GB2199372A - I.c. engine cylinder head - Google Patents

Description

"INTERNA COMBUSTION ENGINE" The present invention relates to an internal combustion engine and more particularly to the construction of an overhead valve type cylinder head of such an engine.

Conventional internal combustion engines with overhead valves include a cylinder head normally having a head cover attachment surface lying parallel to the joining surface or interface along which the cylinder head is joined to the cylinder block. The cylinder head also has an intake manifold attachment surface slanted at an angle with respect to the head cover attachment surface and the joining interface. Thus, when the cylinder head is manufactured, the head cover attachment surface and the intake manifold attachment surface must individually be machined at a high degree of machining accuracy.

It would be highly advantageous if the head cover attachment surface and the intake manifold attachment surface were in the same plane so that they could simultaneously be machined by one cutting tool whereby these attachment surfaces would be machined highly accurately in one process. In U. S. Patent No. 2,856,909 an engine is disclosed with cylinder heads having the head cover attachment surface and intake manifold attachment surface in the same plane but the valve operating mechanism and valves are all on one side of the cylinders.

In more modern overhead cam and valve type engines the valves are on both sides of the combustion chamber and the cylinder head is fully open at its upper end to provide a window to the valve mechanism chamber defined in the cylinder head, the window being closed by a head cover attached to the upper surface of the cylinder head. It is desirable to position the spark plug in the center of the ceiling of the combustion chamber, and plug housings-in which the spark plugs are accommodated extend between the head cover and the ceiling walls of combustion chambers in the cylinder head. Sealing members are interposed between the plug housings and the head cover. The spark plugs thus arranged can ignite the air-fuel mixture substantially centrally in the respective combustion chambers for a higher engine power output and better fuel economy. When the head cover is to be detached from the cylinder head for inspecting and servicing the valve operating mechanism in the valve mechanism chamber, the head cover must also be separated from the plug housings.

Therefore, at the time of attaching the head cover again to the cylinder head, it is necessary to mount the sealing members properly between the head cover and the plug housings. Such a mounting process is however tedious and time-consuming. If the seal membersare mounted improperly or damaged, lubricating oil in the valve mechanism chamber will leak into the plug housing.

Viewed from one aspect the present invention provides an internal combustion engine comprising: a cylinder head having a plurality of combustion chambers having a common centerline, intake and exhaust ports communicating with each of said combustion chambers on opposite sides of the centerline, intake and exhaust valves for opening and closing said intake and exhaust ports respectively, a valve mechanism chamber defined above said combustion chambers, and a valve operating mechanism housed in said valve mechanism chamber on both sides of the combustion chamber centerline for actuating said intake and exhaust valves, said valve mechanism chamber having a window to provide access therethrough to said valve operating mechanism; a head cover removably attached to said cylinder head in closing relation to said window ; and an intake manifold attached to said cylinder head in communication with said intake ports ; said cylinder head having attachment surfaces which lie in a common plane and to which said head cover and said intake manifold are attached, respectively.

Viewed from another aspect the present invention provides an internal combustion engine comprising: a cylinder block having a plurality of cylinders each having an axis ; a cylinder head having a plurality of combustion chambers having respective ceiling walls and opening into said cylinders, intake and exhaust ports communicating with each of said combustion chambers on opposite sides of said axis, intake and exhaust valves disposed on each side of said axis of each of the cylinders for opening and closing said intake and exhaust ports respectively, a valve mechanism chamber defined above said combustion chambers, and a valve operating mechanism housed in said valve mechanism chamber for actuating said intake and exhaust valves, said valve mechanism chamber being defined by a pair of opposite trapezoidal end walls extending from the bottom of the valve mechanism chamber and a ceiling wall integrally interconnecting the upper ends of said trapezoidal end walls, said valve mechanism chamber having a pair of windows defined one on each side of the ceiling wall thereof between said trapezoidal end walls to provide access therethrough to said valve operating mechanism, said cylinder head having cover attachment surfaces extending peripherally around said windows, respectively, and a plurality of cylindrical plug housings extending between said ceiling walls of the combustion chambers and said ceiling wall of the valve mechanism chamber; a plurality of spark plugs mounted on said ceiling walls, respectively, and accommodated in said plug housings, respectively, in substantial alignment with the axes of said cylinders ; and a pair of head covers removably attached respectively to said cover attachment surfaces in closing relation to said windows.

