Patent Grant
12152490
The present disclosure relates generally to rotary engine and more specifically to application of fretting prevention coatings between components of a rotary engine.
A rotary engine is an internal combustion engine with one or more rotating pistons. A piston rotates within a combustion chamber defined within a housing that includes features for supplying coolant flow along with the required air/fuel mixture and lubricant. The combustion chamber is defined between two end walls that are exposed to high temperatures and pressures. The high temperatures and pressures can present challenges to operational longevity and performance.
Engine manufacturers continue to seek further improvements to engine performance including improvements to thermal, transfer and propulsive efficiencies.
A rotary internal combustion engine according to a disclosed example embodiment includes, among other possible things, a main rotor housing that has a peripheral wall that circumscribes a rotor cavity, a first interface surface and a second interface surface. A rotor is disposed within the rotor cavity. A first side housing is secured against the first interface surface of the rotor housing and a second side housing is secured against the second interface surface of the rotor housing, the main rotor housing, the first side housing and the second side housing are formed from an aluminum alloy and at least one of the first interface surface and the second interface surface include an anti-fretting coating. A first side plate is partially disposed within a clearance space between the first side housing and the main housing and a second side plate is partially within a clearance space that is disposed between the second side housing and the main housing. Each of the first side plate and the second side plate define a running surface for the rotor.
A rotary internal combustion engine according to another disclosed example embodiment includes, among other possible things, a main rotor housing that has a peripheral wall that circumscribes a rotor cavity, a first interface surface and a second interface surface. A rotor is disposed within the rotor cavity. A first side housing is secured against the first interface surface of the rotor housing. A second side housing is secured against the second interface surface of the rotor housing, the main rotor housing, the first side housing and the second side housing are formed from an aluminum alloy and at least one of the first interface surface and the second interface surface include an anti-fretting coating that has chromium carbide. A first side plate is partially disposed within a clearance space between the first side housing and the main housing. A second side plate is partially within a clearance space that is disposed between the second side housing and the main housing. Each of the first side plate and the second side plate define a running surface for the rotor, each of the first side housing and the second side housing include a plate support surface and an inner peripheral shoulder that have a peripheral surface that abuts a corresponding one of the first side plate and the second side plate and both the plate support surface and the peripheral surface include the anti-fretting coating.
A method of assembling a rotary internal combustion engine according to another disclosed example embodiment includes, among other possible things, forming at least a main rotor housing, a first side housing and a second side housing from an aluminum alloy. A first side plate and a second side plate are formed. Interface surfaces are selected between at least the main rotor housing, the first side housing, the second side housing, the first side plate and the second side plate. Non-selected surface of the each of the at least the main rotor housing, the first side housing, the second side housing, the first side plate and the second side plate are masked. An anti-fretting coating is applied to the selected interface surfaces.
Although the different examples have the specific components shown in the illustrations, embodiments of this invention are not limited to those particular combinations. It is possible to use some of the components or features from one of the examples in combination with features or components from another one of the examples.
These and other features disclosed herein can be best understood from the following specification and drawings, the following of which is a brief description.
Referring to
The example rotary internal combustion engine 20 is commonly referred to as a Wankel engine and includes a rotor 26 that rotates within a rotor cavity 28 defined by a peripheral wall 24 of a main rotor housing 22. The rotor 26 oscillates about an engine central axis A. Coolant passages 30 are defined within the peripheral wall 24 for circulation of a cooling flow. An inlet 40 and exhaust 42 are indicated schematically and provide communication of fuel and exhaust gases with the rotor cavity 28.
The rotor 26 includes sides 34 that extend between three apex portions 32. An end seal 38 and apex seal 36 are disposed at each of the apex portions 32. The apex seal 36 provides for sealing against the peripheral wall 24 and the end seal 38 provides for sealing against a seal running surface 45 on each of a first side plate 48 and a second side plate 50 (
A first side housing 44 is attached at a first interface 60 to a first side of the main rotor housing 22. A second side housing 46 is attached at a second interface to a second side of the main rotor housing 22. The first side plate 48 includes an edge 76 that is disposed within a first clearance space 64 between an inner edge 72 of the first side housing 44 and the main housing 22. The second side plate 50 includes an edge 78 that is disposed within a clearance space 66 between the main housing 22 and an inner edge 74 of the second side housing 46. The first and second side plates 48, 50 are supported over the rotor cavity 28 such that rotor 26 is mounted with an axial clearance between side plates 48 and 50. The side plates 48, 50 are further supported at corresponding first and second interfaces 68, 70.
