Title of Invention | A NEEDLE SUPPORT ASSEMBLY |
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Abstract | This invention relates to a needle support assembly for a syringe comprising a body having a longitudinal passage, a hollow needle supported within the passage, a handle member mounted to one end of its needle, the other end of the needle being provided with a first opening, a passageway provided through the wall of the passage towards one end of the passage, said passageway being intended to communicate with the chamber of the syringe, said needle being movable between a first position at which it is fully accommodated within the passage and a second position at which the one end of the needle extends from the one end of the passage, a second opening in the wall of the needle positioned such that when the needle is in its second position the second opening will communicate with the passageway, a first seal provided between the passage and the needle which will sealingly isolate the passageway, a second seal provided which will engage the second opening when the needle is in the first position and on movement of the needle to the first position is permanently sealingly disengaged from the second opening. |
Full Text | COMPRESSOR BALL VALVE The present invention relates to refrigerant compressors, and, more particularly, to discharge valve assemblies for refrigerant compressors. Refrigerant compressors are known of various types, such as reciprocating, rotary, and scroll. All such compressors have as a fundamental function the compressing of refrigerant fluids. Refrigerant compressors of the reciprocating piston type include at least one cylinder in which a piston reciprocatingly moves to both draw fluid into the cylinder, and compress the fluid before discharge. It is therefore necessary to provide a means for regulating the inflow and outflow of the fluid to and from the cylinder. Rotary type refrigerant compressors include a roller or piston which rotates or orbits within a cylinder, a sliding vane divides the area defined by the rotary piston and the cylinder wall into a compression chamber and a suction chamber. The rotary piston is rotated beyond a top dead center position to a point where the compression chamber is at a maximum, and to a point just prior to the top dead center position, where the compression chamber is at a minimum. As the rotary piston is rotated beyond the top dead center position it begins to compress refrigerant fluid contained in the compression chamber. One rotary compressor is disclosed in U.S. Letters Patent No. 5,339,652 (Dreiman) and is incorporated herein by reference. As with the reciprocating typ6 compressor, it is necessary to provide a means for regulating the inflow and outflow of the fluid t variety of discharge valve types are used, including flat leaf spring type valves. Typically in a rotary compressor application a flat leaf spring type valve member is biased toward a valve seat, as the volume of fluid is compressed an increasing force is created within the compression chamber. At a certain point, the force becomes sufficient to overcome the biasing force of the leaf spring, thereby causing the valve member to become unseated and permitting compressed refrigerant fluid to enter a discharge chamber. A problem with such valve arrangements is that they are traditionally disposed wholly external the discharge port. This results in a volume of fluid within the discharge port which is never compressed by the piston. This volume of fluid is defined by the thickness of the cylinder head or valve plate. This results in the occurrence of an undesirable re-expansion volume of fluid during each compression cycle. A valve member is needed that extends at least partially into the discharge valve port to reduce the reexpansion volume. Valve arrangements have been devised to provide a means of regulating the outflow of the fluid from the compressor cylinder while reducing the reexpansion volume. U.S. Patent No. 5,346,373, discloses a reciprocating type refrigeration compressor having a discharge valve poppet characterized by a spherical head which is spring biased so as to sealably seat against a valve seat which is formed in a discharge port of the compressor valve plate. A flat leaf spring and a rigid stop member bias the valve poppet toward the valvve seat and limit the displacement of the valve poppet during the compression stroke, respectively. The discharge port is formed in a separate valve plate, not the cylinder head, adding expense and assembly time to the resulting compressor. Moreover, the piston includes a concaved recess to receive the spherical head, which also adds to manufacturing expense while decreasing the cylinder volume. In rotary applications a flat leaf spring is biased toward a discharge port/valve seat provided in the cylinder' head. The leaf spring is disposed over and outside of the discharge port. Although this is a simple arrangement keeping the cost of manufacturing low, it does not address the undesired effect of inefficient re-expansion volume. Again, a valve member is needed that extends at least partially into the discharge valve port to reduce the reexpansion volume. Although the nature of a scroll type compressor does not necessitate a valve at the discharge of the compressor mechanism, enhanced noise qualities have been achieved with the use of