This invention relates generally to internal combustion engines, and more particularly to engines using rotary valves.
Internal combustion engines are well known and are used in various applications. For example, internal combustion engines are used in automobiles, farm equipment, lawn mowers, and watercraft. Internal combustion engines also come in various sizes and configurations, such as two stroke or four stroke and ignition or compression.
Typically, internal combustion engines (
Accordingly, there remains a need for a valvetrain for an internal combustion engine with low friction, good reliability, and a small number of parts.
This need is addressed by the present invention, which provides a valvetrain incorporating a pair of rotating valve shafts with apertures therein that function to open and close intake and exhaust ports of an internal combustion engine.
According to one aspect of the invention, an engine includes: a block defining a cylinder bore; a crankshaft mounted for rotation in the block; a piston disposed in the cylinder bore; a connecting rod interconnecting the piston to the crankshaft; and a cylinder head coupled to the block and including: a combustion chamber aligned with the cylinder bore and having an intake opening and an exhaust opening communicating therewith; an intake port; an exhaust port; a rotatable inlet valve barrel disposed between the intake opening and the intake port and having a first diameter; and a rotatable exhaust valve barrel disposed between the exhaust opening and the exhaust port and having a second diameter different from the first diameter.
According to another aspect of the invention, the first diameter is greater than the second diameter;
According to another aspect of the invention, a ratio of the first diameter to the second diameter is about 4:1 to about 1:1.
According to another aspect of the invention, the inlet and exhaust valve barrels are interconnected with the crankshaft, so as to rotate at one-quarter of a rotational speed of the crankshaft
According to another aspect of the invention, the engine further includes: a crank pulley connected to the crankshaft; an idler pulley connected to the crankshaft by a first drive belt at a 2:1 drive ratio; a drive assembly including a pulley connected to each valve barrel; and a second drive belt connecting the drive assemblies to the idler pulley at a 2:1 drive ratio.
According to another aspect of the invention, the engine includes at least one axial bank of cylinders, each bank including an inlet valve shaft comprising multiple inlet valve barrels and an outlet valve shaft comprising multiple outlet valve barrels, each shaft coupled to a drive assembly including a pulley.
According to another aspect of the invention, the drive assembly includes a pulley and a coupler.
According to another aspect of the invention, a relative angular position of the pulley and the coupler is variable.
According to another aspect of the invention, a relative angular position of the pulley and the coupler is variable.
According to another aspect of the invention, the pulley is attached to the coupler with bolts passing through slots in the pulley and engaging the coupler.
According to another aspect of the invention, the pulley includes a scale showing the relative angular position of the pulley and the coupler.
According to another aspect of the invention, the drive assembly comprises an active adjustment mechanism operable to change the angular relationship of the valve shaft to the pulley.
The invention may be best understood by reference to the following description taken in conjunction with the accompanying drawing figures in which:
Referring to the drawings wherein identical reference numerals denote the same elements throughout the various views,
The illustrated example is an eight-cylinder engine 10 of vee configuration, commonly referred to as a “V-8”, with two banks of four cylinders set 90 degrees to each other. However, it will be understood that the principles of the present invention are applicable to any internal combustion engine, for example engines running various cycles such as Otto or Diesel cycles, or similar machine requiring valves to open and close fluid flow ports.
The engine includes a block 12 which serves as a structural support and mounting point for the other components of the engine 10. Generally cylindrical cylinder bores 14 are formed within the block 12. As noted above the cylinder bores 14 are arranged in two longitudinal cylinder banks 16 of four cylinder bores 14 each. A crankshaft 18 having offset crankpins 20 is mounted in the block 12 for rotation in suitable bearings. A piston 22 is disposed in each cylinder bore 14, and each piston 22 is connected to one of the crankpins 20 by a piston rod 24. The crankshaft 18, piston rods 24, and pistons 22 collectively define a rotating assembly 26. In operation, gas pressure in the cylinder bores 14 causes linear movement of the pistons 22, and the rotating assembly 26 is operable in a known manner to convert linear movement of the pistons to rotation of the crankshaft.
The engine includes one cylinder head assembly 28 attached to each cylinder bank 16. The cylinder head assembly 28 has a generally concave combustion chamber 30 formed therein corresponding to and aligned with each cylinder bore 14. Collectively, each cylinder bore 14 and the corresponding combustion chamber 30 defines a cylinder 32.
