The technology herein relates generally to multiple-cylinder internal combustion engines and more particularly to hydraulically-actuated valve train assemblies in such engines.
The core of a vehicle's internal combustion engine is its cylinders. Combustion of gases and other combustion materials occurs within the cylinders and effectuates the movement of pistons whose power is transferred to the vehicle's driveshaft. The cylinders each include multiple valves that allow the various combustion products and exhaust into and out of the combustion chamber. The proper operation of these valves is crucial to provide the appropriate mix of combustion products at the appropriate times in the combustion chambers in order to produce optimal power from the engine.
Historically, the cylinders were completely encased in an engine block. The engine block was a machined casting that included not only the cylinders and their components but also coolant passages and other necessary engine parts. The engine block was usually made of cast iron and was designed to be strong and to also provide a housing that prevented the leakage of products into or out of the combustion chambers. Because of the importance of avoiding leaks into and out of the combustion chambers, and because of the need for a strong casing, the engine block was manufactured as a single complex unit.
More recently, however, advancements in manufacturing have allowed for the use of a cylinder block with cylinders capped by a separate cylinder head. The cylinder head is mounted onto the cylinder block and often includes a portion of the combustion chamber for each cylinder. The cylinder head may also include openings to allow the combustion products into the combustion chambers. Because the cylinders in a vehicle engine are often arranged adjacent each other, the cylinder head usually consists of a single plate of metal that includes the various combustion chamber components and openings for multiple cylinders in the engine. The cylinder head is often made of aluminum strengthened by nickel.
The openings in the cylinder head that allow the combustion products into the combustion chambers and exhaust out of the chambers are regulated by intake and exhaust valves. Operation of the intake and exhaust valves is facilitated by an electro-mechanical system referred to as a valve train. A valve train generally includes the valves themselves and also various hydraulically-actuated devices for opening and closing the valves such as rocker arms, pushrods, lifters and camshafts. In a non-integrated valve train, for example, the hydraulic devices are electronically controlled. In many implementations, parts of the electronically-controlled hydraulic device are housed in a single “brick” structure. The brick structure includes many of the elements making up the electronically-controlled hydraulic device for the variable operation of the intake and exhaust valves, as well as all the ducts of the hydraulic system associated with that device. The brick often includes an aluminum housing that is secured onto the top of the cylinder head.
A cover may be used in order to enclose and protect the brick and cylinder head. The cover also prevents the leakage of oil from the brick and cylinder head to the exterior engine compartment. Historically, the cover's functions were primarily passive, with no active role being played by the cover. The cover may be made of aluminum or plastic.
The manufacturing requirements of producing and assembling a separate cylinder head, brick and cover result in a complex, expensive process that requires fitting and sealing together multiple parts. To avoid oil leakage, a tight seal is required between the multiple parts. Additionally, the cylinder head, brick and cover stack use a significant amount of the engine space available in a vehicle. Accordingly, there is a desire to reduce the complexities and size of the cylinder head, brick and cover stack.
In various example embodiments, the technology described herein provides an internal combustion engine with a cylinder head cover module. An internal combustion engine includes a cylinder block, a cylinder head and a cylinder head cover module attached to the cylinder head. The cylinder head cover module includes passageways and a plurality of receiving features for valve train components. A housing may be integrally formed with the cylinder head cover module to include passageways and/or one or more receiving features for valve train components. The cylinder head cover module may include components of a non-integrated valve train such as a valve control system and may be used in both inline and V-shaped engines.
In another embodiment, a cylinder head cover module is disclosed. The cover module includes a housing having passageways for hydraulically-actuated valves.
In an additional embodiment, a vehicle engine is disclosed with one or more cylinder blocks that each includes a plurality of cylinders. The vehicle engine also includes a cylinder head mounted onto each of the cylinder blocks. The cylinder head encloses the plurality of cylinders. A cylinder head cover module is also attached to each of the cylinder heads. The cylinder head cover module includes a housing for a plurality of hydraulically-actuated valves.
In yet another embodiment, a method of assembling an internal combustion engine for a vehicle is disclosed. In the method, a cylinder head is attached to a cylinder block, the cylinder block being coupled to a drive train. A cylinder head cover module is attached to the cylinder head, wherein the cylinder head cover module includes a housing for a plurality of hydraulically-actuated valves and is electronically coupled to a valve control system.
Further areas of applicability of the present disclosure will become apparent from the detailed description and claims provided hereinafter. It should be understood that the detailed description, including disclosed embodiments and drawings, are merely exemplary in nature intended for purposes of illustration only and are not intended to limit the scope of the invention, its application or use. Thus, variations that do not depart from the gist of the invention are intended to be within the scope of the invention.
To reduce the assembly and sealing complexities, and to more effectively use the cylinder head cover and available engine space, the brick and the cylinder head cover may be integrated together into a single unit, cylinder head cover module. The integrated module results in fewer valve train components to be assembled and sealed together and a smaller vertical profile.
Without integration, the brick generally includes one or more of the following components: solenoids, check valves, valve actuators, a hydraulic pump, pump actuator arm, pump actuator arm pivot, accumulation chamber, pump return spring, oil temperature sensor and a factory oil fill port. The integrated module, therefore, may include each of the identified brick components in addition to other components more generally associated with a cylinder head cover, for example. Various embodiments of the integrated module include passageways for the flow of fluids therein and receiving features configured to hold, orient, and/or lock a variety of valve train components. Additional valve train components that may be integrated into the cover module include an oil filter, oil fill housing, one or more cam position sensors, a head cover gasket, a low pressure oil reservoir gasket and service and installations screws.
In
As described above, the cover module 210 includes components normally associated with a brick. For example, in
The reduction in the number of parts required in the cylinder assembly results in cost savings and an overall reduction in complexity. Fewer components generally results in fewer assembly-related problems or errors made during assembly. A reduction in components generally results in a reduction in investment for machining costs. Additional cost savings are realized through the reduced need to modify the cylinder head.
The cover module 210 may be made using aluminum casting methods that result in low porosity. Semi-solid casting processes may be used that include the injection of solids and other methods to reduce the porosity of the cover module. Other casting methods that may be used include sand casting and permanent mold casting.
The space-saving benefits of the disclosed cover module allow the cover module to be used in V-shaped engines. V-shaped engines (for example, a V-6 or V-8 engine) include a V-shaped portion that significantly constrains the amount of vertical space available above the cylinder heads. For example,
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