Viewed from a further aspect the invention provides in an internal combustion engine with a plurality of cylinders in a line, a cylinder head having a combustion chamber ceiling for each cylinder, said ceilings having a common centerline extending along the line of cylinders, intake valves and ports on one side of said centerline and exhaust valves and ports on the other side of said centerline, said cylinder head having a first window opposite said intake valves and a second window opposite said exhaust valves for access to said valves, a ceiling wall in said cylinder head between said first and second windows, and spark plug housings extending from said ceiling wall to substantially the centerline of each said combustion chamber ceiling for receiving a spark plug.

An embodiment of the invention will now be described by way of example and with reference to the accompanying drawings, in which: Fig. l, is a front elevation view, partly in cross section, of a V-type multicylinder internal combustion engine according to the present invention ; Fig. 2 is an enlarged cross-sectional view of the cylinder head portion of the internal combustion engine shown in Fig. 1; Fig. 3 is a fragmentary bottom view of one combustion chc ceiling of the cylinder head of the internal combustion engine; and Figs. 4 and 5 are perspective view of the top and side, respectively, of one of the cylinder heads.

Fig. 1 shows a V-type multicylinder internal combustion engineincluding two cylinder arrays Cl, C2 arranged in a V shape as viewed in front elevation. The cylinder arrays Cl, C2 define a central space or valley V therebetween in which there is disposed a common intake manifold Mi communicating with intake ports 8 of the cylinder arrays C1, C2.

Since the cylinder arrays Cl, C2 are symmetrical in construction, only the cylinder array Cl positioned on the lefthand side in Fig. 1 will be described in detail below.

The cylinder array Cl has a cylinder block 2 defining cylinders 1 therein and a cylinder head 3 secured to the upper surface of the cylinder block 2 with a gasket 4 interposed therebetween. A piston 5 is slidably fitted in each of the cylinders 1. The cylinder head 3 has a combustion chamber 6 defined between in its bottom surface and the top of the piston 5.

The cylinder blocks 2 of the cylinder arrays Cl, C2 are integrally formed with a common crankcase 7 shared by the cylinder arrays C1, C2. A common crankshaft 10 is rotatably supported in the crankcase 7 and operatively coupled to the pistons 5 in the cylinder arrays Cl, C2 in a conventional manner.

As shown in Figs. 1 and 3, each combustion chamber 6 has a ceiling wall surface on the cylinder head comprising two slanted surfaces lla, llb inclined progressively downwardly away from each other from a diametrical central line L extending approximately across the axis Ac of the cylinder 1 parallel to crankshaft 10. The center lines L of all of the combustion chambers 6 in the respective cylinder arrays Cl, C2 are on a common line.

Each of the intake ports 8 has a pair of inlet holes opening in the slanted surface lla closer to the valley V, and each of the exhaust ports 9 has a pair of outlet holes opening in the opposite slanted surface llb, each pair of inlet and outlet holes being arranged parallel to the line L. A pair of intake valves 12 and another pair of exhaust valves 13 for opening and closing the intake and exhaust ports 8,9 are slidably supported in valve guide sleeves 14,15, respectively, which are mounted in the cylinder head 3.

As illustrated in Fig. 2, spark plugs 16 (only one shown) are threadedly mounted in a ceiling wall 6a of the combustion chamber 6 with the spark plug electrodes positioned in the combustion chamber 6. The spark plug 16 is substantially aligned with the axis Ac of the cylinder 1 and surrounded by the four intake and exhaust valves 12,13 (see Fig. 3). By this arrangement an extremely efficient intake and ignition of the air-fuel mixture and exhaust of the burned mixture is accomplished.

As shown in Figs. 1 and 2, the cylinder head 3 defines therein a water jacket 17 above the combustion chambers 6 and a valve mechanism chamber 18 above the water jacket 17.

The valve mechanism chamber 18 accommodates therein a valve operating mechanism A for actuating the intake and exhaust valves 12, 13 to open and close the intake and exhaust ports 8,9.

As shown in Fig. 1, valve springs 19,20 are disposed around the valve stems of the intake and exhaust valves 12,13, respectively, and act thereon for normally urging them to close the intake and exhaust ports 8, 9.

A single cam shaft 21 is disposed substantially directly above the intake valves 12, i. e., in a position deviated from the cylinder axis Ac toward the valley V. The cam shaft 21 extends parallel to the crankshaft 10 and is operable thereby through a synchronous transmission mechanism (not shown). As illustrated in Fig. 2, the cam shaft 21 is rotatably supported between a series of longitudinally spaced bearing bases 22 (only one shown) integral with the cylinder head 3 and bearing caps 24 (only one shown) fastened by bolts 23 to the bearing base 22.

