ANTIROTATION REED VALVE SYSTEMS AND METHODS FOR COMPRESSORS

An antirotation valve system for controlling flow through a valve opening defined in a compressor surface. The antirotation valve system includes a reed and a backer each having one mounting opening and one antirotation feature, and a washer.

FIELD

This disclosure relates generally to systems and methods for assembling and manufacturing reed valves, and more particularly to reed valves having an antirotation feature for use with compressors.

BACKGROUND

Reed valves are used to regulate flow through a valve opening in the scroll of a compressor. Components of the reed valve assembly are typically mounted to a compressor surface using fasteners, e.g., screws, to prevent the reed valve assembly from rotating relative to the compressor surface. Such prior mounting requires a multi-step manufacturing process that requires tool changes, and assembly techniques that are time consuming and costly.

Improved, cost-effective systems and methods for manufacturing and assembling reed valves in compressors are needed.

BRIEF DESCRIPTION

In one aspect, an antirotation valve system includes a compressor including a compressor surface defining at least one valve opening and a mounting opening and a reed valve assembly. The reed valve assembly includes a reed including a reed mounting opening. The reed is positionable between an open position where the reed does not obstruct the at least one valve opening and a closed position wherein the reed blocks at least a portion of the valve opening. The reed valve assembly includes a backer having a backer mounting opening. The reed valve assembly includes a retainer. The reed and the backer are mounted to the compressor by the retainer extending through the reed mounting opening, the backer mounting opening, and into the compressor mounting opening. The reed valve assembly includes a washer including an annular wall defining a washer opening that is sized and shaped to receive the retainer extended through the reed mounting opening and the backer mounting opening to retain a relative position of the reed, the backer, the washer, and the retainer.

In another example, an antirotation valve system includes a compressor including a compressor surface defining at least one valve opening and a mounting opening and a reed valve assembly. The reed valve assembly includes a reed including a wall defining a reed mounting opening sized and shaped to receive a retainer extended therethrough. The reed is positionable between an open position where the reed does not obstruct the at least one valve opening and a closed position wherein the reed blocks at least a portion of the valve opening. The wall includes a plurality of teeth configured to be engaged with the retainer. The reed valve assembly includes a backer having a backer mounting opening and a retainer. The reed and the backer are mounted to the compressor by the retainer extending through the reed mounting opening, the backer mounting opening, and into the compressor mounting opening, wherein when the plurality of teeth are configured to be engaged with the retainer to retain a relative position of the reed, the backer, and the retainer.

In another aspect, a method of assembly includes providing a reed including a single reed mounting opening and a reed antirotation feature and providing a backer having an antirotation feature sized to engage with the reed antirotation feature and a single backer mounting opening. The method includes inserting a retainer through the reed mounting opening and the backer mounting opening and inserting the retainer extended through the reed mounting opening and the backer mounting opening into a washer opening defined by an annular wall of a washer to retain a relative position of the reed, the backer, and the washer.

DETAILED DESCRIPTION

Referring to FIGS. 1-3, a scroll compressor, for use with a reed valve assembly 200, is indicated generally at 100. The compressor 100 includes a compressor housing 102 forming at least one sealed cavity within which refrigerant compression is accomplished. The compressor housing 102 includes a shell 104, an end cap 106 and a base 110 disposed at opposing ends of the shell 104.

The compressor 100 includes a non-orbiting scroll 120 (e.g., a fixed scroll) and an orbiting scroll 122 operably engaged with a motor assembly 124. The scroll compressor 100 may be a floating orbit design, a floating non-orbit design such as co-rotating, and related compressor designs. The end cap 106 and the non-orbiting scroll 120 at least partially define a first chamber 128. For example, at least a portion of the shell 104 and/or a muffler plate (not shown) at least partially defines the first chamber 128. The shell 104 at least partially defines a second chamber 130. The motor assembly 124 includes a motor stator 134 and a rotor 136. The compressor 100 also includes a driveshaft 138 that may be press fit within the rotor 136. The rotor 136 transmits rotational power to the driveshaft 138. The motor assembly 124 may be a variable-speed motor for rotating the driveshaft 138 at any of a plurality of speeds. In the illustrated embodiment, the motor assembly 124 is disposed within the shell 104, e.g., within the second chamber 130. In some other embodiments, the compressor 100 may be an open drive compressor driven by a motor assembly that is disposed outside of the compressor housing 102. The compressor 100 further includes a first bearing assembly 140 and a second bearing assembly 142 that may rotationally support the driveshaft 138.

