SLEEVE VALVE OIL SEAL
Leakage of a liquid (e.g. a coolant and/or a lubricant) past a sleeve valve to a port in communication with a combustion chamber of an internal combustion engine can be prevented by use of a substantially ring-shaped seal, which can be carried on the sleeve valve or disposed on a stationary part of the internal combustion engine.
The current application is claims priority under 35 U.S.C. §119(e) to U.S. provisional application No. 61/837,101 filed Jun. 19, 2013, the disclosure of which is incorporated herein by reference.
TECHNICAL FIELDThe subject matter described herein relates to engines that include one or more ports controlled by the motion of one or more sleeve valves.
BACKGROUNDA sleeve valve is a type of valve usable in internal combustion engines, including but not limited to opposed piston engines in which two pistons share a single cylinder, and also in engines in which each piston reciprocates in its own cylinder. Such a valve typically forms all or a portion of the cylinder wall defining a combustion chamber inside the cylinder. In some variations, one or more sleeve valves can reciprocate back and forth substantially in parallel to an axis upon which one or more pistons reciprocates to open and close intake and/or exhaust ports at appropriate times to introduce air or an air-fuel mixture into the combustion chamber and/or to exhaust combustion products from the chamber. In other variations, one or more sleeve valves can rotate about and/or translate along the axis of the piston or pistons to open and close one or both of the intake and exhaust ports. Due to the potentially large circumferential port area that can be controlled by a sleeve valve, such valves can provide a relatively large cross sectional area for fluid flow in the open position.
Sleeve valves, in common with other parts of an internal combustion engine, especially those in the region of the combustion chamber, require cooling. This can be achieved by provision of oil to the sleeve valve, which enables heat arising in the sleeve valve as a result of the combustion process, to be transferred away from the sleeve valve to other parts of the engine. If the oil is delivered to the exterior surface of the sleeve valve, it can transfer heat out of the sleeve valve to other, stationary parts of the engine. The oil can also act as a lubricant between the exterior surface of the sleeve valve and the engine block. However, leakage of the oil into the ports is a concern.
SUMMARYThe current subject matter relates generally to seals for preventing leakage of a liquid (e.g. a coolant and/or a lubricant) past a sleeve valve to a port in communication with a combustion chamber of an internal combustion engine.
In one aspect, a sleeve valve assembly includes a sleeve valve and a substantially ring-shaped seal. The sleeve valve has a valve body configured to at least partially encircle one or more pistons that moves in a reciprocating manner on operation of an internal combustion engine. The sleeve valve and the one or more pistons at least partially define a combustion chamber of the internal combustion engine, and the sleeve valve is configured to move between open and closed positions to control fluid flow through a port that opens to the combustion chamber. The substantially ring-shaped seal is configured to resist leakage of a liquid (e.g. coolant and/or lubricant) past the valve body to the port. In optional variations, the substantially ring-shaped seal includes at least one of a) a ring carried in a groove recessed into the valve body, and b) first and second rings disposed around the valve body and biased apart from each other. In option b), the first and second rings are disposed on a stationary part of the internal combustion engine such that the valve body moves relative to the first and second rings.
In an interrelated aspect, a method includes moving a sleeve valve between open and closed positions to control fluid flow through a port of an internal combustion and resisting leakage of a liquid comprising coolant and/or lubricant past a valve body of the sleeve valve to the port. The resisting is performed at least in part by a substantially ring-shaped seal that includes either or both of a) a ring carried in a groove recessed into the valve body, and b) first and second rings disposed around the valve body and biased apart from each other. In option b), the first and second rings are disposed on a stationary part of the internal combustion engine such that the valve body moves relative to the first and second rings.
In other interrelated aspects an internal combustion engine includes the sleeve valve assembly discussed above with any of the optional variations discussed below. Alternatively or in addition, such an internal combustion engine can be arranged to operate consistent with the method discussed above optionally including any variations discussed below. A vehicle can include such an internal combustion engine.