The first and second side plates 48, 50 are further supported at a radially inner portion by a corresponding one of a first transfer housing 52 and a second transfer housing 54. The first and second transfer housings 52, 54 are fabricated from aluminum and mate to a corresponding one of the first and second side housings 44, 46 by way of a radial fit. The first transfer housing 52 mates to the first side housing 44 at a radially inner interface 90. The second transfer housing 54 mates to the second side housing 44 at a radially inner interface 92.
A first main bearing support 56 is in contact with the first housing 44 at a radial interface 98 and an axial interface 94. A second main bearing support 58 is in contact with the second side housing 46 at a radial interface 100 and an axial interface 96. In one disclosed example, the first main bearing support 56 and the second bearing support 52 are steel parts.
Select interfaces between the components are treated with an anti-fretting coating. The anti-fretting coating is applied to component interfaces and provide increased wear resistance.
Referring to
Additionally, the example anti-fretting coating is selected from material that is compatible with strains encountered at each interface. Accordingly, the composition of the anti-fretting coating is selected, at least partially, based on a ductility in view of the local strain at any interface. Additionally, the example anti-fretting coating 80 is applied as a single-layer coating. However, a multi-layer coating could also be used and is within the contemplation and scope of this disclosure.
Referring to
The interface 60 is between the surface 102 of the main housing 22 and the surface 104 of the first side housing 44. Either or both surfaces 102 and 104 may be coated with an anti-fretting coating. In one example embodiment, the cross-hatched surfaces of the side housing 44 are coated with an anti-fretting coating indicated at 108.
Referring to
Referring to
The support surface 106 is interrupted at portions 110 by a plurality of channels 112. The portions 110 are coated along with the support surface 106 to increase wear resistance at the interface with the side plate 48.
A dowel hole 128 is masked to prevent overspray impingement and to maintain the desired dimensions. Holes 114, 126 for tie bolts and channels 112 may be allowed to have some overspray of the anti-fretting coating. An exterior surface 130 may also be permitted to accumulate some overspray. The surfaces that can tolerate overspray of the anti-fretting coating are not masked to simplify application of the anti-fretting coating.
The application of the anti-fretting coating may be completed before any final contour machining of all these channels 112 to simplify the coating process and avoid complex masking. For example, a simple pocket having the depth of the side plate back support face could be machined in the semi-finish side housing, then the coating would be applied and final machined to produce all the support face contours and improve the surface finish and flatness of the coating surface on the remaining coated surfaces.
Referring to
Referring to
Each of the first transfer housing 52 and the second transfer housing 54 includes a radially inner surface 142 abutting a radially inner surface 86, 88 (
The radially inner surface 142 is coated with anti-fretting coating and is disposed between chamfers 146. The transfer housing 52 is made of aluminum alloy and the coating is applied to protect the aluminum of both the side housing 44 and the transfer housing 52. At the interface 86, the anti-fretting coating 146 is applied to prevent direct contact between the aluminum alloy of the transfer housing 52 and side plate 48 and therefore protect both parts. Overspray may be permitted on the adjacent chamfers 146 disposed on either side of the radially inner surface 142. A seal groove 148 incudes an inner side 144 that may have overspray. Overspray on the inner side 144 of the seal groove may be allowed because the remainder of the seal groove 148 remains clear of overspray.
Referring to
A chamfer 166 leading into the seal groove 162 may be permitted some overspray. The overspray on the chamfer 166 may be smoothed to ease the transition into the seal groove 162. The inner diameter 154 of an opening is masked to prevent adhesion of overspray. The chamfer 156 leading into the inner diameter 154 of thread hole is not masked to ease operation. Similarly, the inner diameter 158 is masked while the chamfer 160 transitioning into the inner diameter 158 is allowed to have some overspray of anti-fretting coating. A shoulder pin hole 152 is masked to prevent anti-fretting coating from changing a defined fit between a shoulder pin (not shown) and the hole 152. Although the portion of the first side housing 44 that engages the first bearing support 56 is shown and describe by way of example, the second side housing 46 would include the same or similar surfaces that are engaged to the second main bearing support 58 (
Although the example anti-fretting coating is described and disclosed by example as being a compound applied in a thermal spray process, other coating application processes could be utilized and are within the contemplation of this disclosure.