An axial direction includes a direction aligned with, and/or parallel to, the longitudinal axis A1 of the driveshaft body 160. A radial direction includes a direction that is radial relative to the longitudinal axis A1 and perpendicular to the longitudinal axis A1. The driveshaft 138 includes a driveshaft body 160 and an eccentric body 162 that may be projecting from the driveshaft body 160. The driveshaft body 160 and the eccentric body 162 are cylindrical in shape. The eccentric body 162 includes a longitudinal axis A2 that is off set from the longitudinal axis A1. The driveshaft body 160 is rotatably supported by the first and second bearing assemblies 140, 142, respectively. The bearing assemblies 140, 142 may include a roller ball assembly. In other embodiments, the first bearing assembly 140 may include other types of rolling bearings, and/or sleeve/journal bearings. The eccentric body 162 of the driveshaft 138 may be drivingly engaged to a drive bearing 164. The drive bearing 164 transmits rotational motion from the eccentric body 162 to the orbiting scroll 122.

An inlet 175 is attached to the compressor housing 102 in the end cap 106, for drawing the working fluid into the fluid pockets defined by a spiral wrap 172 of the orbiting scroll 122 and a spiral wrap 146 of the non-orbiting scroll 120, where the working fluid is compressed. After the working fluid is compressed, the compressed working fluid exits the fluid pocket defined by spiral wrap of the non-orbiting and orbiting scrolls 120, 122 through a discharge passage and into chamber 128. The compressed working fluid flows from the chamber 128 into chamber 130 through one or more passages between the non-orbiting and orbiting scrolls 120, 122, and the shell 104. The compressed working fluid exits the chamber 130 through a discharge fitting 176. The discharge fitting 176 may be attached to the base 110 of the compressor housing 102. A discharge valve assembly, not shown, may be disposed within the discharge fitting 176 and may generally prevent a reverse flow condition through the discharge fitting 176. A hermetic terminal may be attached to the compressor housing 102 at the base 110.

The compressor 100 may include one or more counterweights attached to the driveshaft body 160 to rotationally balance the driveshaft 138.

In reference to FIG. 3, the non-orbiting scroll 120 includes a compressor surface 202 defining one or more valve openings 204, obstructed from view in FIG. 3 by the valve assembly 200. The valve openings 204 are visible in FIG. 10. Flow through one or more of the valve openings 204, formed through the compressor surface 202, may be regulated by the valve assembly 200. In the illustrated embodiment, the compressor surface 202 is a surface of the non-orbiting scroll 120. The valve assembly 200 may be used to regulate flow through valve openings 204 formed in other and/or alternative surfaces of the compressor 100. The valve assembly 200 may be used to regulate flow through valve openings 204 formed in surfaces of additional and/or alternative devices. The compressor surface 202 may have a vertical axis Z202. The valve openings 204 may extend generally parallel to the vertical axis Z202.

In reference to FIGS. 4-10, the valve assembly 200 includes a reed 210, a backer 212, and the valve assembly 200 may be mounted to the compressor 100 using a fastener 214. The valve assembly 200 may be mounted to the compressor 100 using a single fastener 214. When the valve assembly 200 is mounted to the compressor surface 202, the reed 210 is disposed between the compressor surface 202 and the backer 212. The backer 212 includes a backer body 220 having a backer thickness t212 and extending between a first end 222 to a second end 224 along a backer length L212. The backer 212 includes a flat portion 226, that is substantially planar, and an arched portion 228 that is arched relative to the flat portion 226.

The reed 210 includes a reed body 240 extending between a first end 242 and a second end 244. The reed body 240 is substantially planar between the first end 242 and the second end 244 having a relatively constant thickness t210. The reed thickness t210 may be less than the thickness t212 of the backer 212.