In optional variations, one or more additional features, including but not limited to those discussed in the next few paragraphs, can be included in implementations of the current subject matter. The ring and/or each of the first and second rings can be formed of a metal. One or more compression rings can be included in a sleeve valve assembly or otherwise be included for resisting leakage of gases in the combustion chamber and/or the port past the sleeve valve. The sleeve valve can reciprocate between the open and closed positions along a common axis with a piston of the one or more pistons. The valve body can include a cylindrical body having a length and a flange spaced apart radially outwards from the cylindrical body and extending along at least a part of the length, and the cylindrical body and the flange can define a cavity therebetween in which the liquid can circulate. The seal can optionally be carried by the flange.
Consistent with option a), the substantially ring-shaped seal can include the ring carried in the groove recessed into the valve body, and the seal can exert a radial force outward against the stationary part of the internal combustion engine. The seal can exert a first force against a first side of the groove and a second force against a second side of the groove. The seal can include a biasing structure that exerts the first and second forces. The seal can include both the ring and an additional ring, and the ring and additional ring can be substantially flat, split rings. The ring and the additional ring can be separated by the biasing structure. The groove can be configured such that the material thickness of the valve body is substantially the same at the groove as through a remainder of the valve body. The seal can remain substantially stationary relative to the valve body as the sleeve valve moves.
Consistent with option b), the substantially ring-shaped seal can include the first and second rings disposed on the stationary part and around the valve body, and the first and second rings can have respective ring tensions to exert a radial force inward against the valve body. The first ring and the second ring can be separated by a biasing structure which biases them apart. The first and second rings can include flat, split rings having respective ring tensions arising from one or more of their shape; size; curvature and material. The stationary part can include a groove in which the seal is installed, and the first ring can be biased against a first side of the groove while the second ring is biased against a second, opposite side of the groove. The stationary part can further include an oil drain through which oil in the groove drains. The sleeve valve body can include a honed surface against which the first and second rings exert the radial force.
The details of one or more variations of the subject matter described herein are set forth in the accompanying drawings and the description below. Other features and advantages of the subject matter described herein will be apparent from the description and drawings, and from the claims. The claims that follow this disclosure are intended to define the scope of the protected subject matter.
The accompanying drawings, which are incorporated in and constitute a part of this specification, show certain aspects of the subject matter disclosed herein and, together with the description, help explain some of the principles associated with the disclosed implementations. It should be noted that the orientation of various features or structures illustrated in the drawings are not meant to be limiting. For example, in an engine with the axis or axes of reciprocation of the pistons lying close to horizontal, the structures in
When practical, similar reference numbers denote similar structures, features, or elements.
DETAILED DESCRIPTIONImplementations of the current subject matter can, among other possible advantages, provide systems, methods, techniques, etc. to achieve a lubricant seal between a sleeve valve and an engine block or other part of an internal combustion engine that remains stationary during operation of the sleeve valve. In particular, the efficacy of the lubricant seal is improved by provision of an improved sealing apparatus and/or a sealing apparatus that moves with the sleeve valve.
The internal combustion engine 100 includes a pair of opposing pistons that includes a first piston 102 and a second piston 104. The first piston 102 is operably coupled to a first crankshaft 106 by a first connecting rod 110 and the second piston 104 is operably coupled to a second crankshaft 112 by a second connecting rod 114. As shown in
The first cam lobe 232 can be carried on a suitable first camshaft that can be operably coupled to a corresponding crankshaft by one or more gears. On the exhaust side, for example, rotation of the first cam lobe 232 can drive the proximal end portion of the first rocker 230 in one direction (e.g., from left to right), which in turn causes a distal end portion of the first rocker 230 to drive the exhaust sleeve valve 116 in an opposite direction (e.g., from right to left) to thereby open the exhaust port 122. A similar action can occur on the intake side, where rotation of the second cam lobe 240 can drive the proximal end portion of the second rocker 236 in one direction (e.g., from right to left), which in turn causes a distal end portion of the second rocker 236 to drive the intake sleeve valve 120 in an opposite direction (e.g., from left to right) to thereby open the inlet port 124.