For example, a hard anodizing treatment could be utilized and applied to both the side housings 44, 46 and the main rotor housing 22. All surfaces and locations could be protected in the same operation and may provide reduced costs and manufacturing efforts.
Additionally, a hard carbon coating could be utilized instead of thermal deposition or anodizing. A hydrogen free amorphous carbon coating may be applied to aluminum alloys using a filtered arc technique.
Furthermore, an electro-deposited coating may be applied to protect selected locations. Many alternatives exist such as Ni-based matrix with fine SiC particles, Co-based matrix with chromium carbide particles, Co-P (pure, with chromium carbide or SiC particles). In this process, the part is immerged in an electrolyte bath and an electrical current is circulated between the parts (cathode) and a metalizing source material (anode).
Alternatively, a doped aluminum powder deposition process could be utilized. In such a process, a thin layer of aluminum alloy reinforced with hard particles such as SiC is applied in a process similar to thermal deposition.
Accordingly, the example disclosed housing provides for the localized application of an anti-fretting coating to significantly reduce or eliminate wear and fretting damage at the highly loaded mechanical interfaces of the rotary engine. Such wear is reduced while still providing for use of lightweight aluminum housing designs to meet aerospace demanding power-to-weight ratio targets.
A rotary internal combustion engine according to a disclosed example embodiment includes, among other possible things, a main rotor housing 22 that has a peripheral wall 24 that circumscribes a rotor cavity 28, a first interface surface and a second interface surface. A rotor 26 is disposed within the rotor cavity 28. A first side housing 44 is secured against the first interface surface of the main rotor housing 22. A second side housing 46 is secured against the second interface surface of the main rotor housing 22, the main rotor housing 22, the first side housing 44 and the second side housing 46 are formed from an aluminum alloy and at least one of the first interface surface and the second interface surface include an anti-fretting coating. A first side plate 48 is partially disposed within a clearance space 64,66 between the first side housing 44 and the main housing. A second side plate 48/50 is partially within a clearance space 64/66 that is disposed between the second side housing 46 and the main housing. Each of the first side plate 48 and the second side plate 48/50 define a running surface 45 for the rotor 26.
In a further embodiment of the foregoing, each of the first side housing 44 and the second side housing 46 include a plate support surface 106 that abuts a corresponding one of the first side plate 48 and the second side plate 48/50 and the plate support surface 106 includes an anti-fretting coating.
In a further embodiment of any of the foregoing, each of the first side housing 44 and the second side housing 46 includes a peripheral surface that abuts a corresponding one of the first side plate 48 and the second side plate 48/50 and the peripheral surface includes an anti-fretting coating.
In a further embodiment of any of the foregoing, the rotary internal combustion engine includes a first transfer housing 52 and a second transfer housing 54 that each includes a radially outer surface 140 that abuts a corresponding inner radial face surface 132 of one of the first side housing 44 and the second side housing 46. The radial face surface 132 includes an anti-fretting coating.
In a further embodiment of any of the foregoing, the radial face surface 132 of each of the first side housing 44 and the second side housing 46 is recessed to accommodate a thickness of the anti-fretting coating.
In a further embodiment of any of the foregoing, each of the first transfer housing 52 and the second transfer housing 54 includes a radially inner surface 142 that abuts a radially inner surface 142 of a corresponding one of the first side plate 48 and the second side plate 48/50 and the radially inner surface 142 includes an anti-fretting coating.
In a further embodiment of any of the foregoing, each of the first transfer housing 52 and the second transfer housing 54 include a seal surface adjacent to the radially inner surface 142 that does not include the anti-fretting coating.
In a further embodiment of any of the foregoing, the rotary internal combustion engine further includes a first bearing support 56 and a second bearing support 52 that abut against an inner bore surface of a corresponding one of the first side housing 44 and the second side housing 46. The inner bore surface of each of the first side housing 44 and the second side housing 46 includes an anti-fretting coating.