When the valve assembly 200 is mounted to the compressor surface 202 at least a portion of the reed 210 is held flat against the compressor surface 202 by the flat portion 226 of the backer 212. A portion of the reed 210 may bend between a closed position and an open position. When the reed 210 is in the closed position the reed 210 substantially obstructs the valve opening 204. When the reed 210 is in the closed position at least a portion of the reed 210 may cover the valve opening 204 and the reed 210 may be in contact with the compressor surface 202 surrounding a perimeter of the valve opening 204. When the reed 210 is in the closed position the reed 210 may lie flat against the compressor surface 202 along the length L210 of the reed 210, e.g., the reed 210 is parallel to the compressor surface 202 along the length L210 of the reed 210. When the reed 210 is in the open position the reed 210 does not substantially obstruct the valve opening 204. When the reed 210 is in the open position at least a portion of the reed 210 may be flexed away from the compressor surface 202 towards the arched portion 228 of the backer 212.

In reference to FIGS. 4-5, the backer body 220 of backer 212 defines a backer mounting opening 250. The backer 212 of this embodiment includes a single backer mounting opening 250. The backer mounting opening 250 may be formed through the flat portion 226 of the backer 212. The backer mounting opening 250 extends completely through the thickness t212 of the backer body 220. The second end 224 of the backer 212 is suitably rounded or curved, having no sharp edges or corners.

The backer body 220 defines a backer antirotation feature 254. The backer antirotation feature 254 of this embodiment is formed into, or is integral with, the backer body 220, near the first end 222 of the backer body 220. The backer antirotation feature 254 may include a tab 256 (e.g., a protrusion) projecting, generally perpendicularly, from the flat portion 226. The backer antirotation feature 254 may be formed by bending the tab 256 of the backer body 220 such that the tab 256 extends generally perpendicularly from the backer body 220. The backer 212 may be formed of any suitable material, e.g., metal, composites, and/or powdered metal blends that have been sintered.

The reed body 240 defines a reed mounting opening 260. The reed 210 of this embodiment, includes a single one of the reed mounting opening 260. The reed mounting opening 260 passes completely through the thickness t210 of the reed body 240. The second end 244 may be rounded, having no sharp edges or corners. The reed body 240 also defines a reed antirotation feature 264. The reed antirotation feature 264 may be formed on and/or through the reed body 240 near the first end 242 of the reed body 240. The reed antirotation feature 264 may include a channel 266 (e.g., a slot). The channel 266 may be defined, in part, by an arched or semi-circular boundary 268. The semi-circular boundary 268 may have the same radius of curvature as the radius of curvature of the reed mounting opening 260. As such, a single tool may be used to form the reed mounting opening 260 and the reed antirotation feature 264. The reed antirotation feature 264 may have other shapes and/or dimensions. For example, the reed antirotation feature 264 may include one or more straight edges. The reed antirotation feature 264 may include a boundary that completely encloses the channel 266.

The reed antirotation feature 264 may be separated from the reed mounting opening 260 by a distance da. The reed mounting opening 260 may be positioned closer to the first end 242 compared to the second end 224. The reed mounting opening 260 may be spaced from the first end 242 by a distance db. The reed 210 may be formed of any suitable material, e.g., metal, composites, steel, stainless steel, fiberglass, and carbon fiber. The reed 210 may be formed of a material and/or has a suitable shape, e.g., thickness t210, such that the reed 210 is flexible.

When the reed 210 and backer 212 are assembled together to form the valve assembly 200, the backer mounting opening 250 and the reed mounting opening 260 are sized and shaped the same and/or substantially the same, e.g., having the same diameter, or having the same diameter within acceptable manufacturing tolerances, e.g., for a diameter of 0.24 inches the tolerance may have a range within ±0.0065 inches. The backer mounting opening 250 and the reed mounting opening 260 may be formed using the same tool. For example, using the same drill bit.

In reference to FIG. 10, the compressor surface 202 further includes a compressor mounting opening 270 used to mount the valve assembly 200 to the compressor surface 202. For each valve assembly 200, the compressor surface 202 includes a single compressor mounting opening 270. The compressor mounting opening 270 may be a blind bore or a threaded blind bore having a diameter d274. The compressor surface 202 may further define a compressor antirotation feature 274. The compressor antirotation feature 274 may be a blind bore or opening formed through the compressor surface 202. The compressor surface 202 may include a single compressor antirotation feature 274 for use with an individual valve assembly 200. The compressor mounting opening 270 and the compressor antirotation feature 274 may have the same shape and size, e.g., the same diameter, and may be formed using the same tool, e.g., a single drill bit. The depth of the compressor mounting opening 270 may be different than the depth of the antirotation feature, e.g., the antirotation feature may have a shallower depth than the depth compressor mounting opening 270.

