side is offset forwardly in the longitudinal direction of the motorcycle from the associated one of the opposed cylinder bores
21
L
constituting the cylinder bore row
22
L
on the left engine block B
L
side by a first offset amount L
1
.
Referring particularly to
FIGS. 5
,
6
and
7
, the left cylinder head
24
L
includes pairs of intake passages
34
L
and exhaust passages
35
L
communicating with the combustion chambers
26
L
. Each pair of the intake passages
34
L
and the exhaust passages
35
L
are provided for the associated one of the combustion chambers
26
L
. The left cylinder head
24
L
also includes intake valves
36
L
each being adapted to open/close the associated one of the intake passages
34
L
and exhaust valves
37
L
each being adapted to open/close the associated one of the exhaust passages
35
L
.
The intake valves
36
L
and the exhaust valves
37
L
, which extend in the direction parallel to the axial line of the crank shaft
29
, are offset upwardly from a plane
38
L
passing through the axial lines of the cylinder bores
21
L
and the axial line of the crank shaft
29
in such a manner that the exhaust valves
37
L
are offset forwardly from the intake valves
36
L
in the longitudinal direction of the motorcycle. The left cylinder head
24
L
also includes ignition plugs
39
L
facing toward the central portion of an associated one of the combustion chambers
26
L
at a position located between an associated one of the pairs of the intake valves
36
L
and exhaust valve
37
L
on an opposite side from the disposition side of the intake valves
36
L
and the exhaust valves
37
L
with respect to the plane
38
L
. In other words, the ignition plugs are located on the lower side of the plane
38
L
.
Each of the intake valves
36
L
and the exhaust valves
37
L
is mounted to the left cylinder head
24
L
in such a manner as to be tilted at an acute angle with respect to the plane
38
L
. On the opposite side from the disposition side of the intake valves
36
L
and the exhaust valves
37
L
with respect to the plane
38
L
, i.e., on the lower side of the plane
38
L
, the left cylinder head
24
L
has plug mounting holes
40
L
for mounting the ignition plugs
39
L
in a state where the ignition plugs
39
L
are filed at an acute angle with respect to the plane
38
L
. In other words, the ignition plugs
39
L
are mounted to the left cylinder head
24
L
in such a manner as to be tilted downwardly with respect to the plane
38
L
.
On the projection chart crossing the axial lines of the cylinder bores
21
L
at right angles, the intake passages
34
L
are provided in the left cylinder head
24
L
in such a manner as to cross the plane
38
L
substantially at right angles, and are opened to one side surface of the left cylinder head
24
L
on the disposition side of the intake valves
36
L
and the exhaust valves
37
L
with respect to the plane
38
L
, i.e., on the upper side of the plane
38
L
. The exhaust passages
35
L
are opened to the other side surface of the left cylinder head
24
L
on an opposite side from the disposition side of the intake valves
36
L
and the exhaust valves
37
L
with respect to the plane
38
L
, i.e., on the lower side of the plane
38
L
. To be more specific, the exhaust passages
35
L
are curved to be swelled toward one end side of the crank shaft
29
or the front side of the motorcycle in order to bypass the ignition plugs
39
L
, that is, the plug mounting holes
40
L
for mounting the ignition plugs
39
L
.
Each of the exhaust passages
35
L
is formed in such a manner as to be tilted downwardly toward the central portion of the motorcycle in the width direction and to be opened to the other side surface, i.e., the lower surface of the left cylinder head
24
L
. An exhaust system
43
L
is provided which is composed exhaust pipes
41
L
each of which is in communication with an associated one of the exhaust passages
35
L
, a catalyst converter
42
, an exhaust muffler (not shown), and the like. Each of the exhaust pipes
41
L
of the exhaust system
43
L
is tilted such that it is closer to the central portion of the motorcycle in the width direction since it is separated apart downwardly from the left cylinder head
24
L
, and is connected to an opening at the outer end of the associated one of the exhaust passages
35
L
.
The center of the opening at the outer end of each exhaust passage
35
L
is offset forwardly in the longitudinal direction of the motorcycle from a center C
L
of an associated one of the combustion chambers
26
L
by a second offset amount
L
2
.
A single cam shaft
46
L
, which is in parallel to the crank shaft
29
and has an axial line perpendicular to the opening/closing operational lines of the intake valves
36
L
and the exhaust valves
37
L
, is disposed on the disposition side of the intake valves
36
L
and the exhaust valves
37
L
with respect to the plane
38
L
. In other words, the single cam shaft
46
L
is on the upper side of the plane
38
L
. On the other hand, the upper ends of the intake valves
36
L
and the exhaust valves
37
L
biased in the valve closing direction, i.e., upwardly, by springs are in contact with valve lifters
47
L
which are supported by the left cylinder head
24
L
slidably in the direction of the operational axial lines of the valves
36
L
and
37
L
. The cam shaft
46
L
includes intake side cams
48
L
in contact with the valve lifters
47
L
associated with the intake valves
36
L
. Exhaust side cams
49
L
are in contact with the valve lifters
47
L
associated with the exhaust valves
37
L
. In other words, the intake valves
36
L
and the exhaust valves
37
L
are directly opened/closed by the intake side cams
48
L
and the exhaust side cams
49
L
of the cam shaft
46
L
, respectively.
A plurality (for example, four) of portions, spaced in the axial line direction, of the cam shaft
46
L
are rotatably supported by cam bearing portions
50
L
provided on the left cylinder head
24
L
and a cam holder
51
L
commonly fastened to the cam bearing portions
50
L
. Of the four cam bearing portions
50
L
, three are each provided on the left cylinder head
24
L
in such a manner as to be disposed between a pair of the intake valves
36
L
and the exhaust valves
37
L
provided for each combustion chamber
26
L
. The remaining cam bearing portion
50
L
is provided on the left cylinder head
24
L
in such a manner as to be located outside of the combustion chamber
26
L
disposed at the outermost end on one end side of the cam shaft
46
L
(front end side of the motorcycle).
An oil passage
52
L
having both ends closed is coaxially provided in the cam shaft
46
L
. As shown in
FIG. 3
, the cam shaft
46
L
has oiling holes
53
L
at positions corresponding to the cam bearing portions
50
L
. The oiling holes
53
L
are formed in such a manner as to extend from the inside to the outside of the cam shaft
46
L
. Accordingly, lubricating oil is supplied from the interior of the cam shaft
46
L
to the cam bearing portions
50
L
and the cam holder
51
L
. Furthermore, an oil groove
54
L
facing to the outer surface of the cam shaft
46
L
is provided in the cam bearing portion
50
L
disposed at the outermost end on one end side of the cam shaft
46
L
, and an oiling passage
55
L
provided in the left cylinder head
24
L
and the left cylinder block
23
L
is in communication with the oil groove
54
L
. Accordingly, oil is supplied from the oiling passage
55
L
into the oil passage
52
L
in the cam shaft
46
L
via the oil groove
54
L
and the oiling hole
53
L
.
Each of the intake side cams
48
L
and the exhaust side cams
49
L
has an oiling hole (not shown) communicating with the oil passage
52
L
in the cam shaft
46
L
. The outer end of the oiling hole is opened to the outer surface of an associated one of the intake side cams
48
L
and the exhaust side cams
49
L
. Accordingly, lubricating oil is also supplied to a slide-contact portion between each of the intake side cams
48
L
and the exhaust side cams
49
L
and the valve lifters
47
L
provided for each of the intake valves
36
L
and the exhaust valves
37
L
.
The left cylinder head
24
L
is fastened at a plurality of locations to the left cylinder block
23
L
. On the opposite side from the disposition side of the intake valves
36
L
and the exhaust valves
37
L
with respect to the plane
38
L
, i.e., on the lower side of the plane
38
L
, the left cylinder head
24
L
has a plurality (for example, four) of through-holes
56
L
spaced in the axial line direction of the cam shaft
46
L
. Of the four through-holes
56
L
, two are each disposed between adjacent ones of the combustion chambers
26
L
. Fastening bolts
57
L
for fastening the left cylinder head
24
L
to the left cylinder block
23
L
are inserted in the through-holes
56
L
.
Each through-hole
56
L
is adjacent, on one end side (left side in
FIG. 7
) of the cam shaft
46
L
, to an associated one of the exhaust passages
35
L
bypassing the ignition plugs
39
L
provided for the combustion chambers
26
L
. The through-hole
56
L
has a positional relationship such that a distance L
4
between a center of the through-hole
56
L
and a center C
L
of the associated combustion chamber
26
L
is larger than a value L
3
(L
3
<L
4
). The value L
3
is half a distance (
2
L
3
) between the centers C
L
of adjacent ones of the combustion chambers
26
L
.
On the disposition side of the intake valves
36
L
and the exhaust valves
37
L
with respect to the plane
38
L
, i.e., on the upper side of the plane
38
L
, the left cylinder head
24
L
has a plurality (for example, four) of through-holes
58
L
spaced in the axial line direction of the cam shaft
46
L
. Of the four through-holes
58
L
, two are each disposed between adjacent ones of the combustion chambers
26
L
. Fastening bolts
59
L
for fastening the left cylinder head
24
L
to the left cylinder block
23
L
are inserted in the through-holes
58
L
. Each through-hole
58
L
, i.e., fastening bolt
59
L
is disposed at a position where it is partially covered by the cam shaft
46
L
.