Each of the exhaust sleeve valve 116 and the intake sleeve valve 120 is urged into a closed position by a corresponding biasing member, such as for example a first large coil spring 244 and a second large coil spring 246, each of which is compressed between a flange on the bottom portion of the corresponding sleeve valve and an opposing surface fixed to the corresponding crankcase. The first biasing member 244 urges the exhaust sleeve valve 116 from left to right to close the exhaust port 122 as controlled by the first cam lobe 232, and the second biasing member 246 urges the intake sleeve valve 120 from right to left to close the intake port 124 as controlled by the second cam lobe 240.
Due to their proximity to the combustion chamber, the sleeve valves can typically become extremely hot during operation of the engine. Without provision for cooling the sleeve valves, they could undergo damage and distortion. To provide cooling, a coolant, cooling fluid, etc. (such as, for example, oil or the like), can be circulated to contact the sleeve valve. A cooling fluid path within the engine block, part of a sleeve valve assembly, etc. can enable oil to circulate either within or around the sleeve valve, depending on the design of the sleeve valve. Some examples of such cooling are described in co-owned U.S. patent application publication no. US2010/0212622A1, the contents of which are herein incorporated by reference. Regardless of the design of the sleeve valve, it can be desirable for some cooling fluid to flow around the outer surface of the sleeve valve, so that it can act additionally as a lubricant between the outer surface of the sleeve valve and the stationary part of the engine against which it slides. The stationary part can be a part of the engine block, a part of a fluid path-defining piece, or some other engine structure that does not move with the sleeve valve or piston. A trade-off can exist between providing sufficient lubrication and avoiding leakage of cooling fluid past the sleeve valve into the port which the sleeve valve opens and closes. Many prior art piston engines used rotating sleeve valves, which were known to have high oil consumption due to cooling fluid being carried past the sleeve valve to the port by the rotational movement. A reciprocating sleeve valve, has many advantages, such as a better ability to control combustion timing, as described in co-owned U.S. Pat. No. 7,559,298, the disclosure of which is incorporated by reference herein. However, the movement of a reciprocating sleeve valve can potentially cause some amount of the cooling fluid to be carried past the sleeve valve to the port.
To address these and potentially other issues with currently available solutions, one or more implementations of the current subject matter provide methods, systems, articles of manufacture, and the like that may improve the sealing ability of sleeve valves in internal combustion engines. The following exemplary embodiments provide sealing mechanisms for controlling leakage of the cooling fluid into the inlet or exhaust port which is opened and closed by the sleeve valve.
Since a reciprocating sleeve valve does not need to include an opening to align with the intake or exhaust ports, a “sliding seal” i.e. a seal that is able to maintain substantially continuous contact with the sliding metal surface of the sleeve valve, can be used, hence enabling a substantially uninterrupted seal. Some examples of such seals consistent with the current subject matter will be described in the following.
The sleeve valve body 302 reciprocates to open and close the port 306, in a direction as indicated by an arrow 310. As noted above in reference to
The proximal end 308 of the sleeve valve can include a flange or lip 322 spaced radially outward from the sleeve valve body 302. A cavity 324 can be formed in the space between the exterior surface 314 of the sleeve valve body 302 in the region of its proximal end 308 and the flange 322. The flange 322 can extend a sufficient distance along the length of the sleeve valve body 302 to cover the port 306 and to enable formation of a seal against the stationary part 320. The flange 322 forms the exterior surface of the sleeve valve in this region of the sleeve valve and partially surrounds the sleeve valve body 302. This part of a sleeve valve can be referred to as an “umbrella” structure. The end of the flange 322 distal from the proximal end 308 of the sleeve valve body 302 can include a groove 325 formed in the exterior surface of the flange 322. The depth of the groove 325 can be such that it can accommodate a seal 326, details of which are described below. The groove 325 can be formed in an end region 327 of the flange 322, although it is not essential for the groove to be at the end of the flange 322. The end region 327 can, in some implementations of the current subject matter, be formed as a lip protruding towards the inner surface 312 of the sleeve valve body 302, such that the material thickness of the flange 322 in that region can be substantially the same as the thickness elsewhere, while forming the groove 325. There is nevertheless a radial space between the groove 325 and the guide 318.
