Abstract:
This invention relates to linear motor compressors which operate without the use of oil and a gas bearing while providing a flexible suspension for such a compressor. Such structures of this type, generally, provide a highly reliable oil-free compressor for use with cryogenic refrigeration equipment so as to attain unattended, continuous operation without maintenance over extended periods of time.

Description:
CROSS-REFERENCE TO A RELATED APPLICATION 
     This application is related to commonly assigned U.S. patent application Ser. Nos. 07/862,693 now abandoned, 07/862,293 now allowed 07/863,603 now allowed, respectively, to R. A. Ackermann et al., E. T. Laskaris and E. T. Laskaris et al., entitled, &#34;Linear Compressor Dynamic Balancer&#34;, &#34;Balanced Linear Motor Compressor&#34; and &#34;Oil-Free Linear Motor Compressor&#34;. 
     BACKGROUND OF THE INVENTION 
     1. Field of the Invention 
     This invention relates to linear motor compressors which operate without the use of oil and a gas bearing while providing a suspension for such a compressor. Such structures of this type, generally, provide a highly reliable oil-free compressor for use with cryogenic refrigeration equipment so as to attain unattended, continuous operation without maintenance over extended periods of time. 
     2. Description of the Related Art 
     It is known in cryorefrigerator compressors, to employ petroleum-based oil as the lubricant. Typically, a petroleum-based oil dissolves gases such as air and hydrocarbon which come in contact with the gases over time. When the oil in the compressor interacts with the cooling gases pumped by the compressor into the cold head, the oil releases the air into the cooling gases. Thus, a portion of air dissolved into the oil is carried by the cooling gases into the cold head. When the cooling gases contact the cold head, which, typically is maintained at temperatures below 77 K., the air condenses and solidifies on the cold head cold surfaces. The solidification of the air can adversely affect the cold head operation because it plugs up the regenerators, reduces the piston clearances and wears out the piston seals. Ultimately, the reduced capacity of the cold head can affect the overall performance of the cryorefrigerator. Therefore, a more advantageous compressor would be presented if the oil could be eliminated. 
     Also, linear motor compressors employ gas bearings for the reciprocating piston. While the gas bearings have met with a modicum of success, the gas bearings consume about 25% of the useful flow through the compressor and require tight tolerances to operate, thereby increasing the manufacturing cost of the compressor. Therefore, a still further advantageous compressor would be presented if the oil and the gas bearing could be eliminated. 
     It is apparent from the above that there exists a need in the art for a compressor which is capable of operating without a gas bearing and which, at least, equals the cooling characteristics of the known cryorefrigerator compressors, but which at the same time is oil-free so that the contamination and unreliability associated with cold heads employing oil lubricants are reduced. It is a purpose of this invention to fulfill this and other needs in the art in a manner more apparent to the skilled artisan once given the following disclosure. 
     SUMMARY OF THE INVENTION 
     Generally speaking, this invention fulfills these needs by providing an oil-free linear motor compressor suspension system, comprising an enclosure means, a stator means substantially located within said enclosure means, an inner core means substantially located within said stator means, a reciprocating driver coil means substantially located between said stator means and said inner core means, a compressor drive means located adjacent said inner core means and attached to said driver coil means, suspension means rigidly attached to said compressor drive means and said enclosure means, and a gas inlet and exhaust means substantially connected to said compressor drive means. 
     In certain preferred embodiments, the stator means houses a stationary epoxy-impregnated DC field coil and a reciprocating AC driver coil wound on a stainless steel coil form. Also, the compressor drive means includes a thin walled piston having a diaphragm valve and flexure springs. Finally, the suspension means are laminated springs having radial and circumferential sections which accommodate the piston displacement by combined bending and torsion of the springs to allow the piston to reciprocate in a substantially straight line without the use of a gas bearing. 
     In another further preferred embodiment, unattended, continuous operation of the compressor can be attained for long periods of time while reducing contamination of the cryorefrigerator cold head and increasing the reliability of the cold head. 