A left head cover
60
L
is fastened to the left cylinder head
24
L
in such a manner that a valve system chamber
61
L
for containing the cam shaft
46
L
and the cam holder
51
L
is formed between the left head cover SO
L
and the left cylinder head
24
L
. Since the cam shaft
46
L
is disposed upwardly from the plan
38
L
containing the axial lines of the cylinder bores
21
L
, the valve system chamber
61
L
is also formed between the left head cover SO
L
and the left cylinder head
24
L
in such a manner as to be offset upwardly from the plane
38
L
.
A cover portion
62
L
is formed integrally with the left head cover
60
L
. Portions of the exhaust pipes
41
L
of the exhaust system
43
L
connected to the exhaust passages
35
L
, and the ignition plugs
39
L
disposed downwardly therefrom are covered from the outside by the cover portion
62
L
.
Referring particularly to
FIGS. 8 and 9
, the right cylinder head
24
R
includes pairs of intake passages
34
R
and exhaust passages
35
R
communicating with the combustion chambers
26
R
, each pair being provided for an associated one of the combustion chambers
26
R
. The right cylinder head
24
R
also includes intake valves
36
R
each being adapted to open/close an associated one of the intake passages
34
R
and exhaust valves
37
R
each being adapted to open/close the associated one of the exhaust passages
35
R
.
The intake valves
36
R
and the exhaust valves
37
R
, which extend in the direction parallel to the axial line of the crank shaft
29
, are offset upwardly from a plane
38
R
passing through the axial lines of the cylinder bores
21
R
and the axial line of the crank shaft
29
in such a manner that the exhaust valves
37
R
are offset forwardly from the intake valves
36
R
in the longitudinal direction of the motorcycle. Ignition plugs
39
R
, each of which faces to the central portion of an associated one of the combustion chambers
26
R
, are mounted to the right cylinder head
24
R
on a lower side of the plane
38
R
.
Each of the intake valves
36
R
and the exhaust valves
37
R
is tilted at an acute angle with respect to the plane
38
R
. On the lower side from the plane
38
R
, the right cylinder head
24
R
has plug mounting holes
40
R
for mounting the ignition plugs
39
R
in a state where the ignition plugs
39
R
are tilted at an acute angle with respect to the plane
38
R
. The ignition plugs
39
R
are thus mounted to the right cylinder head
24
R
in such a manner as to be tilted downwardly with respect to the plane
38
R
.
On the projection chart crossing the axial lines of the cylinder bores
21
R
at right angles, the intake passages
34
R
are provided in the right cylinder head
24
R
in such a manner as to cross the plane
38
R
substantially at right angles, and are opened to one side surface of the right cylinder head
24
R
on the upper side of the plane
38
R
The exhaust passages
35
R
are opened to the other side surface of the right cylinder head
24
R
on the lower side from the plane
38
R
. To be more specific, the exhaust passages
35
R
are curved to be swelled toward one end side of the crank shaft
29
in the axial direction or the front side of the motorcycle in order to bypass the ignition plugs
39
R
, that is, the plug mounting holes
40
R
.
Each of the exhaust passages
35
R
is formed in such a manner as to be tilted downwardly toward the central portion of the motorcycle in the width direction and to be opened to the lower surface of the right cylinder head
24
R
. An exhaust system
43
R
is provided which is composed of exhaust pipes
41
R
, each of which is in communication with an associated one of the exhaust passages
35
R
, a catalyst converter (not shown), an exhaust muffler (not shown), and the like. Each of the exhaust pipes
41
R
of the exhaust system
43
R
is tilted in such a manner as to be closer to the central portion of the motorcycle in the width direction since being separated apart downwardly from the right cylinder head
24
R
, and is connected to an opening at the outer end of the associated one of the exhaust passages
35
R
.
The center of the opening at the outer end of each exhaust passage
35
R
is offset forwardly in the longitudinal direction of the motorcycle from a center C
R
of an associated one of the combustion chambers
26
R
by the second offset amount L
2
.
The upper ends of the intake valves
36
R
and the exhaust valves
37
R
biased in the valve closing direction by springs are in contact with valve lifters
47
R
supported by the right cylinder head
24
R
. Intake side cams
48
R
are in contact with the valve lifters
47
R
associated with the intake valves
36
R
and exhaust side cams
49
R
are in contact with the valve lifters
47
R
associated with the exhaust valves
37
R
The intake side cams
48
R
are provided on a single cam shaft
46
R
which is disposed on the upper side of the plane
38
R
. The cam shaft
46
R
is in parallel to the crank shaft
29
and has an axial line perpendicular to the opening/closing operational axial lines of the intake valves
36
R
and the exhaust valves
37
R
. In other words, the intake valves
36
R
and the exhaust valves
37
R
are directly opened/closed by the intake side cams
48
R
and the exhaust side cams
49
R
of the cam shaft
46
R
, respectively.
A plurality (for example, four) of portions, spaced in the axial line direction, of the cam shaft
46
R
are rotatably supported by cam bearing portions
50
R
provided on the right cylinder head
24
R
and a cam holder
51
R
commonly fastened to the cam bearing portions
50
R
. Of the four cam bearing portions
50
R
, three are each provided on the right cylinder head
24
R
in such a manner as to be disposed between the pair of the intake valves
36
R
and the exhaust valves
37
R
provided for each combustion chamber
26
R
, and the remaining cam bearing portion
50
R
is provided on the right cylinder head
24
R
in such a manner as to be located outside the combustion chamber
26
R
disposed at the outermost end on one end side of the cam shaft
46
R
(front end side of the motorcycle).
As shown in
FIG. 3
, the cam shaft
46
R
has oiling holes
53
R
at positions corresponding to the cam bearing portions
50
R
. The oiling holes
53
R
are formed in such a manner as to extend from an inside to an outside of the cam shaft
46
R
. Lubricating oil is supplied from an oil passage
52
R
formed in the cam shaft
46
R
to the cam bearing portions
50
R
and the cam holder
51
R
via the oiling holes
53
R
. Furthermore, an oil groove
54
R
facing to the outer surface of the cam shaft
46
R
is provided in the second cam bearing portion
50
R
from the outermost end on one end side of the cam shaft
46
R
, and an oiling passage
55
R
provided in the right cylinder head
24
R
and the right cylinder block
23
R
is in communication with the oil groove
54
R
.
Each of the intake side cams
48
R
and the exhaust side cams
49
R
has an oiling hole (not shown) in communication with the oil passage
52
R
in the cam shaft
46
R
. Lubricating oil is thus also supplied to a slide-contact portion between each of the intake side cams
48
R
and the exhaust side cams
49
R
and an associated one of the valve lifters
47
R
provided for each of the intake valves
36
L
and the exhaust valves
37
L
.
On the lower side of the plane
38
R
, the right cylinder head
24
R
has a plurality (for example, four) of through-holes
56
R
which are spaced in the axial line direction of the cam shaft
46
R
. Of the four through-holes
56
R
, two are each disposed between adjacent ones of the combustion chambers
26
R
. Fastening bolts
57
R
for fastening the right cylinder head
24
R
to the right cylinder block
23
R
are inserted in the through-holes
57
R
.
Each through-hole
56
R
is adjacent, on one end side (right side in
FIG. 9
) of the cam shaft
46
R
, to an associated one of the exhaust passages
35
R
bypassing the ignition plugs
39
R
provided for the combustion chambers
26
R
. The through-hole
56
R
has a positional relationship such that a distance L
4
between a center of the through-hole
56
R
and a center C
R
of the associated combustion chamber
26
R
is larger than a value L
3
(L
3
<L
4
). The value L
3
is half a distance between the centers C
R
of adjacent ones of the combustion chambers
26
R
.
On the upper side of the plane
38
R
, the right cylinder head
24
R
has a plurality (for example, four) of through-holes
58
R
spaced in the axial line direction of the cam shaft
46
R
. Of the four through-holes
58
R
, two are each disposed between adjacent ones of the combustion chambers
26
R
. Fastening bolts
59
R
for fastening the right cylinder head
24
R
to the right cylinder block
23
R
are inserted in the through-holes
58
R
. Each through-hole
58
R
, that is, fastening bolt
59
R
is disposed at a position where it is partially covered by the cam shaft
46
R
.
Referring particularly to
FIG. 10
, of the plurality (for example, four) of the through-holes
58
R
, the through-hole
58
R
disposed at the outermost end on one end side of the cam shaft
46
R
is provided in the cam bearing portion
50
R
, disposed at the outermost end on the one end side of the cam shaft
46
R
, of the four cam bearing portions
50
R
. The oil groove
54
R
is provided in the cam bearing portion
50
R
adjacent to the above-described cam bearing portion
50
R
disposed at the outermost end on the one end side of the cam shaft
46
R
.
