The present disclosure relates to marine engines, and more particularly to cooling jacket cores for forming cooling jackets in cast parts of marine engines, and to methods and assemblies for forming cooling jackets in cast parts of marine engines.
The Background and Summary are provided to introduce a selection of concepts that are further described below in the Detailed Description. The Background and Summary are not intended to identify key or essential features of the claimed subject matter, nor are they intended to be used as an aid in limiting the scope of the claimed subject matter.
The following U.S. Patents are hereby incorporated herein by reference, in entirety:
U.S. Pat. No. 6,478,073 discloses a composite core structure used for metal casting in order to form cavities of preselected sizes and shapes within the casting. The composite core has an insoluble support member that can be metallic, and a soluble portion disposed around at least a part of the support member. When the composite core is used in a casting process, such as a die casting process, the soluble portion is dissolved after the casting process is complete, and the insoluble portion is then removed from the cavity that was formed through the use of the composite core.
U.S. Pat. No. 8,820,389 discloses a method for the high pressure die casting of an engine block assembly having at least one cast-in-place cylinder bore in the engine block and a closed head deck surface, and the resultant engine block. The closed deck high pressure die cast engine block assembly will preferably have at least two cast-in-place cylinder bores in the engine block formed by using a composite core of salt core material supported by at least one cylinder bore to be cast in place. The cylinder bores have a lower outer surface preferably defining at least one surface area that interfaces with the engine block during casting such that the at least one cylinder is cast in place in the engine block. An engine block cooling jacket—as defined by the salt core portion of the composite core—will preferably provide an open passage between each cylinder bore such that cooling fluid may flow around an entire outer circumference of the upper outer surface of the cylinder bores. This provides better and more uniform cylinder wall cooling, reducing thermal hot spotting and bore wall distortion.
U.S. Pat. No. 8,402,930 discloses a cooling system for a marine engine with various cooling channels and passages which allow the rates of flow of its internal streams of water to be preselected so that heat can be advantageously removed at varying rates for different portions of the engine. In addition, the direction of flow of cooling water through the various passages assists in the removal of heat from different portions of the engine at different rates so that overheating can be avoided in certain areas, such as the exhaust manifold and cylinder head, while overcooling is avoided in other areas, such as the engine block.
U.S. Pat. Nos. 8,479,691; 8,763,566; and 8,783,217 disclose a cooling system for a marine engine with various cooling channels which allow the advantageous removal of heat at different rates from different portions of the engine. A split-flow of water is conducted through the cylinder head, in opposite directions, to individually cool the exhaust port and intake ports at different rates. This increases the velocity of coolant flow in the downward direction through the cylinder head to avoid the accumulation of air bubbles and the formation of air pockets that could otherwise cause hot spots within the cylinder head. A parallel coolant path is provided so that a certain quantity of water can bypass the engine block and avoid overcooling the cylinder walls.
U.S. Pat. No. 9,174,818 discloses a marine engine that includes a cylinder block having first and second banks of cylinders that are disposed along a longitudinal axis and extend transversely with respect to each other in a V-shape so as to define a valley there between. A catalyst receptacle is disposed at least partially in the valley and contains at least one catalyst that treats exhaust gas from the marine engine. A conduit conveys the exhaust gas from the marine engine to the catalyst receptacle. The conduit receives the exhaust gas from the first and second banks of cylinders and conveys the exhaust gas to the catalyst receptacle. The conduit reverses direction only once with respect to the longitudinal axis.
Methods, assemblies and apparatuses are for forming a cooling jacket in a cast part of a marine engine. A cooling jacket core has a longitudinally elongated and monolithic body having an elongated first portion that forms a first flow path for conveying cooling fluid through the cast part in a first direction and an elongated second portion that forms an opposite, second flow path for conveying cooling fluid, such as water, through the cast part in an opposite, second direction. The first and second portions are laterally spaced apart from each other. The body further comprises at least one bridge that integrally supports the first and second portions with respect to each other during casting. At least one plug is configured to fit in the cast part where the at least one bridge was located so as to at least partially separate the first and second flow paths from each other, while sealing the first and second flow paths from an opposite side of the cast part.