discharge valves. One beneficial effect of utilizing discharge valves in scroll compressors is the substantial elimination of reverse orbiting which occurs upon the termination of compressor operation. Without a discharge valve, compressed fluid, at a higher pressure than the suction pressure refrigerant or partially compressed refrigerant, rushes into the orbiting scroll mechanism causing a reverse orbiting of the scroll mechanism. This creates an undesired "whizzing" noise which is preferably eliminated. Accordingly, discharge valves are also applicable in scroll applications, although for a different function than that required in reciprocating or rotary compressors. The present invention utilizes a discharge ball valve for use in refrigerant compressors of the reciprocating, rotary and scroll types. The present ball valve addresses the above-identified needs by providing a ball valve assembly having a ball valve member which is positioned at least partially within a discharge port formed directly in a cylinder head. A separate valve plate is therefore not necessary, thus resulting in a less expensive compressor. In addition, by positioning the ball valve member within the discharge port, which is configured to most effectively receive the ball valve member, re- expansion volume is reduced, thereby enhancing compressor efficiency. The present invention as illustrated in the drawings provides a discharge ball valve assembly for use in a rotary compressor wherein the compressor includes at least one cylinder having a rotary piston or roller rotatingly disposed therein. A discharge port, preferably having a partially chamfered or spherical shape, is formed directly in the cylinder head of the compressor so as to provide a valve seat. The discharge port/valve seat receives a spherical valve member which engages the discharge port/valve seat. An plastically deformable arm with a cut-out, preferably circular, v/hich engages and captures the spherical valve member such that the spherical valve member in part protrudes through the cut-out. The elastically deformable arm biases the spherical valve rnember into penetrating and sealing contact with the discharge port to reduce re-expansion volume. The ball valve assembly is configured such that the spherical ball member is retained in engagement with the cut-out and is prevented from becoming dislodged and discharged into the discharge chamber. During the suction phase of the rotary piston within the cylinder, or the suction stroke in the case of a reciprocating piston, the elastic arm biases the spherical valve member into engagement with the discharge port During the compression phase of the rotary piston, the force of the compressed refrigerant within the cylinder will at some point overcome the biasing force of the elastically deformable arm to unseat the spherical valve member from engagement with the discharge port, thereby allowing the compressed refrigerant to be discharged. To maintain alignment of the spherical valve member with the discharge port and to prevent the spherical valve member from being displaced from its engagement with the elastic arm, a rigid stop plate is positioned adjacent the elastically deformable arm such that the spherical valve member protrudes through the elastically deformable arm at the cut-out and contacts the rigid stop plate during the compression phase. The movement of the spherical valve member is therefore limited by the rigid stop plate and the valve member is thereby retained in engagement with the cut-out. One advantage of the present invention is that re-expansion volume within the discharge port is reduced. Another advantage of the present invention is that the ball valve member is maintained in proper position due to the cut-out within the elastically deformable arm. Another advantage of the present invention is that the movement of the ball valve member is limited by the rigid stop plate. Yet another advantage of the present invention is that the discharge port/valve seat is formed directly in the cylinder head and does not necessitate the use of a separate valve plate. The present invention is therefore less expensive and easier to manufacture than prior art compressors. The present invention, in one form thereof, provides a refrigerant compressor comprising a compressor mechanism, a discharge chamber, and a discharge valve assembly. The compressor mechanism defines a compression chamber for compressing refrigerant fluid. The discharge chamber receives compressed fluid from the compression chamber. The discharge valve assembly is disposed intermediate the compression chamber and the discharge chamber and comprises a spherical valve member, a discharge port providing a seat for the valve member, an elastically deformable arm, and a rigid stop. The spherical valve member is seated against the discharge port adjacent the discharge chamber and is dimensioned to partially penetrate and seal the discharge port, thereby reducing re-expansion volume. The elastically deformable arm includes an aperture for partially receiving the valve member, and engages and bias the spherical valve member into engagement with the discharge port. The arm is adapted to elastically deform and thereby allow the valve member to move out of engagement with the discharge port during discharge of fluid from the compression chamber to the discharge chamber. The rigid