Furthermore, a distance L
5
between a center of the through-hole
58
R
disposed at the outermost end on the one end side of the cam shaft
46
R
and the center C
R
of the combustion chamber
26
R
disposed at the outermost end on the one end side of the cam shaft
46
R
is set to be smaller than the value L
3
(L
5
<L
3
). The value L
3
is, as described above, half the distance between the centers C
R
of adjacent ones of the combustion chambers
26
R
.
A right head cover
60
R
is fastened to the right cylinder head
24
R
in such a manner that a valve system chamber
61
R
for containing the cam shaft
46
R
and the cam holder
51
R
is formed between the right head cover
60
R
and the right cylinder head
24
R
. The valve system chamber
61
R
is formed between the right head cover
60
R
and the right cylinder head
24
R
in such a manner as to be offset upwardly from the plane
38
R
.
A cover portion
62
R
is formed integrally with the right head cover
60
R
. Portions of the exhaust pipes
41
R
of the exhaust system
43
R
connected to the exhaust passages
35
R
, and the ignition plugs
39
R
disposed downwardly therefrom are covered from the outside by the cover portion
62
R
.
With respect to the intake passages
34
L
and the exhaust passages
35
L
provided in the left cylinder head
24
L
and the intake passages
34
R
and the exhaust passages
35
R
provided in the right cylinder head
24
R
as described above, the relative positional relationship between the intake passages
34
L
and the exhaust passages
35
L
along the axial line direction of the crank shaft
29
in the left cylinder head
24
L
is set to be nearly equal to the relative positional relationship between the intake passages
34
R
and the exhaust passages
35
R
along the axial line direction of the crank shaft
29
in the right cylinder head
24
R
.
A throttle body
63
, an intake manifold
64
and an intake system
66
including fuel injection valves
65
provided for each of the combustion chambers
26
L
and
26
R
are disposed over a location between both of the cylinder heads
24
L
and
24
R
. The intake manifold
64
is connected to the intake passages
34
L
and
34
R
of both of the cylinder heads
24
L
and
24
R
.
Secondary air supply passages
44
L
each of which is in communication with the exhaust passage
35
L
are provided in the cylinder head
24
L
and the cylinder block
23
L
of the left engine block B
L
, and secondary air supply passages
44
R
each of which is in communication with the exhaust passage
35
R
are provided in the cylinder head
24
R
and the cylinder block
23
R
of the right engine block B
R
. The secondary air supply passages
44
L
are connected to control valves (not shown) via check valves
45
provided in the cylinder block
23
L
, and the secondary air supply passages
44
R
are similarly connected to control valves (not shown) via check valves
45
provided in the cylinder block
23
R
.
Referring particularly to
FIG. 11
, a transmission mechanism
68
L
is provided between one end portion of the cam shaft
46
L
on the left engine block B
L
side and one end portion of the crank shaft
29
. The transmission mechanism
68
L
is adapted to reduce a rotational power of the crank shaft
29
to half and transmit the reduced rotational power to the cam shaft
46
L
. A transmission mechanism
68
R
is provided between one end portion of the cam shaft
46
R
on the right engine block B
R
side and one end portion of the crank shaft
29
. The transmission mechanism
68
R
is adapted to reduce a rotational power of the crank shaft
29
to half and transmit the reduced rotational power to the cam shaft
46
R
.
The transmission mechanism
68
L
(or
68
R
) is configured such that an endless chain
71
L
(or
71
R
) is wound around a drive sprocket
69
L
(or
69
R
) fixed on the one end portion of the crank shaft
29
and a driven sprocket
70
L
(or
70
R
) fixed on the one end portion of the cam shaft
46
L
(or
46
R
). As described above, each of the cylinder bores
21
R
constituting the cylinder bore row
22
R
on the right engine block B
R
side is offset forwardly in the longitudinal direction of the motorcycle from each of the cylinder bores
21
L
constituting the cylinder bore row
22
L
on the left engine block B
L
side by the first offset amount L
1
. Correspondingly, the transmission mechanism
68
R
on the right engine block B
R
side is offset forwardly in the longitudinal direction of the motorcycle from the transmission mechanism
68
L
on the left engine block B
L
side. In this case, a gap L
6
between both the transmission mechanisms
68
L
and
68
R
is set to be smaller than the first offset amount
1
(L
6
<L
1
).
A transmission chamber
72
L
for containing the transmission mechanism
68
L
is formed in the front end portion of the left engine block B
L
along the longitudinal direction of the motorcycle in such a manner as to extend from the head cover
60
L
to the crank case
27
L
by way of the cylinder head
24
L
and the cylinder block
23
L
. To be more specific, one end of the transmission chamber
72
L
faces the valve system chamber
61
L
and the other end thereof faces the crank shaft
29
. Similarly, a transmission chamber
72
R
for containing the transmission mechanism
68
R
is formed in the front end portion of the right engine block B
R
along the longitudinal direction of the motorcycle in such a manner as to extend from the head cover
60
R
to the crank case
27
R
by way of the cylinder head
24
R
and the cylinder block
23
R
. To be more specific, one end of the transmission chamber
72
R
faces the valve system chamber
61
R
and the other end thereof faces one end of the crank shaft
29
. Accordingly, the other end portions of both the transmission chambers
72
L
and
72
R
are commonly formed in such a manner as to face the one end of the crank shaft
29
. An opening
73
facing to the other end portions of both the transmission chambers
72
L
and
72
R
is provided in the left and right crank cases
27
L
and
27
R
, and is covered with a lid member
74
fastened to the left and right crank cases
27
L
and
27
R
.
In a space on the other end side of the transmission chambers
72
L
and
72
R
, a pulse rotor
75
is fixed to the one end portion of the crank case
29
at a position outside both of the sprockets
68
L
and
68
R
. A sensor
76
facing to the outer periphery of the pulse rotor
75
is mounted on one of the left and right crank cases
27
L
and
27
R
(left crank case
27
L
in this embodiment). The sensor
76
is adapted to detect the passing of teeth provided on the outer periphery of the pulse rotor
75
. In this way, the rotational position of the crank shaft
29
is detected by the sensor
76
.
A pulse rotor
77
is fixed to the one end portion of one of the cam shafts
46
L
and
46
R
(cam shaft
46
L
in this embodiment) at a position outside the driven sprocket
70
L
. A sensor (not shown) for detecting the rotational position of the cam shaft
46
L
is mounted to the left cylinder head
24
L
in such a manner as to face the outer periphery of the pulse rotor
77
.
The crank shaft
29
is rotated in the rotational direction shown by an arrow
78
in FIG.
11
. At the left side transmission mechanism
68
L
, a chain tensioner
79
L
is elastically, slidably in contact with the forward movement portion, i.e., the lower side running portion of the chain
71
L
running counterclockwise from the drive sprocket
69
L
to the driven sprocket
70
L
, and a chain guide
80
L
is slidably in contact with the backward movement portion, i.e., the upper side running portion of the chain
71
L
running counterclockwise from the driven sprocket
70
L
to the drive sprocket
69
L
.
The chain tensioner
79
L
is extended in the running direction of the chain
71
L
. One end portion of the chain tensioner
79
L
is turnably supported by the bearing cap
32
, which is closest to the transmission mechanism
68
L
, for rotatably supporting the crank shaft
29
in co-operation with the plurality of journal walls
31
, via a supporting shaft
81
L
having an axial line parallel to the rotational axial line of the crank shaft
29
. A tensioner lifter
82
L
, which is in contact with an intermediate portion of the chain tensioner
79
L
in the longitudinal direction while pressing the chain tensioner
79
L
onto the chain
71
L
, is mounted to the left cylinder block
23
L
.
The chain guide
80
L
is extended in the running direction of the chain
71
L
. One end portion of the chain guide
80
L
is supported via a bolt
83
L
on the journal wall
31
closest to the transmission mechanism
68
L
; and an intermediate portion and the other end portion of the chain guide
80
L
are in contact with and supported by the left cylinder block
23
L
and the left cylinder head
24
L
, respectively.
At the right side transmission mechanism
68
R
, a chain tensioner
79
R
is elastically, slidably in contact with the forward movement portion, i.e., the upper side running portion of the chain
71
R
running counterclockwise from the drive sprocket
69
R
to the driven sprocket
70
R
, and a chain guide
80
R
is slidably in contact with the backward movement portion, i.e., the lower side running portion of the chain
71
R
running counterclockwise from the driven sprocket
70
R
to the drive sprocket
69
R
.
The chain tensioner
79
R
is extended in the running direction of the chain
71
R
. One end portion of the chain tensioner
79
R
is turnably supported by the journal wall
31
, which is closest to the transmission mechanisms
68
L
and
68
R
, is formed integrally with the left crank case
27
L
, via a supporting shaft
81
R
having an axial line parallel to the rotational axial line of the crank shaft
29
. A tensioner lifter
82
R
, which is in contact with an intermediate portion of the chain tensioner
79
R
in the longitudinal direction while pressing the chain tensioner
79
R
onto the chain
71
R
is mounted to the right cylinder block
23
R
.