When the backer mounting opening 250 and the reed mounting opening 260 are aligned, the fastener 214 may be passed through both the backer mounting opening 250 and the reed mounting opening 260 and into the compressor mounting opening 270. The fastener 214 may be a screw, a bolt, a rivet, or any suitable attachment mechanism. The compressor mounting opening 270 may be threaded and the fastener 214 may be threadably engaged with the threads of the compressor mounting opening 270. When the fastener 214 is threaded into engagement with the threaded blind bore of the compressor mounting opening 270, at least a portion of the reed 210 is positioned between the backer 212 and the compressor surface 202.

Additionally, when the compressor mounting opening 270, the reed mounting opening 260 and the backer mounting opening 250 are aligned, the backer antirotation feature 254 may be positioned through the reed antirotation feature 264 and into the compressor antirotation feature 274. The backer antirotation feature 254 may extend into the compressor antirotation feature 274 to a depth of dc. The depth dc may be substantially the same as the depth of the blind bore compressor antirotation feature 274. The backer antirotation feature 254 may extend into the compressor opening at any suitable depth to maintain the backer antirotation feature 254 within the reed antirotation feature 264 and within the compressor antirotation feature 274. The reed antirotation feature 264 may have a width W254 that is substantially the same as the diameter of the compressor antirotation feature 274. The width W254 may be slightly less than the diameter d274, such that the reed antirotation feature 264 may be press fit into frictional engagement with compressor antirotation feature 274. No tools are needed to assemble the backer antirotation feature 254 with the reed antirotation feature 264 and/or the compressor antirotation feature 274.

FIG. 11 is a process flow diagram of a method 500 for manufacturing and assembling a reed valve assembly, such as the reed valve assembly 200 for use with the compressor shown in FIG. 1 and the reed valve assembly 200 shown in FIG. 3, as an example.

Method 500 of this embodiment includes making (e.g., manufacturing, fabricating, or forming) the reed body 240 using a suitable stamping operation. Such operation may use a stamp or die, for example. A boundary or outline of the stamp may be shaped to cut or stamp out the perimeter of the reed body 240. The reed body 240 is suitably stamped from a substantially planar sheet of metal having a suitable thickness for use as the reed 210. Method 500 also includes forming 504 the reed mounting opening 260. The die may include an outer cutting edge for cutting the outer perimeter of the reed body 240 and an inner cutter having a circular shape for cutting the reed mounting opening 260. Method 500 may include using one or more dies and/or more stamping processes to form the reed body 240. For example, method 500 may include a first stamping process for cutting out the outer perimeter of the reed body 240 and a second stamping process for cutting out the reed mounting opening 260.

Method 500 may include forming 502 the reed antirotation feature 264, e.g., formed as a cutout in the boundary of the reed body 240.

Method 500 includes making (e.g., manufacturing, fabricating, or forming) the backer body 220 using a suitable stamping process using a stamp or die to form the perimeter of the backer body 220 and/or the backer opening from a planar sheet of metal having a suitable thickness for the backer 212. Method 500 includes bending the arched portion 228 of the backer 212 relative to the flat portion 226. Method 500 includes forming 506 the backer antirotation feature 254. Forming 506 the backer antirotation feature 254 may also include bending the tab 256 of the backer 212 approximately 90° relative to the flat portion 226 of the backer 212. Method 500 includes forming 508 the backer mounting opening 250 and/or forming 506 the reed 210 mounting opening 260. In one embodiment, the forming 508 step is a drilling operation using a drill bit, and in one example, this step does not require a tool change. Forming 508 the backer mounting opening 250 and/or forming 506 the reed 210 mounting opening 260 may include a punching process, e.g., using a die and mandrel.

Making the reed 210 and making the backer 212 may include performing any suitable manufacturing process. In some embodiments, making the reed 210 and the backer 212 may include a powdered metallurgy process including preparing and mixing the powdered composite, compacting the powder, and sintering. Making the reed 210 and the backer 212 may include performing a casting process. For example, the backer body 220 and the backer antirotation feature 254 may be formed integrally using a casting process such that the backer antirotation feature 254 projects outward from the backer body 220.

Method 500 includes forming 510 the compressor mounting opening 270. Forming the compressor mounting opening 270 may include drilling to a depth to form the blind bore. Forming the compressor mounting opening 270 may further include forming threads on an internal surface of the blind bore. The drill bit used to form the compressor mounting opening 270 may be the same drill bit that is used to form the backer mounting opening 250 and/or the reed mounting opening 260.