The stationary part 320 has features enabling cooling fluid to be circulated through or in contact with the sleeve valve body 302. This can be achieved by a variety of designs, for example an oil-path defining piece for circulating oil as a cooling fluid such as is described in U.S. Pat. No. 7,559,298. Schematically, the oil path flows form a cooling fluid inlet port 328, along the length of the sleeve valve body 302 in a direction towards the proximal end 308 and into the cavity 324. Having circulated in the cavity 324, as shown by the dotted path, the oil can exit in a region beyond the groove 325 (having been able to flow through the above-mentioned radial space) and back out into the cylinder block 320 through a cooling fluid outlet port 330. Absent some sort of sealing structure or mechanism, such as for example the seal 326, it would be possible for oil to leak past the flange 322 and into the port 306.
The seal 326 is ring-shaped and may be formed from metal or elastomer and can be sized to fit within the groove 325 and to protrude out of the groove 325 to form a seal and running surface against a sealing surface 332 of the stationary part 320. The seal 326 can be dimensioned and have a ring tension such that it provides a good contact against the outer contact (sealing) surface 332 to minimize oil leakage, while also maintaining sufficient tension against the flange 322 with an inner contact surface such that during reciprocating strokes, a small amount of oil can flow onto the outer contact surface 332 to ensure sufficient lubrication during the stroke. In general, oil will be in the area between the seal 326 and the cooling fluid outlet port 330 while the valve is in its closed position (e.g. with the proximal end 308 in contact with the valve seat 304). The sealing surface 332 upon which the seal slides is therefore coated with oil when the sleeve valve is in this position. In some implementations of the current subject matter, this coating of oil can be sufficient to insure proper lubrication of the sliding surface. This lubricating oil and any oil which is scraped by the ring can be drained by provision of a suitable drain in the sleeve valve body 602. The configuration of such a drain would need to ensure that cooling oil circulating through the cavity 624 as previously described was not picked up into the seal. For example, a vertical configuration (i.e. vertically in
A metal ring seal 326 can be designed to balance the amount of oil allowed to pass and the life of the sliding surfaces. Typically, a metal ring seals against the outside sealing surface 332 and one of the sides of the groove 325, but not simultaneously against both the sealing surface 332 and the base of the groove 325. For this reason, a metal oil control ring can employ tension to push the outer contact surface of the ring out against the sealing surface 332. A spring arrangement or some other configuration that provides an expansive force in a direction parallel to the arrow 310 to push the seal 326 against the sides of the groove 325 can also or alternatively be included. A conventional piston ring used to contain lubricating fluid around a piston from entering the combustion chamber generally relies on gas pressure to push the piston ring out against the cylinder walls and down against the side of a groove to make the seal. In the seal configurations described here, a metal seal 326 can include two or more rings. In one example, a three piece ring can include two thin rings and a spring between the two thin rings to push the two thin rings outwardly against the sides of the groove 325. Some examples of use of such a seal will be discussed in more detail below. A seal 326 constructed of an elastomer material can seal against the inner and the outer surfaces because of its ability to change shape under compression, which can accommodate changes in distance between the two sliding surfaces that can result from manufacturing tolerances, temperature differences during operation, etc.
While the seal 326 moves with the sleeve valve, in many cases there will be some local relative movement between the seal 326 and the other parts of the sleeve valve during reciprocating strokes. For example, some degree of movement of the seal 326 within the groove 325 is possible within the scope of the current subject matter. In other words, the seal 326 remains substantially stationary relative to the sleeve valve in general and specifically relative to the flange 322.
In a second sleeve valve system 400 shown in
A ring-shaped seal made of one or more of a variety of materials, including but not limited to metal (e.g. steel or the like), an elastomer, etc., can be used as the seal 326, 326A, 326B. The ring-shaped seal may be generally ring-shaped but have a gap in a portion of the ring, to facilitate the correct tension and consequent pre-load in the ring relative to the sleeve valve. The ring-shaped seal may be flat to provide optimal contact with the sides of the grooves 325, 325A or 325B. An additional spring may be provided to enable the ring to provide an appropriate level of force to operate as a seal and to allow lubrication as described above. The invention is not limited to a single ring but may include arrangements having multiple rings or other configurations such as spiral rings having, for example, 2-5 or more turns.