The chain guide
80
R
is extended in the running direction of the chain
71
R
. One end portion of the chain guide
80
R
is supported via a bolt
83
R
on a supporting portion
84
formed integrally with the right crank case
27
R
; and an intermediate portion and the other end portion of the chain guide
80
R
are in contact with and supported by the right cylinder block
23
R
and the right cylinder head
24
R
, respectively.
One end portion of the transmission chamber
72
L
(or
72
R
) for containing the transmission mechanism
68
L
(or
68
R
) is in communication with the valve system chamber
61
L
(or
61
R
), and the valve system chamber
61
L
(or SI
R
) is disposed on the upper side of the plane
38
L
(or
38
R
) containing the axial line of the crank shaft
29
and the axial lines of the cylinder bores
21
L
(or
21
R
). Accordingly, oil supplied from the interior of the valve system chamber
61
L
(or
61
R
) into the one end of the transmission chamber
72
L
(or
72
R
) can be introduced to the other end portion, facing the one end of the crank shaft
29
, of the transmission chamber
72
L
(or
72
R
). A return hole
85
for communicating the bottoms of the other end portions of both of the transmission chambers
72
L
and
72
R
to the crank chamber
28
is provided in the left and right crank cases
27
L
and
27
R
.
Referring particularly to
FIG. 12
, a plurality of ribs
88
in contact with and connected to the plurality of journal walls
31
formed integrally with the left crank case
27
L
are formed integrally with the right crank case
27
R
in such a manner as to surround the bearing caps
32
. The return hole
85
is formed in a region extending from the journal wall
31
facing both of the transmission chambers
72
L
and
72
R
to the rib
88
in contact with and connected to the above journal wall
31
. To be more specific, the return hole
85
is composed of a recess
86
provided in the above journal wall
31
in such a manner as to be opened toward the above rib
88
side and a recess
87
provided in the above rib
88
in such a manner as to be opened toward the above journal wall
31
side.
The bearing cap
32
is, as described above, fastened to the journal wall
31
with the pair of bolts
33
, and the return hole
85
is extended in the fastening direction of the bearing cap
32
to the journal wall
31
, i.e., the axial line direction of the bolts
33
.
The return hole
85
is formed between the crank cases
27
L
and
27
R
in such a manner as to be offset toward the left crank case
27
L
side. To be more specific, of the recesses
86
and
87
constituting the return hole
85
, the recess
86
provided in the journal wall
31
is formed longer in the axial line direction of the bolts
33
than the recess
87
formed in the rib
88
.
A mission case
90
is continued to the left and right engine blocks B
L
and B
R
in such a manner as to extend downwardly from the crank cases
27
L
and
27
R
and also extend rearwardly in the longitudinal direction of the motorcycle from the cylinder blocks
23
L
and
23
R
. In the same manner as the above-described return hole
85
, a passage hole
89
is provided in such a manner as to extend from the bottom of the journal wall
31
disposed between the return hole
85
and the interior of the mission case
90
to the bottom of the rib
88
in contact with and connected to the journal wall
31
. Accordingly, oil returning from the transmission chambers
72
L
and
72
R
into the crank chamber
28
via the return hole
85
is introduced in the mission case
90
by way of the passage hole
89
.
As described above, oil in the valve system chamber
61
L
and
61
R
is returned to the crank chamber
28
side via the transmission chambers
72
L
and
72
R
on one end sides of the cam shafts
64
L
and
64
R
. Since the cam shafts
64
L
and
64
R
are disposed substantially in the horizontal direction, it may be desirable to allow the return of oil from the other end sides of the cam shafts
64
L
and
64
R
to the crank chamber
28
side in the valve system chambers
61
L
and
61
R
. To meet the above requirement, a return passage
91
L
(or
91
R
) having one end in communication with the interior of the valve system chamber
61
L
(or
61
R
) on the other end side of the cam shaft
64
L
(or
64
R
) and having the other end in communication with the crank chamber
28
is provided in the left cylinder head
24
L
(or right cylinder head
24
R
) and the left cylinder block
23
L
(or right cylinder block
23
R
).
Referring particularly to
FIGS. 13 and 14
, a water pump
94
including a pump shaft
95
directly connected to the crank case
29
is disposed on the back face of the mission case
90
. A casing
96
of the water pump
94
is composed of a pump body
97
for rotatably supporting the pump shaft
95
, and a pump cover
98
is fastened to the pump body
97
in such a manner as to cover an impeller
99
fixed to the pump shaft
95
.
The pump body
97
is formed integrally with the mission case
90
. The pump cover
98
is fastened to the pump body
97
with a pump chamber
100
formed between the pump cover
98
and the pump body
97
. The pump shaft
95
is rotatably supported by the pump body
97
in a state where one end thereof projects in the pump chamber
100
. An engagement plate
95
a
to be engaged with an engagement recess
29
a
provided in the other end of the crank shaft
29
is projectingly provided at the other end of the pump shaft
95
. In other words, one end side of the crank shaft
29
is connected to the cam shafts
64
L
and
64
R
via the transmission mechanisms
68
L
and
68
R
, while the other end side of the crank shaft
29
is directly connected to the pump shaft
95
of the water pump
94
.
The impeller
99
is disposed in the pump chamber
100
and is fixed to the one end of the pump shaft
95
. Over the impeller
99
, a containing portion
101
in communication with the central portion of the pump chamber
100
is formed in the upper portion of the pump cover
98
.
A wax type thermostat
102
, which is additionally provided on the water pump
94
, is contained in the containing portion
101
in a state where it is held between the pump body
97
and the pump cover
98
.
The thermostat
102
is of a known type, and includes a supporting plate
103
held between the pump body
97
and the pump cover
98
, a thermostat valve
104
, and a bypass valve
105
.
A first suction port
106
opened toward one end of the containing portion
101
is provided in the upper portion of the pump body
97
in such a manner as to be openable/closable by the thermostat valve
104
. A second suction port
107
opened toward the other end of the containing portion
101
is provided in the pump cover
98
in such a manner as to be openable/closable by the bypass valve
105
. A discharge port
108
for discharging cooling water discharged depending on rotation of the impeller
99
is provided in the pump cover
98
. The discharge port
108
is in communication with the pump chamber
100
.
A water jacket
109
L
(or
109
R
) is provided on the left cylinder block
23
L
(or right cylinder block
23
R
), and a water jacket
110
L
(or
110
R
) in communication with the water jacket
109
L
(or
109
R
) is provided on the cylinder block
23
L
(or
23
R
). The discharge port
108
of the water pump
94
is in communication with the water jackets
109
L
and
109
R
via cooling water supply pipes
111
connected to the left and right cylinder blocks
23
L
and
23
R
.
A cooling water discharge pipe
112
L
(or
112
R
) for discharge cooling water from the water jackets
110
L
(or
110
R
) is connected to the left cylinder block
24
L
(or right cylinder head
24
R
). The cooling water discharge pipes
112
L
and
112
R
are connected to the second suction port
107
of the water pump
94
, and are also connected to inlets of radiators
113
L
and
113
R
, respectively.
The radiators
113
L
and
113
R
are disposed over the left and right engine blocks B
L
and B
R
, i.e., both of the cylinder bore rows
22
L
and
22
R
. The outlets of both of the radiators
113
L
and
113
R
are connected to the first suction port
106
of the water pump
94
.
According to such a cooling water circuit, in a state where the temperature of cooling water is low before the engine is warm the thermostat
102
closes the thermostat valve
104
and opens the bypass valve
105
. Therefore, cooling water discharged from the discharge port
108
of the water pump
94
is not sucked from the water jackets
109
L
,
110
L
,
109
R
and
110
R
into the water pump
94
by way of the radiators
113
L
and
113
R
. On the other hand, as the temperature of cooling water becomes higher along with termination of warming of the engine, the thermostat
102
opens the thermostat valve
104
and closes the bypass valve
105
. Therefore, cooling water discharged from the discharge port
108
of the water pump
94
is sucked from the water jackets
109
L
,
110
L
,
109
R
and
110
R
into the water pump
94
by way of the radiators
113
L
and
113
R
. In other words, a bottom bypass type cooling water circuit using the thermostat
102
is formed among the water pump
94
, the water jackets
109
L
,
109
R
,
110
L
and
110
R
and the radiators
113
L
and
113
R
.
A jiggle valve
114
for releasing air in the water pump
94
onto the first suction port
106
side is mounted on the upper portion of the supporting plate
103
of the thermostat
102
disposed over the impeller
99
.
Referring particularly to
FIG. 13
, a main shaft
115
linked with the crank shaft
29
, a counter shaft
116
with a plurality of gear trains capable of being selectively established provided between the main shaft
115
and the counter shaft
116
, and an output shaft
117
linked with the counter shaft
116
via a one-way clutch (not shown) are rotatably supported by the mission case
90
. Each of the shafts
115
,
116
and
117
has an axial line parallel to that of the crank shaft
29
. The output shaft
117
for transmitting power to the rear wheel side of the motorcycle projects rearwardly from the back face of the mission case
90
.