Method 500 includes forming 512 the compressor antirotation feature 274. A single tool may be used to form both the compressor antirotation feature 274 and the compressor mounting opening 270. Forming the compressor antirotation feature 274 and forming the compressor mounting opening 270 may be formed sequentially, in either order, without requiring a tool change.

Method 500 includes one or more steps for assembling the valve assembly 200 and attaching the valve assembly 200 to the compressor surface 202. Method 500 suitably includes engaging 514 the reed antirotation feature 264 with the backer antirotation feature 254. Engaging 514 the reed antirotation feature 264 with the backer antirotation feature 254 also includes inserting the tab 256 into the channel 266. Engagement of the reed antirotation feature 264 with the backer antirotation feature 254 restricts rotation, about a vertical axis Z226 extending perpendicular to the flat portion 226, between the reed 210 and the backer 212. Method 500 may further include engaging 516 the backer antirotation feature 254 with the compressor antirotation feature 274. Engaging 516 may include inserting the backer antirotation feature 254 into the compressor antirotation feature 274.

When the backer antirotation feature 254 is engaged with the compressor antirotation feature 274, the reed mounting opening 260, the backer mounting opening 250, and the compressor mounting opening 270 are aligned. Method 500 includes fastening 518 the reed 210 assembly to the compressor surface 202. Fastening 518 may include inserting the fastener 214 through the reed mounting opening 260 and through the backer mounting opening 250 and into the compressor mounting opening 270. Method 500 may include threading the fastener 214 into threaded engagement with the compressor mounting opening 270. In some embodiments, the fastener 214 may be press fit into the reed mounting opening 260, backer mounting opening 250, and the compressor mounting opening 270.

FIGS. 12-14 show a perspective view of another example reed valve assembly 400 including the reed 210 and the backer 212. The reed valve assembly 400 includes the backer mounting opening 250 and the reed mounting opening 260. The backer body 220 defines a backer antirotation feature 402. The backer antirotation feature 402 of this embodiment extends therefrom, or is formed integrally with, the backer body 220, positioned near the first end 222 of the backer body 220. The backer antirotation feature 402 may include a rod 404 (e.g., a protrusion) projecting, generally perpendicularly, from the flat portion 226. The rod 404 may be cylindrical. In alternative embodiments, the backer antirotation feature 402 may have other shapes or configurations, e.g., a non-round part or a spring pin. The backer antirotation feature 402 may be spaced a distance d402 from the first end 222. In some embodiments, the backer antirotation feature 402 may be spaced the distance d402 from an edge, e.g., a lateral edge, of the backer body 220.

The reed body 240 defines a reed antirotation feature 420. The reed antirotation feature 420 may be formed on and/or through the reed body 240 near the first end 242 of the reed body 240. The reed antirotation feature 420 may include an opening 422. In the illustrated embodiment, the opening 422 is enclosed. For example, the opening 422 may be defined by a boundary 424 that is circular. The boundary 424 may have the same radius of curvature as the radius of the reed mounting opening 260. As such, a single tool may be used to form the reed mounting opening 260 and the reed antirotation feature 420. The reed antirotation feature 420 may be sized and shaped to receive the backer antirotation feature 402 therein. The reed antirotation feature 420 may have other shapes and/or dimensions, e.g., rectangular or having an open side.

In some embodiments, the reed valve assembly 400 may include a retainer 430, e.g., a pin, a dowel, a rivet, a bolt, a stud, a fastener or a screw, that may be inserted through the backer mounting opening 250 and the reed mounting opening 260 to hold and align the reed 210 and the backer 212 together, during assembly and/or the retainer 430 may be used to attach the reed valve assembly 400 to the compressor 100, e.g., the retainer 430 may be connected to the compressor 100 by inserting the retainer 430 into the compressor mounting opening 270 and/or threadably engaging threads of the retainer 430 with internal threads of the compressor mounting opening 270. In some embodiments, the backer 212 includes a counterbore 432 sized and shaped to receive a portion of the retainer 430, e.g., the counterbore 432 may include a depth suitable to receive a head 434 of the retainer 430 such that no portion of the retainer 430 extends above an upper surface of the backer 212 when the reed valve assembly 400 is attached to the compressor 100.