The cylinder head assembly 28 has a plurality of intake ports 34 formed therein; each intake port 34 extends from one of the combustion chambers 30 to an intake plane 36 at an exterior surface of the cylinder head assembly 28. As will be described in detail below, an intake valve barrel 38 is disposed across each intake port 34 and includes an intake aperture 40 passing therethrough. The intake port 34, intake valve barrel 38, and intake aperture 40 are arranged such that in a first angular orientation of the intake valve barrel 38, fluid flow is permitted between the intake plane 36 and the combustion chamber 30, and at a second angular orientation of the intake valve barrel 38, fluid flow is blocked between the intake plane 36 and the combustion chamber 30.
The cylinder head assembly 28 also includes a plurality of exhaust ports 42 formed therein; each exhaust port 42 extends from one of the combustion chambers 30 to an exhaust plane 44 at an exterior surface of the cylinder head assembly 28. As will be described in detail below, an exhaust valve barrel 46 is disposed across each exhaust port 42 and includes an exhaust aperture 48 passing therethrough. The exhaust port, exhaust valve barrel 46, and exhaust aperture 48 are arranged such that in a first angular orientation of the exhaust valve barrel 46, fluid flow is permitted between the exhaust plane 44 and the combustion chamber 30, and at a second angular orientation of the exhaust valve barrel 46, fluid flow is blocked between the exhaust plane 44 and the combustion chamber 30.
The engine 10 includes a fuel delivery system 50 which is operable to receive an incoming airflow, meter a hydrocarbon fuel such as gasoline into the airflow to generate a combustible intake mixture, and deliver the intake mixture to the cylinders 32.
The fuel delivery system 50 may be continuous flow or intermittent flow, and the fuel injection point may be at the individual cylinders 32 or at an upstream location. Optionally the fuel injection point may be within the cylinders 32, a configuration commonly referred to as “direct injection”, in which case the intake ports 34 deliver only air to the cylinders 32. Known types of fuel delivery systems include carburetors, mechanical fuel injection systems, and electronic fuel injection systems. The specific example illustrated is an electronic fuel injection system with one intake runner 52 connected to each intake port 34.
The engine 10 includes an ignition system comprising one or more spark plugs 54 mounted in each combustion chamber 30, to ignite the intake mixture. An appropriate ignition power source is provided, such as a conventional Kettering ignition system with a coil and distributor, or a direct ignition system with a trigger module and multiple coils. The ignition power source is connected to the spark plugs 54, for example with leads 56.
The lower section 58 is a block-like element which may be formed by casting or machining from billet. It includes an exterior surface 62 which incorporates the combustion chambers 30 (see
The upper section 60 is also a block-like element which may be formed by casting or machining from billet. It includes an exterior surface 76, and an opposed interior surface 78 which mates with the interior surface 64 of the lower section 58. The intake ports 34 described above are formed as part of the upper section 60. Adjacent the interior surface 78, the upper section 60 has a plurality of semi-cylindrical intake barrel recesses 69 formed therein, arranged in a longitudinal line (see
Provisions made be incorporated for liquid cooling all or part of the cylinder head 57. In the illustrated example, the upper section 60 includes a hollow interior chamber (not shown) disposed between the interior surface 78 and the exterior surface 76. A series of coolant inlet holes 77 (
The lower section 58 and upper section 60 receive an intake valve shaft 80A and an exhaust valve shaft 80B. The valve shafts 80A and 80B are generally similar in construction to each other, with the intake valve shaft 80 being slightly larger in scale. The construction of the intake valve shaft 80A will be described in detail, with the understanding that the details are applicable to both of the valve shafts 80A, 80B.
It is also noted that, while the illustrated example includes inlet and exhaust valve shafts 80A and 80B, it should be appreciated that the modular valve shaft construction described herein could also be applied to a single valve shaft having both intake and exhaust valve barrels, or to valve barrels having both intake and exhaust apertures therein.
Referring to
The lateral dimension of the intake aperture 90 (perpendicular to the axis 82), the diameter of the intake valve barrel 38, and the rotational speed of the intake valve shaft 80A relative to the crankshaft speed all effect the valve open time or “duration”, and these effects are inter-related. This is also true for the exhaust valve barrels 46. These variables may be manipulated in order to adapt the intake valve shaft 80A and/or exhaust valve shaft 80B to suit a particular application. For example, the intake valve barrels 38 could be a different diameter than the exhaust valve barrels 46. In one non-limiting example, the ratio of the diameter of the intake valve barrels 38 to the diameter of the exhaust valve barrels 46 could be about 1:1 to about 4:1.