A shifter shaft
119
for axially movably supporting a plurality of shifters
118
for selectively establishing the gear trains between the main shaft
115
and the counter shaft
116
is supported by the mission case
90
at a position below and between the main shaft
115
and the counter shaft
116
. A shift drum
120
for selectively moving one of the shifters
118
is supported by the mission case
90
at a position adjacent to the shifter shaft
119
in such a manner as to be rotatable on its axis.
A motor
121
having a rotational axial line parallel to the axial line of the crank shaft
29
is mounted on the back face of the mission case
90
at a position above and between the crank shaft
29
and the output shaft
117
. An intermediate shaft
122
is supported by the mission case
90
at a position between the crank shaft
29
and the motor
121
. A gear train (not shown), which allows transmission of rotational power from the motor
121
to the crank shaft
29
but does not allow transmission of power from the crank shaft
29
to the motor
121
, is provided between the motor
121
and the crank shaft
29
with the intermediate shaft
122
interposed therebetween. Therefore, the power of the motor
121
is transmitted to the crank shaft
29
upon start-up of the engine.
A power transmission mechanism
123
actuated upon backward movement is provided between the motor
121
and the output shaft
117
. The mechanism
123
is adapted to transmit rotational power from the motor
121
to the output shaft
117
on the basis of a driver's operation for backward movement and to rotate the output shaft
117
in a reverse direction upon forward movement. The power transmission mechanism
123
actuated for backward movement cuts off the power transmission from the output shaft
117
to the motor
121
upon operation which is not for backward movement.
An electric generator
124
linked with the crank shaft
29
is mounted on the back face of the mission case
90
in parallel to the axial line of the crank shaft
29
. A clutch
125
coaxial with the main shaft
115
, which is capable of switching the connection/disconnection between the crank shaft
29
and the main shaft
115
, is disposed on the back face of the mission case
90
. In other words, the electric generator
124
and the clutch
125
are disposed on the back face of the mission case
90
in parallel to the water pump
94
coaxial with the crank shaft
29
.
An oil pump
126
connected to the main shaft
115
via a power transmission mechanism
128
such as a chain is provided in the lower portion of the mission case
90
. Oil discharged from the oil pump
126
is supplied to respective portions to lubricate the engine main body E via an oil filter
127
(see
FIG. 2
) provided on the front surface side of the mission case
90
. The oiling passages
55
L
and
55
R
provided in the left and right cylinder blocks
23
L
and
23
R
and the left and right cylinder heads
24
L
and
24
R
for introducing oil to portions of the cam shafts
46
L
and
46
R
to be lubricated are connected to the oil filter
127
.
Referring again to
FIGS. 1 and 2
, a body frame (not shown) of the motorcycle has steps
130
L
and
130
R
on which the driver's feet are to rest. The steps
130
L
and
130
R
are mounted on left and right portions positioned behind and below the left and right cylinder heads
24
L
and
24
R
of the engine main body E in such as manner as to project leftwardly and rightwardly therefrom. The inner end of each of the steps
130
L
and
130
R
is offset a distance L
7
inwardly in the width direction of the motorcycle from the opening formed at the outer end of each of the exhaust passages
35
L
and
35
R
provided in the cylinder heads
24
L
and
24
R
.
To prevent the action of the driver's feet on the steps
130
L
and
130
R
from being obstructed by the left and right cylinder heads
24
L
and
24
R
and the left and right head covers
60
L
and
60
R
, the lower rear corners thereof are cut off as shown by reference numeral
131
.
The function of this embodiment will now be described. In the horizontally-opposed type multi-cylinder (for example, six cylinder) engine, a pair of left and right cylinder bore rows
22
L
and
22
R
disposed on both sides of the crank shaft
29
extending substantially in the horizontal direction; the left cylinder bore row
22
L
(or right cylinder bore row
22
R
) is composed of a plurality (for example, three) of the cylinder bores
21
L
(or
21
R
) disposed in parallel; and the cam shaft
46
L
(or
46
R
) corresponding to the cylinder bore row
22
L
(or
22
R
) is disposed on an upper side of the plane
38
L
(or
38
R
) containing the axial lines of the cylinder bores
21
L
(or
21
R
) and the axial line of the crank shaft
29
. Accordingly, the valve system mechanism containing the cam shaft
46
L
(or
46
R
) is offset upwardly from the axial lines of the cylinder bores
21
L
(or
21
R
), so that the cylinder head
24
L
(or
24
R
) can be formed in such a manner as to ensure a space under the portion corresponding to the valve system mechanism. In other words, a relatively large space can be ensured under the cylinder head
24
L
(or
24
R
).
When the horizontally-opposed type multi-cylinder engine is mounted on a motorcycle in such a manner that the axial line of the crank shaft
29
extends along the longitudinal direction of the motorcycle and the cylinder heads
24
L
and
24
R
project on both sides of the motorcycle in the width direction, it is possible to ensure a sufficient space for allowing the driver's feet to extend forward at a position under the cylinder heads
24
L
and
24
R
and to set a bank angle α of the motorcycle at a relatively large value.
The pairs of the intake valves
36
L
(or
36
R
) and the exhaust valves
37
L
(or
37
R
), each pair being disposed for each cylinder bore
21
L
(or
21
R
), i.e., for each combustion chamber
26
L
(or
26
R
), are disposed in parallel in such a manner as to be offset upwardly from the plane
38
L
(or
38
R
), and are directly opened/closed by the intake side cams
48
L
(or
48
R
) and the exhaust cams
49
L
(or
49
R
) provided on the cam shaft
46
L
(or
46
R
). Accordingly, the valve system mechanism for driving the intake valves
36
L
(or
36
R
) and the exhaust valves
37
L
(or
37
R
) can be significantly simplified. Furthermore, since the cam shafts
46
L
and
46
R
are disposed for the cylinder bore rows
22
L
and
22
R
, respectively, the cylinder heads
24
L
and
24
R
can be made compact.
Since the intake valves
36
L
(or
36
R
) and the exhaust valves
37
L
(or
37
R
) are disposed in the cylinder head
24
L
(or
24
R
) in such a manner as to be tiled at an acute angle with respect to the plane
38
L
(or
38
R
), it is possible to form the ceiling of each of the combustion chambers
26
L
(or
26
R
) into a pent-roof or semi-spherical shape and hence to set the S/V ratio at a relatively small value.
On the opposite side from the disposition side of the intake valves
36
L
(
36
R
) and the exhaust valves
37
L
(or
37
R
) with respect to the plane
38
L
(or
38
R
), i.e., on the lower side of the plane
38
L
(or
38
R
), the ignition plugs
39
L
(
39
R
) are mounted to the cylinder head
24
L
(or
24
R
). Each of the ignition plugs
39
L
(
39
R
) face toward the combustion chamber
26
L
(or
26
R
). Furthermore, in this case, since the intake valves
36
L
(or
36
R
) and the exhaust valves
37
L
(or
37
R
) are tilted at an acute angle with respect to the plane
38
L
(or
38
R
), it is possible to ensure a relatively wide space on the side opposite to the disposition side of the intake valves
36
L
(or
36
R
) and the exhaust valves
37
L
(or
37
R
) with respect to the plane
38
L
(or
38
R
), i.e., the lower side of the plane
38
L
(or
38
R
). Therefore, it is easy to make the ignition plugs
39
L
(or
39
R
) face toward the central portions of the combustion chambers
26
L
(or
26
R
) while avoiding interference with the intake valves
36
L
(or
36
R
) and the exhaust valves
37
L
(or
37
R
) and to increase the degree of freedom of disposition of the ignition plugs
39
L
(or
39
R
).
The ignition plugs
39
L
(or
39
R
) are tilted at an acute angle with respect to the plane
38
L
(or
38
R
). With regard to the tilting angle of the ignition plugs
39
L
(or
39
R
), since the intake valves
36
L
(or
36
R
) and the exhaust valves
37
L
(or
37
R
) are tilted at an acute angle with respect to the plane
38
L
(or
38
R
), it is possible to make the ignition plugs
39
L
(or
39
R
) face to the central portions of the combustion chambers
26
L
(or
26
R
) while avoiding the interference with the cam shafts
46
L
(or
46
R
) without setting the tilting angle of the ignition plugs
39
L
(or
39
R
) at a large value.
The cylinder head
24
L
(or
24
R
) includes the intake passages
34
L
(or
34
R
) opened toward the side surface of the cylinder head
24
L
(or
24
R
) on the upper side of the plane
38
L
(or
38
R
). Furthermore, the cylinder head
24
L
(or
24
R
) also includes the exhaust passages
35
L
(or
35
R
) opened toward the other side surface of the cylinder head
24
L
(or
24
R
) on the lower side of the plane
38
L
(or
38
R
). In other words, since the intake valves
34
L
(or
34
R
) and the exhaust valves
35
L
(or
35
R
) are provided in such a manner as to be opened toward the side surfaces of the cylinder head
24
L
(or
24
R
) on both sides of the plane
38
L
(or
28
R
), it is easy to connect the intake system
66
and the exhaust system
43
L
(or
43
R
) to the cylinder head
24
L
(or
24
R
).