By positioning the cam shafts 21 in the cylinder arrays Cl, C2 closer to the valley V, the maximum outer dimensions of the cylinder arrays Cl, C2 are minimized to reduce the overall size of the V-type engine.

As shown in Fig. 1, the cam shaft 21 has intake and exhaust cams 21i, 21e operatively associated with the intake and exhaust valves 12,13, respectively. First cam followers 25 are interposed between the intake cams 21i and the heads or upper ends of the valve stems of the intake valves 12, and have sides held in sliding engagement with the intake cams 21i.

Each of the first cam followers 25 has an end pivotally supported on the hemispherical end 27a of a first hydraulic tappet 27 mounted in a supporting hole 26 defined in the cylinder head 3.

A second cam follower 28 has an intermediate portion with a side thereof held in sliding engagement with each exhaust cam 21e. Each second cam follower 28 has an upper end operatively coupled through an interlink mechanism 29 to the exhaust valve 13 and a lower end pivotally supported on the hemispherical end 31a of a second hydraulic tappet 31 mounted in a supporting hole 30 defined in the cylinder head 3.

Each of the interlink mechanisms 29 comprises a pusher rod 32 having one end engaging the second cam follower 28 at a point spaced from the cam shaft 21, and a bellcrank-shaped rocker arm 33 having one end engaging the opposite end of the pusher rod 32 and the other end engaging the head or upper end of the valve stem of the exhaust valve 13. The rocker arm 33 is pivotally supported on a rocker shaft 34 that is supported on bearing bosses 35 integral with the cylinder head 3.

During operation of the engine, the cam shaft 21 in each of the cylinder arrays Cl, C2 is rotated by the crankshaft 10 through a non-illustrated synchronous transmission mechanism. When each piston 5 starts its intake stroke, the raised portions of the intake cams 21i push the first cam followers 25 toward the intake valves 12, causing the followers 25 to pivot about the hemispherical ends 27a. of the first hydraulic tappets 27. The intake valves 12 open the intake port 8 against the resilient forces of the valve springs 19 for thereby introducing an air-fuel mixture into the combustion chamber 6 through the intake manifold Mi and the intake port 8. The intake valves 12 close approximately at the end of the intake stroke of piston 5 which then starts the compression stroke toward the cylinder head 3.

When the compressed air-fuel mixture in the combustion chamber 6 is ignited by a spark produced by the spark plug 16 as the piston 5 is about to reach the end of its compression stroke, the air-fuel mixture is combusted and the piston 5 begins an expansion or power stroke. Inasmuch as the spark plug 16 is positioned in alignment with or close to the axis Ac of the cylinder 1, the flame propagation distances from the igniting point to the peripheral edge of the combustion chamber 6 are substantially equal to allow the entire air-fuel mixture to be burned in a short period of time. Therefore, the power output of the engine is increased and its fuel economy is improved.

Following the power stroke, as the piston 5 initiates an exhaust stroke the raised portions of the exhaust cams 21e push the second cam followers 28 about the hemispherical ends 31a of the second hydraulic tappets 31 for thereby pushing the pusher rods 32 to turn the rocker arms 33 toward the exhaust valves 13. The exhaust valves 13 are moved against the resi liency of the valve springs 20 to open the exhaust port 9 for discharging the exhaust gas from the combustion chamber 6 into the exhaust port 9.

When the intake and exhaust valves 12,13 are closed, the first and second hydraulic tappets 27,31 are extended in the known manner to cause the hemispherical ends 27a, 31a to push the ends of the cam followers 25,28 for eliminating any gap which would otherwise be produced between cam followers 25,28 and the heads of the stem of valve 12 and rod 32, respectively.

As illustrated-in Figs. 4 and 5, the valve mechanism chamber 18 is defined by a rectangular surrounding wall 40 extending upwardly from the peripheral edge of the bottom of the chamber 18, a pair of generally trapezoidal shaped end walls 41, 42 extending upwardly at the longitudinally opposite ends of the surrounding wall 40 beyond the upper edge thereof, and a ceiling wall 43 interconnecting the upper ends of the trapezoidal end walls 41, 42. The cylinder head 3 has two windows 44,45 defined one on each side of the ceiling wall 43 and extending between the end walls 41,42. The windows 44,45 are open above the intake and exhaust valves 12,13, respectively, to provide access to the valve operating mechanism A, which can therefore be inspected and serviced through the windows 44,45. The cam shaft 21 is positioned in the window 44 which is closer to the valley V.