The drawings illustrate the best mode presently contemplated of practicing the concepts of the present disclosure. The same numbers are used throughout the drawings to reference like features and like components. In the drawings:
During research and experimentation, the present inventor has endeavored to invent improved assemblies, apparatuses and methods for forming cooling jackets in cast parts of marine engines. More particularly, the present inventor has identified certain problems associated with current assemblies, apparatuses and methods for forming cooling jackets in cast parts of marine engines. Even more particularly, as described in the above-incorporated U.S. Pat. Nos. 8,479,691; 8,763,566; and 8,783,217; known cast parts in outboard marine engines have cooling jackets (e.g. passageways or channels for conveying water or any other cooling fluid) that promote removal of heat at different rates from different portions of the engine. As explained in the above-incorporated patents, it is known to produce a split-flow of cooling fluid through a cast part of the engine, for example a cylinder head, in opposite directions, to individually cool the exhaust ports and intake ports at different rates. This has been found to advantageously limit accumulation of air bubbles and formation of air pockets which could otherwise cause hot spots within the cylinder head. Various other functional advantages also result from such an arrangement.
Referring to
Referring now to
Optionally, the cooling jacket core 20 further includes a plurality of supporting printouts 32, which in the illustrated example are located adjacent to (e.g. formed with or fixed to) the respective bridges 30 and are configured to support the cooling jacket core 20 with respect to the mold 15 prior to and during the casting process. The location and configuration of the bridges 30 and printouts 32 can vary from what is shown in the drawings. Optionally, the bridges 30 and printouts 32 are co-located and are longitudinally spaced apart along the cooling jacket core 20. Optionally, the bridges 30 and printouts 32 are interdigitated amongst the locations of cylinders on the internal combustion engine 17. Additional bridges 30 and/or printouts 32 can be included. Effectively, the bridges 30 act as “tie bars” so that the monolithic cooling jacket core 20 is strong enough to be handled and placed in the mold 15 without breaking and the printouts 32 act as supporting members for the monolithic cooling jacket core 20 once it is placed into the mold 15.
The illustrated cooling jacket core 20 also includes an elongated third portion 34, which forms a third flow path (see e.g., arrows 36) for cooling fluid to flow alongside an exhaust conduit that is integrally cast with the cylinder head 10 and configured to convey exhaust gas from the internal combustion engine 17. This type of integrally-formed exhaust conduit and cylinder head 10 is disclosed in the above-incorporated U.S. Pat. No. 9,174,818.
Thus, as shown by the arrows in
Referring to
To fully isolate the first and second flow paths 24, 28 from the opposite side of the cast part (here the lubricated side of the cylinder head), to further isolate the first and second flow paths 24, 28 from each other, and to allow for the above-described split-flows (with or without controlled short circuiting), a plug 40 (e.g., see
Optionally, the location wherein the bridges 30 were once located can be machined (e.g. drilled or milled, etc.) to form a larger and/or more precise passageway 31 (see
Referring to
The present inventor has further realized that in certain embodiments it can be desirable to intentionally permit some flow of cooling fluid from the first flow path 24 to the second flow path 28 via the passageway 31. That is, in some embodiments, it can be advantageous to permit a certain amount of cooling fluid to bypass (i.e., short circuit) downstream portions of the first flow path 24 and upstream portions of the second flow path 28 via the passageway 31. The inventor further realized that it is possible to purposefully machine the passageway 31 so that it does not form a complete seal with the body 43 (or alternately to select the configuration of the plug 40 so that it does not form a complete seal with the passageway 31), thus permitting a partial flow (i.e. a short circuit flow) of cooling fluid there through. The difference in size and/or shape of the passageway 31 and body 43 can be purposefully selected to as to attain a desired amount of “short circuit” fluid flow. Thus it is possible to tune of the cooling flow system by metering the short circuit cooling flow between the first and second flow paths 24, 28, using plugs that are sized (length and/or diameter) to match specific flow requirements. In examples where there are multiple passageways 31 and plugs 40, all or only some of the passageways 31 can be machined in this way so as to achieve desired leakage of cooling fluid at desired locations along the length of the first and second cooling paths 24, 28.