On the projection chart perpendicular to the axial lines of the cylinder bores
21
L
(or
21
R
), the intake passages
34
L
(or
34
R
) are provided in the cylinder head
24
L
(or
24
R
) in such a manner as to cross the plane
38
L
(or
38
R
) substantially at right angles. In other words, since the intake valves
34
L
(or
34
R
) extend substantially in a straight line while being relatively gently curved toward the combustion chambers
26
L
(or
26
R
), it is possible to reduce the intake resistance at the intake passages
34
L
(or
34
R
) and hence to enhance the charging efficiency.
The exhaust passages
35
L
(or
35
R
) are provided in the cylinder head
24
L
(or
24
R
) in such a manner as to be curved or swelled to one end side of the cam shaft
46
L
(or
46
R
), i.e., the front side of the motorcycle, in order to bypass the ignition plugs
39
L
(or
39
R
). As a result, the flow resistance in the exhaust passages
35
L
(or
35
R
) is larger than that of the intake passages
34
L
(or
34
R
); however, no problems arise because the exhaust gas from the combustion chambers
26
L
(or
26
R
) is pressurized.
Since the cam shaft
46
L
(or
46
R
) is disposed over the axial line of the cylinder bore row
22
L
(or
22
R
) and the exhaust passages
35
L
(or
35
R
) bypass the ignition plugs
39
L
(or
39
R
) by curving toward the front side of the motorcycle, it is easy to ensure space for allowing the driver's feet to extend forward at a position behind and below the horizontally-opposed type engine mounted on the motorcycle.
While the exhaust passages
35
L
(or
35
R
) are downwardly opened toward the lower side surface of the cylinder head
24
L
(or
24
R
), the ignition plugs
39
L
(or
39
R
) are also mounted to the cylinder head
24
L
(or
24
R
) in such a manner as to be tilted downwardly. Accordingly, in the horizontally-opposed type multi-cylinder engine mounted on the motorcycle, it is possible to improve the appearance of the ignition plugs
39
L
(or
39
R
) and the surrounding area, to easily discharge water which has permeated in the vicinity of the ignition plugs
39
L
(
39
R
) on the outer surface side of the cylinder head
24
L
(or
24
R
), and to easily lay out the exhaust pipes
41
L
(
41
R
) connected to the exhaust passages
35
L
(or
35
R
).
Furthermore, since the cover portion
62
L
(or
62
R
) for covering the ignition plugs
29
L
(or
29
R
) from the outside is formed integrally with the left head cover
60
L
(or right head cover
60
R
) which is connected to the left cylinder head
24
L
(or right cylinder head
24
R
) with the valve system chamber
61
L
(or
61
R
) for containing the cam shaft
46
L
(
46
R
), it is possible to further improve the appearance of the ignition plugs
39
L
(or
39
R
) and the surrounding area.
Since the exhaust passages
35
L
(or
35
R
) are provided in the cylinder head
24
L
(or
24
R
) in such a manner as to be tilted toward the central side of the motorcycle in the width direction and to be downwardly opened to allow the exhaust pipes
41
L
(or
41
R
) connected to the exhaust passages
35
L
(or
35
R
) to be disposed near the center portion of the motorcycle in the width direction, it is possible to loosen the restriction of the bank angle α of the motorcycle due to the exhaust pipes
41
L
(or
41
R
) and hence to easily ensure the above bank angle α.
Furthermore, since the exhaust pipes
41
L
(or
41
R
) are tilted in such a manner that they become closer to the central side of the motorcycle in the width direction, since they are separated apart downwardly from the cylinder head
24
L
(or
24
R
) and are connected to the exhaust passages
35
L
(or
35
R
), it is possible to further loosen the restriction of the bank angle α of the motorcycle due to the exhaust pipes
41
L
(or
41
R
) and hence to more easily ensure the above bank angle α.
Since the exhaust valves
37
L
(
37
R
) are disposed on the upper side of the plane
38
L
(or
38
R
) while the exhaust passages
35
L
(or
35
R
) are opened toward the bottom surface of the cylinder head
24
L
(or
24
R
), it is possible to relatively increase the distance between each of the combustion chambers
26
L
(or
26
R
) and the opening end of an associated one of the exhaust passages
35
L
(or
35
R
) opened toward the bottom surface of the cylinder head
24
L
(or
24
R
). Furthermore, a relatively gentle curving of the exhaust passages
35
L
(
35
R
) within the plane perpendicular to the axial line of the crank shaft
29
can be made even though the exhaust passages
35
L
(or
35
R
) are opened while being tilted to the central side of the motorcycle in the width direction. This allows suppression of the increase in exhaust resistance.
The cover portion
62
L
(or
62
R
) formed integrally with the left head cover
60
L
(right head cover
60
R
) functions to cover connecting portions of the exhaust passages
35
L
(or
35
R
) of the exhaust pipes
41
L
(or
41
R
) from outside. This makes it possible to improve the appearance of the connecting portions of the exhaust passages
35
L
(or
35
R
) of the exhaust pipes
41
L
(or
41
R
). Furthermore, since the exhaust pipes
41
L
(or
41
R
) are separated apart from the cover portion
62
L
(or
62
R
) since directed downwardly, even if the head cover
60
L
(or
60
R
) is made from a synthetic resin, it is possible to avoid occurrence of thermal degradation of the cover portion
62
L
(or
62
R
).
With respect to the intake passages
34
L
and the exhaust passages
35
L
provided in the left cylinder head
24
L
and the intake passages
34
R
and the exhaust passages
35
R
provided in the right cylinder head
24
R
, the relative positional relationship between the intake passages
34
L
and the exhaust passages
35
L
along the axial line direction of the crank shaft
29
is set to be nearly equal to the relative positional relationship between the intake passages
34
R
and the exhaust passages
35
R
along the axial line direction of the crank shaft
29
. This makes it possible to simplify the structure of the intake system
66
and the exhaust systems
43
L
and
43
R
.
A plurality of the through-holes
56
L
(
56
R
) spaced in the axial direction of the cam shaft
46
L
(or
46
R
) are formed in the cylinder head
24
L
(or
24
R
) on the lower side of the plane
38
L
(or
38
R
) to fasten the cylinder head
24
L
(or
24
R
) to the cylinder block
23
L
(or
23
R
). The fastening bolts
57
L
(or
57
R
) are inserted in the through-holes
56
L
(or
56
R
). Furthermore, each through-hole
56
L
(or
56
R
) is adjacent, on one end side of the cam shaft
46
L
(or
46
R
), to an associated one of the exhaust passages
35
L
(or
35
R
) bypassing the ignition plugs
39
L
(or
39
R
) provided in the combustion chambers
26
L
(or
26
R
). The through-hole
56
L
(or
56
R
) has a positional relationship such that a distance L
4
between a center of the through-hole
56
L
(or
56
R
) and a center C
L
(or C
R
) of an associated combustion chamber
26
L
(or
26
R
) is larger than a value L
3
. The value L
3
is half a distance between the centers C
L
(or C
R
) of adjacent ones of the combustion chambers
26
L
(or
26
R
). This makes it possible to make the curving of the exhaust passages
35
L
(or
35
R
) bypassing the ignition plugs
39
L
(or
39
R
) relatively small. Therefore, the flow resistance of the exhaust passages
35
L
(or
35
R
) are prevented from being excessively increased.
On the disposition side of the intake valves
36
R
and the exhaust valves
37
R
with respect to the plane
38
R
, the right cylinder head
24
R
has a plurality of the through-holes
58
R
which are spaced in the axial line direction of the cam shaft
46
R
. Of the plurality of the through-holes
58
R, the central side through-holes
58
R
are each disposed between adjacent ones of the combustion chambers
26
R
. A distance L
5
between a center of the through-hole
58
R
disposed at the outermost end on one end side of the cam shaft
46
R
and the center C
R
of the combustion chamber
26
R
disposed at the outermost end on the one end side of the cam shaft
46
R
is set to be smaller than the value L
3
. The value L
3
is, as described above, half the distance between the centers C
R
of adjacent ones of the combustion chambers
26
R
. Accordingly, the end portion of the cylinder head
24
R
on the one end side of the cam shaft
46
R
can be made as close to the center C
R
of the combustion chamber
26
R
which is disposed at the outermost end on the curved side of the exhaust passages
35
R
bypassing the ignition plugs
39
R
, as possible. This makes the length of the cylinder head
24
R
along the axial direction of the cam shaft
46
R
as small as possible.