The reed valve assembly 400 includes a washer 450 that may be connected to the retainer 430, to hold together and align the relative positions of the reed valve assembly 400, e.g., the retainer 430, the reed 210, and the backer 212. The washer 450 includes an annular wall 452 including an inner surface 454 defining an opening 456. In some embodiments, the inner surface 454 is annular and is sized and shaped to receive at least a portion of the retainer 430 therein. In one embodiment, the washer 450 is a threaded nut wherein the inner surface 454 includes threads that may be threadably engaged with threads, not shown, of the retainer 430. In other embodiments, the washer 450 is formed of a plastic material and the retainer 430 may be press fit into the opening 456 and the retainer 430 may be in frictional connection with the inner surface 454 of the washer 450. The washer 450 may also be suitably formed of a metal or metal alloy.

The compressor mounting opening 270 may include a counterbore, not shown, having a depth and diameter that is sized and shaped to receive the washer 450 therein such that at least a portion of the lower surface 480 of the reed 210 is in contact with the compressor surface 202, when the reed valve assembly 400 is connected to the compressor 100.

FIG. 15 is a perspective view of an example embodiment of the washer 450. FIG. 16 is a perspective view of another example embodiment of the washer 450. In some embodiments, the inner surface 454 may include a plurality of protrusions 460 (e.g., teeth), extending generally radially inward into the opening 456 and valleys 462 defined between adjacent protrusions 460. In some embodiments such as the FIG. 15 embodiment, the protrusions 460 and the valleys 462 are rounded or have rounded portions. As shown in FIG. 15, the protrusions 460 suitably include an upper surface 464 that is parallel and aligned with an upper surface 468 of the annular wall 452. as shown in the FIG. 16 embodiment, the protrusions 460 suitably include a portion of the upper surface 464 that extends vertically beyond the upper surface 468 of the annular wall 452.

When the washer 450 is pressed within the compressor counterbore (e.g., between the reed 210 and the compressor 100) during attachment of the reed valve assembly 400 to the compressor 100, the protrusions 460 may be pressed into or against either, or both, of a lower surface 480 of the reed 210 or a compressor surface 202 of the compressor 100. The washer 450 may serve a dual purpose such that the washer 450 may be used to retain the reed valve assembly 400 together before the reed valve assembly 400 is attached to the compressor 100, and additionally, the washer 450 acts as a lock washer when the reed valve assembly 400 is attached to the compressor 100. In alternative embodiments, the washer 450 may be removed from the retainer 430 immediately prior to connecting the reed valve assembly 400 to the compressor 100.

In reference to FIG. 14, the washer 450 is placed at a depth along the length of the retainer 430, enabling the retainer 430 to be able to translate relative to the backer 212 and or the reed 210. The reed valve assembly 400 of this embodiment may include a biasing mechanism (not shown) disposed between the reed 210 and the washer 450 to maintain the position of the washer 450 along the length of the retainer 430. The biasing mechanism may also be used to retain the reed 210 relative to the backer 212 as the retainer 430 comes into contact with the compressor mounting opening 270 and/or internal threads of compressor mounting opening 270 enabling the retainer 430 to translate, e.g., upwards, while maintaining the reed 210 and the backer 212 in alignment. As the retainer 430 is tightened, the biasing mechanism may be compressed between the washer 450 and a lower surface 480 of the reed 210.

The washer 450 may also be c-shaped, having an opening formed in the annular wall 452. In some embodiments, the washer 450 may include additional or alternative shapes, for example, the washer 450 may be a C-clip or an E-clip.

FIG. 17 shows a perspective view of another example reed valve assembly 600 including a reed 602 and the backer 212. The reed 602 includes a reed mounting opening 604 defined by an inner surface 608, formed in the reed 602, via a stamping process, which may include a plurality of protrusions 610 (e.g., teeth) and valleys 612. In some embodiments, the protrusions 610 and the valleys 612 are rounded or have rounded portions. The plurality of protrusions 610 may be equally spaced apart by the valleys 612. In the reed assembly 600, the washer 450 may be omitted, and the reed mounting opening 604 including the protrusions 610 may be used to retain the retainer 430 together with the reed 602 and the backer 212. In addition, in the reed assembly 600, there may be no need for a counterbore formed on the compressor 100. A separate washer may also be used to hold the retainer 430 in place, in addition to the plurality of protrusions 610.