Cover attachment surfaces 46,47 are formed around the windows 44,45, respectively, and slang progressively downwardly from the ceiling wall 43 toward the surrounding wall 40. Head covers 48,49 (Figs. 1 and 2) are attached by bolts to the cover attachment surfaces 46,47.

As illustrated in Figs. 2,4 and 5, cylindrical plug housings 50 are integrally formed with the ceiling walls 6a of the combustion chambers 6 and project upwardly for accommodating the spark plugs 16 respectively therein. The plug housings 50 extend through the water jacket 17 and the valve mechanism chamber 18 and have open upper ends. The plug housings 50 are disposed between and integrally connected to the ceiling wall 43 of the valve mechanism chamber 18 and a ceiling wall 17a of the water jacket 17. High-voltage ignition cables (not shown) are connected to the respective spark plugs 16 through the plug housings 50. The spark plugs 16 can be attached and detached by a tool (not shown) insertable through the plug housings 50. Since the head cover 48,49 are positioned on each side of the plug housings 50 without direct engagement therewith, the head covers 48,49 can easily be attached to and detached from the cylinder head 3 independently of the plug housings 50. Therefore, the valve operating mechanism A can efficiently be inspected and serviced.

Bridges 51,52 are integrally joined between the plug housings 50 and the opposite side wall members of the surrounding wall 40. The bearing bases 22 are integral with the bridges51 and the bearing bosses 35 are integral with the bridge 52. By this integral construction, the plug housings 50, the bearing bases 22, and the bearing bosses 35 are very rigid.

The cylinder head 3 has an attachment surface 53 to which the intake manifold Mi is attached and joint surfaces 54 of the bearing bases 22 to which the bearing caps 24 are joined. The attachment surface 53 and the joint surfaces 54 lie in the same plane with the inner cover attachment surface 46 close to the valley V in a substantially horizontal common plane extending across the cylinder arrays Cl, C2, as shown in Fig. 1. Therefore, these surfaces 53, 54, 46 of the cylinder arrays Cl, C2 can be machined simultaneously with a common cutting tool, whereby the cylinder head 3 can be machined highly accurately and efficiently.

The outer cover attachment surface 47 remote from the valley V is defined in a substantially vertical plane to minimize the maximum outer dimensions of each of the cylinder arrays Cl, C2. Since only the cover 49 is attached to the surface 47 and no other engine components are attached to the surface 47, the angle and spacing of surface 47 relative to the other surfaces on the cylinder head are not critical whereby the machine of surface 47 may be easily accomplished.

It will thus be seen that the present invention, at least in its preferred forms, provides an internal combustion engine having a cylinder head which can be machined highly accurately and efficiently: and furthermore provides a cylinder head including spark plugs positioned in substantial alignment with the axes of cylinders, and a head cover attachable to and detachable from the cylinder head and separate from the plug housings in which the spark plugs are accommodated, so that both good engine performance and good serviceability of a valve operating mechanism can be ensured.

It is to be clearly understood that there are no particular features of the foregoing specification, or of any claims appended hereto, which are at present regarded as being essential to the performance of the present invention, and that any one or more of such features or combinations thereof may therefore be included in, added to, omitted from or deleted from any of such claims if and when amended during the prosecution of this application or in the filing or prosecution of any divisional application based thereon.

Claims (12)