The cam shaft
46
L
(or
46
R
) is rotatably supported at a plurality of locations spaced in the axial direction of the cam shaft
46
L
(or
46
R
) by the cam bearing portions
50
L
(or
50
R
) provided on the cylinder head
24
L
(or
24
R
) and the cam holder
51
L
(or
51
R
) fastened to the cam bearing portions
50
L
(or
50
R
). The transmission mechanism
68
L
(or
68
R
), which reduces rotational power of the crank shaft
29
to half and transmits the reduced rotational power to the cam shaft
46
L
(or
46
R
), is provided between the crank shaft
29
and the cam shaft
46
L
(or
46
R
). The oil passage
52
L
(or
52
R
), which is capable of supplying oil from the oiling passage
55
L
(or
55
R
) provided in the cylinder head
24
L
(or
24
R
) and the cylinder block
23
L
(or
23
R
), is provided in the cam shaft
46
L
(or
46
R
). On the left cylinder head
24
L
side, oil is supplied from the oil groove
54
L
provided in the cam bearing portion
50
L
disposed at the outermost end on the one end side of the cam shaft
46
L
into the oil passage
52
L
in the cam shaft
46
L
via the oiling hole
53
L
formed in the cam shaft
46
L
. On the right cylinder head
24
R
side, the oil groove
54
R
for supplying oil into the oil passage
52
R
in the cam shaft
46
R
via the oiling hole
53
R
formed in the cam shaft
46
R
is formed in the cam bearing portion
50
R
which is provided in the cylinder head
24
R
correspondingly to the combustion chamber
26
R
closest to the transmission mechanism
68
R
among the plurality of combustion chambers
26
R
disposed in the axial direction of the cam shaft
46
R
.
With this disposition of the oil groove
54
R
, it is possible to supply oil into the oil passage
52
R
in the cam shaft
46
R
without restriction of the disposition of the fastening bolts
57
R
and
59
R
for fastening the right cylinder head
24
R
to the right cylinder block
23
R
.
The cam bearing portion
50
R
closest to the transmission mechanism
68
R
among the plurality of the cam bearing portions
50
R
provided on the right cylinder head
24
R
has the through-hole
58
R
into which the fastening bolt
59
R
among the fastening bolts
57
R
and
59
R
for fastening the cylinder head
24
R
to the cylinder block
23
R
is to be inserted. As a result, the fastening bolt
59
R
between the transmission mechanism
68
R
and the combustion chamber
26
R
is made as close to the combustion chamber
26
R
as possible, so that it is possible to shorten the length of the cylinder head
24
R
along the axial line direction of the cam shaft
46
R
.
The transmission mechanism
68
R
corresponding to the cam shaft
46
R
on the right cylinder head
24
R
side is offset forwardly along the axial line direction of the crank shaft
29
from the transmission mechanism
68
L
corresponding to the cam shaft
46
L
on the left cylinder head
24
L
. In other words, the outermost end on one end side of the cam shaft
46
R
is offset forwardly from that of the cam shaft
46
L
, and the transmission mechanism
68
R
is connected to the outermost end on the one end side of the cam shaft
46
R
. The above through-hole
58
R
and the above oil groove
54
R
are provided in two of the plurality of the cam bearing portions
50
R
provided on the cam shaft
46
R
. Accordingly, it is possible to shorten the length between the transmission mechanism
68
R
and the combustion chamber
26
R
and hence to more effectively shorten the length of the multi-cylinder engine along the axial line direction of the cam shaft
46
L
(or
46
R
).
The pair of the cylinder bore rows
22
L
and
22
R
are offset from each other in the axial line direction of the crank shaft
29
. Furthermore, the transmission mechanisms
68
L
and
68
R
are disposed in such a manner that the gap L
6
therebetween is smaller than the first offset amount L
1
between the cylinder bore rows
22
L
and
22
R
. Accordingly, it is possible to set the gap between the transmission mechanisms
68
L
and
68
R
at a smaller value, and hence to decrease the length of the engine main body E along the axial line direction of the cam shaft
46
L
(
46
R
).
Furthermore, since both the transmission mechanisms
68
L
and
68
R
are provided between one end portion of the crank shaft
29
and one end portion of the cam shaft
46
L
and between one end portion of the crank shaft
29
and the one end portion of the cam shaft
46
R
, respectively, it is possible to more freely set the gap between the transmission mechanisms
68
L
and
68
R
.
The outer end opening of each of the exhaust passages
35
L
(or
35
R
) opened toward the bottom surface of the left cylinder head
24
L
(or right cylinder head
24
R
) is offset toward one end side of the cam shaft
46
L
(or
46
R
), i.e., toward the transmission mechanism
68
L
(or
68
R
) from the center C
L
(or C
R
) of an associated one of the combustion chambers
26
L
(or
26
R
). Accordingly, the exhaust systems
43
L
and
43
R
respectively connected to the exhaust passages
35
L
and
35
R
can be disposed by making effective use of the space between the transmission mechanisms
68
L
and
68
R
, so that the entire engine including the exhaust systems
43
L
and
43
R
can be made compact.
Since the transmission mechanisms
68
L
and
68
R
are disposed on the front portion of the engine main body E, a relatively large space is formed at a location positioned behind and below the left and right cylinder heads
24
L
and
24
r
, the steps
130
L
and
130
R
on which the driver's feet are to rest can be disposed behind the left and right cylinder heads
24
L
and
24
R
without any difficulty. Furthermore, since the inner end portion of each of the steps
130
L
and
130
R
is offset inwardly from the outer end opening of each of the exhaust passages
35
L
and
35
R
in the width direction of the motorcycle, the projecting amounts of the steps
130
L
and
130
R
in the width direction of the motorcycle is made as small as possible, so that the restriction of the steps
130
L
and
131
R
to the bank angle α can be suppressed.
The transmission mechanism
68
L
(or
68
R
) performs power transmission using the chain
71
L
(or
71
R
) . The transmission chamber
72
L
(
72
R
), having one end in communication with the valve system chamber
61
L
(or
61
R
) and the other end facing toward one end of the crank shaft
29
and containing the transmission mechanism
68
L
(or
68
R
), extends from the head cover
60
L
(or
60
R
) to the crank case
27
L
(or
27
R
) via the cylinder head
24
L
(or
24
R
) and the cylinder block
23
L
(or
23
z). The other end of the transmission chamber
72
L
(or
72
R
) is in communication with the crank chamber
28
.
Unlike a belt-type transmission mechanism, the transmission chamber
72
L
(or
72
R
) containing the transmission mechanism
68
L
(or
68
R
) allows oil to flow therethrough. Accordingly, it is possible to eliminate the necessity of provision of any means for preventing leakage of oil from the crank case
27
L
(or
27
R
) side onto the transmission chamber
72
L
(or
72
R
) side. More specifically, the necessity of provision of a seal structure on the crank case
27
L
(or
27
R
) is eliminated. Therefore, the engine is made as compact as possible.
Furthermore, since the cam shaft
46
L
(or
46
R
) is disposed over the crank shaft
29
, oil in the valve system
61
L
(or
61
R
) is allowed to flow onto the crank shaft
29
side at the lower level through the transmission chamber
72
L
(or
72
R
). As a result, oil in the valve system chamber
61
L
(or SI
R
) is easily returned to the crank case
27
L
(or
27
R
) side.
In addition, the return hole
85
is provided in the left and right crank cases
27
L
and
27
R
to communicate the bottom portions of the other ends of the transmission chambers
72
L
and
72
R
into the crank chamber
28
. Accordingly, it is not required to provide oil return passages specialized for the cylinder blocks
23
L
and
23
R
and the cylinder heads
24
L
and
24
R
for returning oil from at least the transmission chambers
72
L
and
72
R
into the crank chambers
28
. Therefore, the cylinder blocks
23
L
and
23
R
and the cylinder blocks
24
L
and
24
R
can be made compact and reduced in weight.
The crank shaft
29
is rotatably supported by a plurality of the journal walls
31
formed integrally with the left crank case
27
L
and a plurality of bearing caps
32
fastened to the journal walls
31
. The return hole
85
is extended in the fastening direction of the bearing caps
32
to the journal walls
31
. Accordingly, it is possible to make the opening area of the return hole
85
relatively wide without reducing the supporting rigidity of the crank shaft
29
. Therefore, the return of oil into the crank chamber
28
is enhanced.
The return hole
35
is formed in the left and right crank cases
27
L
and
27
R
in such a manner as to be offset toward the left crank case
27
L
side. Accordingly, it is possible to increase the opening area of the return hole
85
avoiding a reduction in rigidity of the crank case on which the journal walls
31
are not integrally formed, i.e., the right crank case
27
R
. Therefore, the return of the oil is further enhanced.
In the transmission mechanism
68
L
provided between the left side cam shaft
46
L
and the crank shaft
29
, the chain tensioner
79
L
extending along the running direction of the chain
71
L
is elastically, slidably in contact with the chain
71
L
. One end of the chain tensioner
79
L
in the longitudinal direction is turnably supported by the bearing cap
32
closest to the transmission mechanism
68
L
among a plurality of the bearing caps
32
. With this configuration, it is possible to moderate the restriction in the rotatably supporting position of the chain tensioner
79
L
and to confine the behavior of the chain
71
L
by setting the length of the chain tensioner
79
L
at a relatively large value.