The intake valve barrel 38 may be made from a rigid, wear-resistant material such as a metal alloy or ceramic. A wear coating such as ceramic or carbide may be applied to all or part of the intake valve barrel 38, particularly the peripheral surface 84, to improve its wear properties.
Optionally, longitudinal holes 92 or other openings may be formed in the intake valve barrel 38 extending between the forward and aft end faces 86, 88. These holes 92 may be used to reduce the mass of the intake valve barrel 38, for balancing purposes, and/or to provide a cooling air flow.
A cylindrical forward stub shaft 94 extends from the forward end face 86, and a cylindrical aft stub shaft 96 extends from the aft end face 88.
The stub shafts 94, 96 may include mating mechanical alignment features to transfer torque between two adjacent intake valve barrels 38 and to maintain a specific angular relationship therebetween. For example, the forward stub shaft 94 may include a ring of axial pins 98 (
Optionally, the valve stub shafts 94, 96 could be connected to each other using fasteners, a mechanical interlock, or a bonding method such as welding or structural adhesives. Also, alternatively, the valve shaft 80 could be manufactured as a single integral component instead of being built up from individual intake valve barrels 38.
As seen in
When assembled, the intake valve shaft 80A and exhaust valve shaft 80B are received in the bearing recesses 70 and barrel recesses 66, 72, and are clamped between the lower section 58 and the upper section 60, which may be coupled together using conventional fasteners (not shown). The intake and exhaust valve shafts 80A, 80B are then free to rotate within the cylinder head assembly 28.
As noted above, each intake barrel recess 66 communicates with an intake opening 68, and each exhaust barrel recess 72 communicates with an exhaust opening 74. Each of these openings incorporates a sealing assembly. A single sealing assembly at one of the intake openings 68 will be described in general with reference to
A seal slot 104 is formed around the periphery of the intake opening 68. A seal 106 is received in the seal slot 104 and operates to reduce or prevent leakage between the cylinder 32 and the intake valve barrel 38.
The seal 106 is shown in more detail in
The seal 106 may be made from a rigid, wear-resistant material such as a metal alloy or ceramic. A wear coating such as ceramic or carbide may be applied to all or part of the seal 106 to improve its wear properties.
A pair of seal springs 116 are disposed in the seal slot 104 underneath the seal 106. As shown in
As further seen in
The seal slot 104 described above may be machined directly into the lower section 58. However, optionally, as seen in
In the assembled engine, a drive assembly 128 (
The pulley 130 is configured to engage a drive belt, chain, or similar transmission element. In the illustrated example the pulley 130 has teeth 136 around its periphery and is configured to engage a conventional toothed drive belt.
The drive assembly 128 may be adjustable. More specifically, the relative angular position of the pulley and the mechanical alignment feature 134 may be variable. In the example shown in
As shown in
The operation of the engine 10 will be described with reference to
The apparatus described above has several advantages over the prior art. The rotary valve structure has significantly lower parts count and frictional losses as compared to a conventional poppet valvetrain. The rotary valve structure also has the potential to be much more reliable than a conventional valvetrain because it does not require reciprocating movement and does not rely on highly-stressed valve springs for operation at high engine speeds.
Furthermore, the sealing assembly described herein will provide effective sealing of the rotary valve apparatus while permitting low mechanical loads and long component life.
It will be understood that the present invention may be implemented as a complete engine, or that the cylinder head assemblies described herein may be retrofitted to an existing internal combustion engine, or that the rotary valve apparatus and/or the sealing assembly may be incorporated into a cylinder head design.
The foregoing has described a rotary valve apparatus, a seal apparatus for a rotary valve apparatus, and an engine with a rotary valve apparatus. All of the features disclosed in this specification (including any accompanying claims, abstract and drawings), and/or all of the steps of any method or process so disclosed, may be combined in any combination, except combinations where at least some of such features and/or steps are mutually exclusive.
Each feature disclosed in this specification (including any accompanying claims, abstract and drawings) may be replaced by alternative features serving the same, equivalent or similar purpose, unless expressly stated otherwise. Thus, unless expressly stated otherwise, each feature disclosed is one example only of a generic series of equivalent or similar features.
The invention is not restricted to the details of the foregoing embodiment(s). The invention extends any novel one, or any novel combination, of the features disclosed in this specification (including any accompanying claims, abstract and drawings), or to any novel one, or any novel combination, of the steps of any method or process so disclosed.