A system consistent with implementations of the current subject matter can include a sleeve valve including a valve body arranged to at least partially encircle at least one piston arranged to move in a reciprocating manner. The sleeve valve and the at least one piston at least partially define a combustion chamber of an internal combustion engine. The sleeve valve is moveable between an open position and a closed position to control fluid flow through a port of the internal combustion engine. The system can also include a substantially ring-shaped seal carried in a groove on the sleeve valve in a configuration. During operation of an internal combustion engine that includes the sleeve valve, the substantially ring-shaped seal remains substantially stationary relative to the sleeve valve to resist leakage of coolant from the valve body to the port.
The sleeve valve body 602 reciprocates to open and close the port 306, in a similar manner as discussed above with respect to the sleeve valve body 302 of
The sleeve valve body 602 can be formed as a hollow cylinder having an inside surface 612 and an exterior surface 614 and a length extending in the direction of the arrow 610. A piston and a combustion chamber (not shown) are disposed in the interior 616 of the hollow sleeve valve body 602. In other words, the sleeve valve body 602 at least partially encircles at least one piston and a combustion volume that expands and contracts with motion of the at least one piston. A portion of the exterior surface 614 of the sleeve valve 602 distal from the valve seat 304 can run against a cylindrical guide 618 disposed between this distal portion of the sleeve valve and a stationary part 620, which can be the engine block or other engine structure relative to which the sleeve valve body 602 moves.
The proximal end 608 of the sleeve valve can include a flange or lip 622 spaced radially outward from the sleeve valve body 602. A cavity 624 can be formed in the space between the exterior surface 614 of the sleeve valve body 602 in the region of its proximal end 608 and the flange 622. The flange 622 can extend a sufficient distance along the length of the sleeve valve body 602 to cover the port 306 and to enable formation of a seal against the stationary part 620. The flange 622 forms the exterior surface of the sleeve valve in this region of the sleeve valve and partially surrounds the sleeve valve body 602. This part of a sleeve valve can be referred to as an “umbrella” structure. This umbrella structure can have an exterior surface finish that has been engineered to provide a sealing surface for sealing against a stationary seal 626 mounted in the stationary part 620. Typically, the surface finished in this way is hard enough to resist the abrasion from the seal 626 and has small surface features that can maintain a small amount of coolant, such as oil, which lubricates the interface between the seal 626 and the surface of the flange 622 as the sleeve valve body 602 moves. Steel and iron having a surface topology provided by a honing process are examples of a suitable surface finish, but others could be contemplated by those skilled in the art. In one example, the honing can include a pattern of shallow scratches that are narrow compared to the dimensions of the sleeve valve body 602 at that are aligned at some angle (e.g. ±approximately 45°, ±approximately 30°, ±approximately 60°) relative to the axis along which the sleeve valve reciprocates. During operation, such scratches can fill with oil to thereby create a sealing effect which can minimize transmission of oil past the sleeve valve body 602 to the port 304 and which is also able to form a substantially gas-tight seal. In another example, the honing can include a pattern of surface features such as divots, depressions, channels, or the like. Surface topologies such as those described, as well as others that are also within the scope of the current subject matter, can be formed by processes such as grinding, burnishing, bombardment with beads or other materials, sanding, laser treatment, etching, or other that might be contemplated by those skilled in the art.
The seal 626 is mounted in a stationary part 620 such as an engine block, so it remains substantially stationary while the sleeve valve assembly 600 moves. In other words, the position of the seal 626 relative to the moving sleeve valve body 602 varies as the sleeve valve moves. For example, in
The seal 626 can be an elastomeric seal, as described in co-owned US publication no. 2012/0085309A1. However, durability may be improved if at least a part of the seal 626 comprises a metal.