1. Claims 1. An internal combustion engine comprising: a cylinder block having a plurality of cylinders each having an axis ; a cylinder head having a plurality of combustion chambers having respective ceiling walls and opening into said cylinders, intake and exhaust ports communicating with each of said combustion chambers on opposite sides of said axis, intake and exhaust valves disposed on each side of said axis of each of the cylinders for opening and closing said intake and exhaust ports respectively, a valve mechanism chamber defined above said combustion chambers, and a valve operating mechanism housed in said valve mechanism chamber for actuating said intake and exhaust valves, said valve mechanism chamber being defined by a pair of opposite trapezoidal end walls extending from the bottom of the valve mechanism chamber and a ceiling wall integrally interconnecting the upper ends of said trapezoidal end walls, said valve mechanism chamber having a pair of windows defined one on each side of the ceiling wall thereof between said trapezoidal end walls to provide access therethrough to said valve operating mechanism, said cylinder head having cover attachment surfaces extending peripherally around said windows, respectively, and a plurality of cylindrical plug housings extending between said ceiling walls of the combustion chambers and said ceiling wall of the valve mechanism chamber ; a plurality of spark plugs mounted on said ceiling walls, respectively, and accommodated in said plug housings, respectively, in substantial alignment with the axes of said cylinders; and a pair of head covers removably attached respectively to said cover attachment surfaces in closing relation to said windows.
2. 2-An internal combustion engine according to claim If wherein said cylinder block comprises a pair of cylinder arrays each having said cylinders and interconnected in a V shape with a central space defined between said cylinder arrays, a said cylinder head being mounted on each of said cylinder arrays
3. 3. An internal combustion engine according to claim 2, wherein said valve operating mechanism in each of the cylinder heads has a cam shaft operatively associated with said intake and exhaust valves and positioned in one of said windows which is closer to said central space.
4. 4. An internal combustion engine according to claim 2 or 3, wherein one of said cover attachment surfaces which is remoter from said central space extends in a substantially vertical plane.
5. 5. An internal combustion enaine according to any of claims 1 to 4, including an intake manifold attached to the or each said cylinder head in communication with said intake ports, the or each said cylinder head having an attachment surface which lies in a common plane with one of said cover attachment surfaces and to which said intake manifold is attached.
6. 6. An internal combustion engine according to claim 5, wherein the or each said cylinder head includes a plurality of bearing bases integral therewith and a plurality of bearing caps joined respectively thereto through respective joint surfaces of the bearing bases, said valve operating mechanism having a cam shaft rotatably supported between said bearing bases and said bearing caps and operatively associated with said intake and exhaust valves, said joint surfaces lying in a common plane with said attachment surface and said one of the cover attachment surfaces.
7. In an internal combustion engine with a plurality of cylinders in a line, a cylinder head having a combustion chamber ceiling for each cylinder, said ceilings having a common centerline extending along the line of cylinders, intake valves and ports on o side of said centerline and exhaust valves and ports on the other side of said centerline, said cylinder head having a first window opposite said intake valves and a second window opposite said exhaust valves for access to said valves, a ceiling wall in said cylinder head between said first and second windows, and spark plug housings extending from said ceiling wall to substantially the centerline of each said combustion chamber ceiling for receiving a spark plug.
8. 8. An engine according to claim 12, wherein said first window has an attachment surface for receiving a cover which surface lies in a common plane with an attachment surface for an intake manifold of the engine.
9. 9 An internal combustion engine comprising: a cylinder head having a plurality of combustion chambers having a common centerline, intake and exhaust ports communicating with each of said combustion chambers on opposite sides of the centerline, intake and exhaust valves for opening and closing said intake and exhaust ports respectively, a valve mechanism chamber defined above said combustion chambers, and a valve operating mechanism housed in said valve mechanism chamber on both sides of the combustion chamber centerline for actuating said intake and exhaust valves, said valve mechanism chamber having a window to provide access therethrough to said valve operating mechanism; a head cover removably attached to said cylinder head in closing relation to said window; and an intake manifold attached to said cylinder head in communication with said intake ports; said cylinder head having attachment surfaces which lie in a common plane and to which said head cover and said intake manifold are attached, respectively.
10. 10. An internal combustion engine according to claim 9, including a cylinder block comprising a pair of cylinder arrays interconnected in a V shape, a said cylinder head being mounted on each of said cylinder arrays, said intake manifold being positioned between said cylinder arrays and connected to the cylinder heads on the respective cylinder arrays, said attachment surfaces of the two cylinder heads lying in a common plane.
11. 11. An internal combustion engine according to claim 9 or 10 wherein the or each said cylinder head includes a plurality of bearing base integral therewith and a plurality of bearing caps joined respectivel thereto through respective joint surfaces of the bearing bases, said valve operating mechanism having a cam shaft rotatably supported between said bearing bases and said bearing caps and operatively associated with said intake and exhaust valves, said joint surfaces lying flush with said attachment surfaces.
12. 12. An internal combustion engine according to any of claims 9 to 11, wherein the or each said cylinder head has a pair of said windows with a ceiling wall positioned between said pair of windows.

    13-An internal combustion engine according to claim 12, wherein a spark plug housing extends from said ceiling wall to each said combustion chamber for receiving a spark plug in substantially the center of said combustion chamber.