stop is positioned over the spherical valve member and the deformable arm such that movement of the spherical valve member is limited by the rigid stop during discharge to thereby maintain alignment of the spherical valve member with the discharge port. The above-mentioned and other features and advantages of this invention, and the manner of attaining them, will become more apparent and the invention will be better understood by reference to the following description of an embodiment of the invention taken in conjunction with the accompanying drawings, wherein: Fig. 1 is a partial sectional view of a rotary compressor incorporating the discharge ball valve assembly of the present invention; Fig. 2A is an elilarged partial sectional view of the ball valve assembly of Fig. 1 in the closed position; Fig. 2B is an enlarged partial sectional view of the ball valve assembly of Fig. 1 in |he open position; and Fig. 3 is a plan view of the deformable arm of the ball valve assembly of Fig. 1. Corresponding reference characters mdicate corresponding parts throughout the several views. The exemplification set out herein illustrates one embodiment of the invention and such We Claim:- 1. A refrigerant compressor (20), comprising: a compressor mechanism (26) defining a compression chamber for compressing refrigerant fluid; a discharge chamber (57) receiving compressed refrigerant fluid from said compression chamber; and a discharge valve assembly (43) disposed intermediate said compression chamber and said discharge chamber, said discharge valve assembly characterized by: a discharge port (40); a spherical valve member (44) seated against said discharge port, said spherical valve member dimensioned to partially penetrate and seal said discharge port; an elastically deformable arm (46) having an aperture (48) partially receiving said spherical valve member therein, said arm engaging said spherical valve member and biasing said spherical valve member into engagement with said discharge port, said arm adapted to deform and thereby allow said spherical valve member to move out of engagement with said discharge port during a compression phase; and a rigid stop (50) disposed adjacent said spherical valve member and said arm, and limiting the movement of said spherical valve member during the compression phase, thereby maintaining alignment of said spherical valve member with said discharge port. 2. The compressor of Claim 1 characterized in that said arm aperture is a circular cut-out. 3. The compressor of Claim 1 characterized in that said deformable arm is manufactured from spring steel. 4. The compressor of Claim 1 characterized in that said deformable arm is manufactured from heat resistant plastic. 5. The compressor of Claim 1 characterized in that said deformable arm has a substantially planar surface, and said rigid stop is a rigid plate having an arcuate surface (54). 6. The compressor of Claim 5 characterized in that said compressor mechanism comprises a cylinder head (38), and wherein said deformable arm and said rigid plate are fastened to said cylinder head, said arm and said plate being in contact where said arm and said plate are fastened to said cylinder head, said arcuate rigid plate curving away from said deformable arm proximate said spherical valve member. 7. The compressor of Claim 1 characterized in that said discharge port is chamfered at a surface adjacent said discharge chamber to provide a seat (56) for said spherical valve member. 8. The compressor of Claim 1 characterized in that said compressor mechanism (26) includes a cylinder (34) receiving a piston (36) and a cylinder head (38) in which said discharge port (40) is formed therethrough, and said cylinder and said cylinder head define said compression chamber, 9. The compressor of Claim 1 characterized in that said compressor is a rotary refrigerant compressor which comprises a cylinder block (33) having a bore (39) defining a cyUnder (34), a roitary piston (36) received in said cylinder, a vane slidingly received in said cylinder block and engaging said piston, and a cylinder head (38) having said discharge port formed therethrough and defining said discharge chamber, and wherein said cylinder, said vane, said piston, and said cyhnder head define said compression chamber. 10. A refrigerant compressor substantially as herein desceibed with reference to the accompanying drawings. |
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2575-mas-1997 description (complete) duplicate.pdf
2575-mas-1997 pct search report.pdf
2575-mas-1997-correspondence others.pdf
2575-mas-1997-correspondence po.pdf
2575-mas-1997-description complete.pdf
Patent Number | 202150 | ||||||||
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Indian Patent Application Number | 2575/MAS/1997 | ||||||||
PG Journal Number | 05/2007 | ||||||||
Publication Date | 02-Feb-2007 | ||||||||
Grant Date | 11-Sep-2006 | ||||||||
Date of Filing | 12-Nov-1997 | ||||||||
Name of Patentee | M/S. EASTLAND MEDICAL SYSTEMS LTD | ||||||||
Applicant Address | L.Z 680 MURRAY STREET, WEST PERTH, WESTERN | ||||||||
Inventors:
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PCT International Classification Number | A61M 05/32 | ||||||||
PCT International Application Number | N/A | ||||||||
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PCT Conventions:
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