One possible design for the seal 626 is a ring arrangement as shown in
The first and second rings 650, 652 can be separated by a biasing structure 654, which may be a spring, and conveniently is a spring washer or other similar structure. The ring arrangement is fitted in a groove 656 in the stationary part 620. The groove 656 has a first side 658, corresponding to the proximal end of the sleeve valve body 602 and a second side 660, corresponding to the distal end of the sleeve valve body 602. Thus the first and second sides 658, 660 are substantially flat and substantially parallel to the first and second rings 650, 652 when the ring arrangement is installed in the groove 656. The biasing structure 654 tends to hold the first ring 650 against the first side 658 and the second ring 652 against the second side 660. Thus the first ring 650 exerts a first lateral force on the first side 658 and the second ring 652 exerts a second lateral force on the second side 660. The arrangement of the biasing structure 654 between the two rings 650, 652 thus urges the rings against the sides of the groove 656 and thereby improves the effect of the seal 626 by improving the stability of the rings 650, 652 when subject to forces arising from their contact with the moving sleeve valve 600.
As the sleeve valve 600 moves from the open position of
In examples consistent with the present subject matter where the seal is held in a stationary part of the engine, the hottest region of the sleeve valve body 602 i.e. the proximal end 608 which closes the port 306, will be closer to the seal at some times during an engine cycle than it would be if the seal remained a fixed distance from the proximal end 608 as in examples such as those of
The arrangement of a seal 626 in a groove 656 as shown in
It may be desirable to use a further ring 950 in a naturally aspirated engine. It may also be useful to use one or two further rings such as the further ring 950 in a turbocharged engine, in order to further improve resistance to gas leakage. This approach can be desirable in a heavily turbocharged engine where the exhaust system pressure is very high relative to the engine internal pressure.
In either of the arrangement of
The arrangements of
It will be understood by those skilled in the art that features of the current subject matter could equally well be applied to a sleeve valve operating to open and/or close one or more ports in an engine in which each piston moves in its own cylinder. Furthermore, it is not essential for the sleeve valve to have an “umbrella” portion, but rather embodiments of the invention are also applicable to the main body of a sleeve valve not having a flange.
In the descriptions above and in the claims, phrases such as “at least one of” or “one or more of” may occur followed by a conjunctive list of elements or features. The term “and/or” may also occur in a list of two or more elements or features. Unless otherwise implicitly or explicitly contradicted by the context in which it used, such a phrase is intended to mean any of the listed elements or features individually or any of the recited elements or features in combination with any of the other recited elements or features. For example, the phrases “at least one of A and B;” “one or more of A and B;” and “A and/or B” are each intended to mean “A alone, B alone, or A and B together.” A similar interpretation is also intended for lists including three or more items. For example, the phrases “at least one of A, B, and C;” “one or more of A, B, and C;” and “A, B, and/or C” are each intended to mean “A alone, B alone, C alone, A and B together, A and C together, B and C together, or A and B and C together.” Use of the term “based on,” above and in the claims is intended to mean, “based at least in part on,” such that an unrecited feature or element is also permissible.
The subject matter described herein can be embodied in systems, apparatus, methods, and/or articles depending on the desired configuration. The implementations set forth in the foregoing description do not represent all implementations consistent with the subject matter described herein. Instead, they are merely some examples consistent with aspects related to the described subject matter. Although a few variations have been described in detail above, other modifications or additions are possible. In particular, further features and/or variations can be provided in addition to those set forth herein. For example, the implementations described above can be directed to various combinations and subcombinations of the disclosed features and/or combinations and subcombinations of several further features disclosed above. In addition, the logic flows depicted in the accompanying figures and/or described herein do not necessarily require the particular order shown, or sequential order, to achieve desirable results. Other implementations may be within the scope of the following claims.
Claims
1. A sleeve valve assembly comprising:
- a sleeve valve having a valve body configured to at least partially encircle one or more pistons that moves in a reciprocating manner on operation of an internal combustion engine, the sleeve valve and the one or more pistons at least partially defining a combustion chamber of the internal combustion engine, the sleeve valve being configured to move between open and closed positions to control fluid flow through a port that opens to the combustion chamber; and
- a substantially ring-shaped seal configured to resist leakage of a liquid comprising coolant and/or lubricant past the valve body to the port, the substantially ring-shaped seal comprising at least one of:
- a) a ring carried in a groove recessed into the valve body, and
- b) first and second rings disposed around the valve body and biased apart from each other, the first and second rings being disposed on a stationary part of the internal combustion engine such that the valve body moves relative to the first and second rings.