FIGS. 18 and 19 show another reed 700 that may be used with the reed assembly 600. The reed 700 includes a reed mounting opening 704 defined by an inner surface 708 including a star pattern formed in the reed 700, via a stamping process. The star pattern includes a plurality of protrusions 710 (e.g., teeth) and valleys 712. In some embodiments, the protrusions 710 are triangular and include a point 714. In some embodiments, the point 714 is blunt or flattened. In the illustrated embodiment, the valleys 712 are also triangular in shape. The star pattern may include ten of the protrusions 710. In other embodiments, the star pattern may include any suitable number of protrusions 710.

FIG. 20 is a process flow diagram of a method 800 for manufacturing and assembling a reed valve assembly, such as the reed valve assembly 400 or 600, for use with the compressor 100 shown in FIG. 1 and the reed valve assembly 400 shown in FIGS. 12-14, as an example.

Method 800 includes engaging 802 the reed antirotation feature 420 with the backer antirotation feature 402. Engaging 802 the reed antirotation feature 420 with the backer antirotation feature 402 also includes inserting the backer antirotation feature 402 into the reed antirotation feature 420. Engagement of the reed antirotation feature 420 with the backer antirotation feature 402 may, at least partially, restrict rotation (e.g., after a threaded portion of the retainer 430 is connected to the compressor 100), about the vertical axis Z226 extending perpendicular to the flat portion 226, between the reed 210 and the backer 212.

Method 800 further includes inserting 804 the retainer 430 into the backer mounting opening 250 and the reed mounting opening 260. Method 800 also includes connecting 806 the washer 450 to the retainer 430. For example, the retainer 430 may extend all the way through the backer mounting opening 250 and the reed mounting opening 260 such that a portion of the retainer 430 extends outwards from the reed 210 and backer 212, beyond the lower surface 480 of the reed 210, and the washer 450 attached thereto. The retainer 430 may be inserted into the opening 456 and the inner surface 454 is connected to an outer surface of the retainer 430. For the reed assembly 600, not including the washer 450, the method 800 may include the protrusions 610, 710 formed in the reed 602 or 700 retaining the retainer 430, the reed 602 or 700, and the backer 212 together. The washer 450 of this embodiment retains the reed 210, the backer 212, and the retainer 430 together relative to one another.

Method 800 suitably includes fastening 808 the reed 210 assembly to the compressor surface 202. Fastening 808 may include inserting the retainer 430, which extends through the reed mounting opening 260, the backer mounting opening 250, the washer 450, into the compressor mounting opening 270. Method 800 may include threading the retainer 430 into threaded engagement with the compressor mounting opening 270. In some embodiments, the retainer 430 may be press fit into the compressor mounting opening 270. Method 800 may suitably include inserting the washer 450 into a counterbore formed in the compressor 300.

Embodiments described and shown enable reduction of both manufacturing and assembly times, as compared to known methods and systems. For example, the washer enables retention of the reed valve assembly, e.g., the reed, the backer, and the retainer together, such that the reed valve assembly may be assembled and then subsequently attached to the compressor.

In another example, the reed mounting opening formed in the reed may include protrusions enabling retention of the reed valve assembly, e.g., the reed, the backer, and the retainer together, such that the reed valve assembly may be assembled and then subsequently attached to the compressor, while reducing the number of assembly components. The valve assembly may be mounted to the compressor surface using only a single mounting opening that is formed in the reed, the backer, and the compressor surface, and requires only a single retainer or fastener. The antirotation features, e.g., the reed antirotation feature, the backer antirotation feature, and the compressor antirotation feature, enable restriction of rotation of the valve assembly to maintain the alignment of the valve assembly and the valve opening, without requiring the use of an additional fastener or an additional use of a tool.

The anti-rotation features may eliminate the need for secondary mounting openings and/or secondary fixtures, per valve assembly, thereby reducing machining and assembly times. The single fastener may reduce assembly times compared to conventional systems requiring more than one fastener to maintain the alignment of the reed valve assembly. One or more of the antirotation features may be formed using the same tool that is used to form one or more of the mounting openings, reducing the manufacturing time by not requiring a tool change. For example, a single tool may be used to form the compressor mounting opening and the compressor antirotation feature. In another example, a single tool may be used to form the reed mounting opening and the reed antirotation feature.