It will thus be seen that the present disclosure provides improved assemblies for forming a cast part of a marine engine and particularly for forming a cylinder head of the marine engine, such as for example the cylinder head 10 shown in
As described herein above, the cast part can be a cylinder head 10 of the marine engine, wherein the first flow path 24 is configured to convey cooling fluid alongside intake valves in the cylinder head 10, and wherein the second flow path 28 is configured to convey cooling fluid alongside exhaust valves in the cylinder head 10. In some examples, the cooling jacket core 20 can further comprise an elongated third portion 34 that forms a third flow path 36 for cooling fluid to flow alongside an exhaust conduit cast with the cylinder head 10 by the mold 15.
As described herein above, the present disclosure further provides methods of forming a cooling jacket in a cast part of a marine engine. The method can comprise (1) positioning a longitudinally elongated and monolithic cooling jacket core into a mold for forming the cast part of the marine engine, the cooling jacket core having a longitudinally elongated first portion that forms a first flow path for conveying cooling fluid through the cast part in a first direction, and a longitudinally elongated second portion that forms an opposite, second flow path for conveying cooling fluid through the cast part in an opposite, second direction, wherein the first and second portions are laterally spaced apart from each other, and wherein the cooling jacket core further comprises at least one bridge that integrally supports the first and second portions with respect to each other during casting; (2) casting a metal in the mold to form a cast part and thereafter breaking down and removing the cooling jacket core from the cast part to thereby open the first and second flow paths; and (3) or inserting at least one plug into the cast part where the at least one bridge was located so as to at least partially isolate the first and second flow paths from each other. The methods can further optionally comprise: (4) machining the at least one supporting printout to form a passageway, wherein the at least one plug is inserted into the passageway. The methods can further optionally comprise (5) machining the cast part so that when the plug is inserted where the at least one bridge was located, a gap occurs between the plug and the cast part, the gap being configured to allow a portion of the cooling fluid to pass by the plug from the first flow path to the second flow path. The methods can further optionally comprise (6) machining the cast part so that the gap has a size that is selected to achieve a desired amount of leakage of cooling fluid past.
Thus apparatuses, assemblies and methods of the present disclosure advantageously enable formation of a split-flow cylinder head cooling jacket using plugs to prevent short circuit of cooling fluid, and preventing the cooling fluid from entering the engine and mixing with oil therein. The one piece cooling jacket core facilitates improved casting manufacturability over the prior art, as described herein above.
Through research and experimentation, the present inventors have determined that the bridge in the sand core that connects the multiple flow paths forms a passage, which if not sealed (or partially sealed), will have a large short circuit of fluid flow from one flow path to the other. This passage formed by the bridge must be sealed or partially sealed (with controlled leak rate) with the fluid dam (i.e. plug). The bridge does not need to have a connected printout connecting the cooling jacket to the oil cavity (or outside of the part), but in certain examples can be added since it helps locate and support the cooling jacket cores. Without the printout, the way a dam (i.e. plug) could be inserted would be by machining an access hole. With a cast printout hole, it is possible that a dam could be inserted, seal (or partially seal) the cast surfaces between the flow paths and seal the cooling jacket (both flow paths) from the oil cavity (or outside of the part).
Machining the access hole, or further opening the access hole formed by the printout, provides precision smooth surfaces for better sealing with the fluid dam (or a more precisely controlled leak). It also conveniently provides a method to secure the fluid dam (with the threaded portion of the plug) and provides a seal to the oil cavity (or outside of the part). The sealing to the oil cavity (or outside of the part) could be made with methods other than the depicted O-ring style plug (shown in
This written description uses examples to disclose embodiments of the invention, including the best mode, and also to enable any person skilled in the art to make and use the same. The patentable scope of the invention is defined by the claims and may include other examples that occur to those skilled in the art. Such other examples are intended to be within the scope of the claims if they have structural elements that do not differ from the literal language of the claims, or if they include equivalent structural elements with insubstantial differences from the literal language of the claims.
The present application is a divisional of U.S. patent application Ser. No. 15/440,376, filed Feb. 23, 2017, now U.S. Pat. No. 10,464,125. The above-noted application is incorporated herein by reference, in entirety.
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Number | Date | Country | |
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Parent | 15440376 | Feb 2017 | US |
Child | 16587868 | US |