2. The sleeve valve assembly of claim 1, wherein the ring and/or each of the first and second rings is formed of a metal.
3. The sleeve valve assembly of claim 1, further comprising one or more compression rings for resisting leakage of gases in the combustion chamber and/or the port past the sleeve valve.
4. The sleeve valve assembly of claim 1, wherein the sleeve valve reciprocates between the open and closed positions along a common axis with a piston of the one or more pistons.
5. The sleeve valve assembly of claim 1, wherein the substantially ring-shaped seal comprises the ring carried in the groove recessed into the valve body, and wherein the seal exerts a radial force outward against the stationary part of the internal combustion engine.
6. The sleeve valve assembly of claim 5, wherein the seal exerts a first force against a first side of the groove and a second force against a second side of the groove.
7. The sleeve valve assembly of claim 6, wherein the seal comprises a biasing structure that exerts the first and second forces.
8. The sleeve valve assembly of claim 5, wherein the seal comprises both the ring and an additional ring, and the ring and additional ring are substantially flat, split rings.
9. The sleeve valve assembly of claim 8, wherein the ring and the additional ring are separated by the biasing structure.
10. The sleeve valve assembly of claim 5, wherein the groove is configured such that the material thickness of the valve body is substantially the same at the groove as through a remainder of the valve body.
11. The sleeve valve assembly of claim 5, wherein the seal remains substantially stationary relative to the valve body as the sleeve valve moves.
12. The sleeve valve assembly of claim 1, wherein the substantially ring-shaped seal comprises the first and second rings disposed on the stationary part and around the valve body, and wherein the first and second rings have respective ring tensions to exert a radial force inward against the valve body.
13. The sleeve valve assembly of claim 12, wherein the first ring and the second ring are separated by a biasing structure which biases them apart.
14. The sleeve valve assembly of claim 12, wherein the first and second rings comprise flat, split rings having respective ring tensions arising from one or more of their shape;
- size; curvature and material.
15. The sleeve valve assembly of claim 12, wherein the stationary part comprises a groove in which the seal is installed and wherein the first ring is biased against a first side of the groove and the second ring is biased against a second, opposite side of the groove.
16. The sleeve valve assembly of claim 15, wherein the stationary part further comprises an oil drain through which oil in the groove drains.
17. A method comprising:
- moving a sleeve valve between open and closed positions to control fluid flow through a port of an internal combustion; and
- resisting leakage of a liquid comprising coolant and/or lubricant past a valve body of the sleeve valve to the port, the resisting being performed at least in part by a substantially ring-shaped seal comprising at least one of:
- a) a ring carried in a groove recessed into the valve body, and
- b) first and second rings disposed around the valve body and biased apart from each other, the first and second rings being disposed on a stationary part of the internal combustion engine such that the valve body moves relative to the first and second rings.
18. The method of claim 17, further comprising resisting leakage of gas past the sleeve valve.
19. The method of claim 17, wherein the sleeve valve reciprocates between the open and closed positions along a common axis with a piston of the one or more pistons.
20. The method of any of claim 17, wherein the substantially ring-shaped seal comprises the ring carried in the groove recessed into the valve body, and wherein the seal exerts a radial force outward against the stationary part of the internal combustion engine.
21. The method of any of claim 17, wherein the substantially ring-shaped seal comprises the first and second rings disposed on the stationary part and around the valve body, and wherein the first and second rings have respective ring tensions to exert a radial force inward against the valve body.
22. The method of claim 21, further comprising draining liquid out of a groove in the stationary part in which the seal is disposed.
Type: Application
Filed: Jun 19, 2014
Publication Date: Dec 25, 2014
Inventor: James M. Cleeves (Redwood City, CA)
Application Number: 14/309,825
International Classification: F01L 7/16 (20060101);