In a further embodiment of any of the foregoing, the anti-fretting coating includes a thermal spray coating that contains at least one of a chromium carbide, aluminum bronze, or tungsten carbide.
In a further embodiment of any of the foregoing, the anti-fretting coating includes one of an anodizing coating, a hard carbon coating, an electro-deposition coating or an aluminum powder coating.
In a further embodiment of any of the foregoing, the anti-fretting coating is machined to a desired thickness.
A rotary internal combustion engine according to another disclosed example embodiment includes, among other possible things, a main rotor housing 22 that has a peripheral wall 24 that circumscribes a rotor cavity 28, a first interface surface and a second interface surface. A rotor 26 is disposed within the rotor cavity 28. A first side housing 44 is secured against the first interface surface of the main rotor housing 22. A second side housing 46 is secured against the second interface surface of the main rotor housing 22, the main rotor housing 22, the first side housing 44 and the second side housing 46 are formed from an aluminum alloy and at least one of the first interface surface and the second interface surface include an anti-fretting coating that has chromium carbide. A first side plate 48 is partially disposed within a clearance space 64/66 between the first side housing 44 and the main housing. A second side plate 48/50 is partially within a clearance space 64/66 that is disposed between the second side housing 46 and the main housing. Each of the first side plate 48 and the second side plate 48/50 define a running surface 45 for the rotor 26, each of the first side housing 44 and the second side housing 46 include a plate support surface 106 and an inner peripheral shoulder that have a peripheral surface that abuts a corresponding one of the first side plate 48 and the second side plate 48/50 and both the plate support surface 106 and the peripheral surface include the anti-fretting coating.
In a further embodiment of the foregoing, the rotary internal combustion engine includes a first transfer housing 52 and a second transfer housing 54 that each includes a radially outer surface 140 that abuts a corresponding radial face surface 132 of one of the first side housing 44 and the second side housing 46 and a radially inner surface 142 that abuts a radially inner surface 142 of a corresponding one of the first side plate 48 and the second side plate 48/50. Both the radially outer surface 140 and the radial face surface 132 include the anti-fretting coating.
In a further embodiment of any of the foregoing, the rotary internal combustion engine further includes a first bearing support 56 and a second bearing support 52 that abut against an inner bore surface of a corresponding one of the first side housing 44 and the second side housing 46. The inner bore surface of at least one of the first side housing 44 and the second side housing 46 includes an anti-fretting coating.
A method of assembling a rotary internal combustion engine according to another disclosed example embodiment includes, among other possible things, forming at least a main rotor housing 22, a first side housing 44 and a second side housing 46 from an aluminum alloy. A first side plate 48 and a second side plate 48/50 are formed. Interface surfaces are selected between at least the main rotor housing 22, the first side housing 44, the second side housing 46, the first side plate 48 and the second side plate 48/50. Non-selected surface of the each of the at least the main rotor housing 22, the first side housing 44, the second side housing 46, the first side plate 48 and the second side plate 48/50 are masked. An anti-fretting coating is applied to the selected interface surfaces.
In a further embodiment of the foregoing, the method further includes forming a recess 136 on at least one of the selected interface surfaces prior to application of the anti-fretting coating. The recess 136 is formed to correspond with a final thickness of the anti-fretting coating.
In a further embodiment of any of the foregoing, the method further includes applying the anti-fretting coating to first thickness and machining the anti-fretting coating to a second thickness that is less than the first thickness.
In a further embodiment of any of the foregoing, the method further includes selecting a radially outer surface 140 on each of a first transfer housing 52 and a second transfer housing 54 that abuts a corresponding radial face surface 132 of one of the first side housing 44 and the second side housing 46 and applying the anti-fretting coating to the radially outer surface 140.
In a further embodiment of any of the foregoing, each of the first transfer housing 52 and the second transfer housing 54 include a seal surface adjacent to the radially inner surface 142 and the method includes the step of masking the seal surface.
In a further embodiment of any of the foregoing, the anti-fretting coating includes one of a chromium carbide, an aluminum bronze, or a tungsten carbide.
Although an example embodiment has been disclosed, a worker of ordinary skill in this art would recognize that certain modifications would come within the scope of this disclosure. For that reason, the following claims should be studied to determine the scope and content of this disclosure.
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