Since the transmission mechanism
68
L
is provided between one end portion of the cam shaft
46
L
and one end portion of the crank shaft
29
, it is not required to take into account the disposition of the rotatably supporting portion of the chain tensioner
79
L
at a position where the chain tensioner
79
L
does not interfere with a crank weight of the crank shaft
29
. This makes it possible to simply set the rotatably supporting position of the chain tensioner
79
L
.
Since one end of the chain tensioner
79
L
for the transmission mechanism
68
L
on the cylinder block
23
L
side on which the journal walls
31
are integrally formed is rotatably supported by the bearing cap
32
closest to the transmission mechanism
68
L
, it is possible to simply set the rotatably supporting position of the chain tensioner
79
L
by making effective use of one of the bearing caps
32
necessarily provided for the horizontally-opposed type multi-cylinder engine.
The pump shaft
95
of the water pump
94
is directly connected to the other end of the crank shaft
29
with one end side connected to the transmission mechanisms
68
L
and
68
R
, i.e., the rear end of the crank shaft
29
along the longitudinal direction of the motorcycle, and the water pump
94
is directly driven by the crank shaft
29
. Accordingly, it is possible to eliminate the necessity of a gear, a chain, a belt, etc. required for driving the conventional water pump, and therefore simplify the drive mechanism of the water pump
94
.
The pulse rotor
75
for detecting a rotational position of the crank shaft
29
is fixed to one end portion of the crank shaft
29
. By use of the pulse rotor
75
, it is possible to easily detect a rotational position of the crank shaft
29
with no obstruction by the water pump
94
.
Since the water pump
94
is disposed on the rear side in the longitudinal direction of the motorcycle, a piping system for cooling water, connected to the water pump
94
, can be disposed at an inconspicuous position.
Since the radiators
113
L
and
113
R
are respectively disposed over the engine blocks B
L
and B
R
, i.e., over the cylinder bore rows
22
L
and
22
R
, pipes for cooling water between the engine and the radiators
113
L
and
113
R
are made nearly equal on the left and right sides or are even shortened.
Since the electric generator
124
and the clutch
125
are disposed in parallel with the water pump
94
, it is not required to increase the length of the crank shaft
29
for disposing the electric generator
124
and the clutch
125
in spite of the fact that the water pump
94
is directly driven by the crank shaft
29
. Accordingly, it is possible to make the engine compact in the axial direction of the crank shaft
29
.
The casing
96
of the water pump
94
is composed of the pump body
97
for rotatably supporting the pump shaft
95
, and the pump cover
98
connected to the pump body
97
in such a manner as to cover the impeller
99
fixed to the pump shaft
95
. The thermostat
102
held between the pump body
97
and the pump cover
98
is contained in the containing portion
101
formed in the pump cover
98
. As a result, in the case of additionally providing the thermostat
102
in the water pump
94
, it is possible to reduce the number of parts, and hence to reduce the cost and weight and the number of assembling steps.
The first suction port
106
opened toward one end of the containing portion
101
is provided in the pump body
97
in such a manner as to be in communication with the radiators
113
L
and
113
R
. The second suction port
107
opened toward the other end of the containing portion
101
for introducing water from the engine not by way of the radiators
113
L
and
113
R
is provided in the pump cover
98
. The thermostat
102
having the thermostat valve
104
for opening/closing the first suction port
106
and the bypass valve
105
for opening/closing the second suction port
107
is contained in the containing portion
101
. Accordingly, when the temperature of cooling water is low, the thermostat valve
104
is closed and the bypass valve
105
is opened, while as the temperature of cooling water is increased, the thermostat valve
104
is opened and the bypass valve
105
is closed. In this way, the bottom-bypass type cooling water circuit can be simply obtained.
Since the discharge port
108
for discharging cooling water discharged depending on rotation of the impeller
99
is provided in the pump cover
98
, it is possible to simply obtain a circuit for introducing cooling water from the water pump
94
.
Since the thermostat
102
is disposed over the impeller
99
, it is possible to release air in the water pump
94
by means of the jiggle valve
114
of the thermostat
102
.
FIG. 15
shows a second embodiment of the present invention. In a V-shaped multi-cylinder engine in which both the cylinder bore rows
22
L
and
22
R
are disposed in an approximately V-shape, the cam shafts
46
L
and
46
R
corresponding to the cylinder bore rows
22
L
and
22
R
are disposed over the planes
38
L
and
38
R
containing the axial lines of the cylinder bores
21
L
and
21
R
constituting the cylinder bore rows
22
L
and
22
R
, respectively.
When such a V-shaped multi-cylinder engine is mounted on the motorcycle with the crank shaft
29
extending in the longitudinal direction of the motorcycle, a width W of the multi-cylinder engine in the width direction of the motorcycle can be set at a value smaller than that for a V-shaped multi-cylinder engine in which a single cam shaft is disposed within each of the planes
38
L
and
38
R
or a pair of cam shafts are disposed on both sides of each of the planes
38
L
and
38
R
(shown by chain lines in FIG.
15
), with a result that the V-shaped multi-cylinder engine can be made compact.
As described above, according to a first aspect of the present invention, since the valve system mechanism containing the cam shaft is offset upwardly from the axial lines of the cylinder bores, it is possible to ensure a relatively large space under the cylinder head.
According to a second aspect of the present invention, in mounting the horizontally-opposed type multi-cylinder engine on the motorcycle, it is possible to ensure a sufficient space allowing the driver's feet to extend forwardly under the cylinder heads, and to set the bank angle of the motorcycle at a relatively large value.
According to a third aspect of the present invention, in mounting the V-shaped multi-cylinder engine on the motorcycle, it is possible to set the width of the multi-cylinder engine in the width direction of the motorcycle at a relatively small value, and hence to make the V-shaped multi-cylinder engine compact.
According to a fourth aspect of the present invention, it is possible to simplify the configuration of the valve system mechanism driving the intake valves and exhaust valves.
According to a fifth aspect of the present invention, it is possible to make the cylinder head compact.
The invention being thus described, it will be obvious that the same may be varied in many ways. Such variations are not to be regarded as a departure from the spirit and scope of the invention, and all such modifications as would be obvious to one skilled in the art are intended to be included within the scope of the following claims.
Claims
- 1. A multi-cylinder engine for a vehicle, comprising:a crank shaft disposed in a substantially horizontal direction in the multi-cylinder engine; a pair of cylinder bore rows arranged perpendicular to the crank shaft, each of said pair of cylinder bore rows including a plurality of cylinder bores disposed in parallel with each other; cam shafts corresponding to said cylinder bore rows are spaced from and disposed above a pair of planes containing axial lines of said cylinder bores, respectively, wherein each one of said cam shaft operates intake valves and exhaust valves that are disposed substantially above a respective one of said pair of planes; and wherein said engine is mounted on said vehicle with said cylinder bore rows opposed to each other and with the axial lines of said cylinder bores extending substantially in the horizontal direction, and said crank shaft extends in a longitudinal direction of said vehicle.
- 2. A multi-cylinder engine for a vehicle according to claim 1, further comprising cams for directly opening/closing said intake valves and said exhaust valves disposed in cylinder heads of each of said cylinder bores are provided on said cam shafts, respectively.
- 3. A multi-cylinder engine for a vehicle according to claim 2, wherein each of said cam shafts is common to said intake valves and said exhaust valves for each of said cylinder bore rows.
- 4. A multi-cylinder engine for a vehicle according to claim 1, wherein said each of said cam shafts is common to said intake valves and said exhaust valves for each of said cylinder bore rows.
- 5. A vehicle, comprising:a multi-cylinder engine mounted in said vehicle; a crank shaft disposed in a substantially horizontal direction in the multi-cylinder engine; a pair of cylinder bore rows arranged perpendicular to the crank shaft, each of said pair of cylinder bore rows including a plurality of cylinder bores disposed in parallel with each other; cam shafts corresponding to said cylinder bore rows are spaced from and disposed above a pair of planes containing axial lines of said cylinder bores, respectively, wherein each one of said cam shaft operates intake valves and exhaust valves that are disposed substantially above a respective one of said pair of planes; and wherein said engine is mounted on said vehicle with said cylinder bore rows opposed to each other and with the axial lines of said cylinder bores extending substantially in the horizontal direction, and the crank shaft of said engine extends in a longitudinal direction of said vehicle.
- 6. The vehicle according to claim 5, further comprising cams for directly opening/closing said intake valves and said exhaust valves disposed in cylinder heads of each of said cylinder bores are provided on said cam shafts, respectively.
- 7. The vehicle according to claim 6, wherein each of said cam shafts is common to said intake valves and said exhaust valves for each of said cylinder bore rows.
- 8. The vehicle according to claim 5, wherein said each of said cam shafts is common to said intake valves and said exhaust valves for each of said cylinder bore rows.
- 9. The vehicle according to claim 5, wherein said vehicle is a motorcycle.
Priority Claims (1)
Number |
Date |
Country |
Kind |
10-282389 |
Oct 1998 |
JP |
|
US Referenced Citations (5)
Foreign Referenced Citations (1)
Number |
Date |
Country |
A61-291760 |
Dec 1986 |
JP |