     The preferred compressor, according to this invention, offers the following advantages: easy assembly and repair; excellent compressor characteristics; good stability; improved durability; good economy; excellent suspension characteristics; and high strength for safety. In fact, in many of the preferred embodiments, these factors of compressor characteristics and durability and suspension characteristics are optimized to an extent considerably higher than heretofore achieved in prior, known compressors. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     The above and other features of the present invention which will become more apparent as the description proceeds are best understood by considering the following detailed description in conjunction with the accompanying drawings wherein like characters represent like parts throughout the several views and in which: 
     FIG. 1 is a side plan view of an oil-free linear motor compressor, according to the present invention; 
     FIG. 2 is a detailed, side plan view of the stator, the inner core and the driver coil, according to the present invention; 
     FIG. 3 is a detailed, side plan view of the piston, gas bearing and gas feed assemblies, according to the present invention; 
     FIG. 4 is a detailed, side plan view of the driver coil spring, according to the present invention; and 
     FIG. 5 is a detailed end view of the driver coil spring, according to the present invention. 
    
    
     DETAILED DESCRIPTION OF THE INVENTION 
     With reference first to FIG. 1, there is illustrated oil-free linear motor compressor 2. Compressor 2, generally, includes, stator assembly 4, gas feed assembly 50 and driver and suspension assembly 100. 
     As shown more clearly in FIG. 2, stator assembly 4 includes a conventional, water-cooled heat exchanger coil 6 which is secured to stator 12 by a band 8 that is located around the circumference of stator 12. Band 8 and stator 12, preferably, are constructed of steel. A conventional thermal grease 10 is located between the contacting surfaces of heat exchanger 6 and stator 12 in order to assure proper heat exchange between stator 12 and heat exchanger 6. Preferably, stator 12 is constructed of two halves 12a and 12b. A conventional threaded fastener 14 is used to retain halves 12a and 12b together. Located within stator 12 is DC field coil 18. Coil 18, preferably, contains epoxy-impregnated copper wire which is wound by conventional winding techniques upon a stainless steel coil form (not shown). Coil 18 is rigidly retained in stator 12 by fasteners 14. A conventional DC lead connection 20 is electrically connected to field coil 18. 
     Stator 12 is rigidly attached to bracket 22 by conventional fasteners 24. Bracket 22, preferably, is constructed of stainless steel. Diagonal sawcuts 28 are cut into stator 12 by conventional cutting techniques. Sawcuts 28 are used to break up the eddy current flow paths that are created by field coil 18 during operation of stator assembly 4. Typically, eddy currents create adverse electrical losses unless their flow path can be interrupted. 
     Also, located within stator 12 is alignment ring 30. Ring 30, preferably, is constructed of fiberglass. Ring 30 is rigidly held in stator 12 by rabbet fits 31. AC driver coils 34a and 34b are located on each side of ring 30. Coil 34, preferably, includes aluminum wires wound on a stainless steel coil form 33 by conventional winding techniques. Located along coil form 33 are slots 36. Slots 36 are machined on coil form 33 by conventional machining techniques to clear pins 32. Slots 36 allow driver coils 34a and 34b to reciprocate along the direction of arrows X and X&#39;, respectively, while stator assembly 4 is in operation. Electrical air gaps 35 are the annular gaps between stator halves 12a and 12b and core 42 within which the driver coils 34 are reciprocating. 
     Extension 40 is part of coil form 33. A conventional electrical lead 38 is electrically attached to coil 34 and a spring lead 112 (FIG. 4). Located inside coils 34 is inner core 42. Core 42, preferably, is constructed of iron and is rigidly held in stator 12 by alignment pins 32. Horizontal sawcuts 44 are machined in core 42 by conventional machining techniques. Sawcuts 44 perform substantially the same function as sawcuts 28 in that sawcuts 44 break up the flow path of eddy currents created by coils 34 during their reciprocating motion inside stator assembly 4. 
     FIG. 3 illustrates gas feed assembly 50. Assembly 50 includes, in part, conventional inlet 52 and conventional outlet 88. Helium, preferably, is the gas used in assembly 50 and throughout compressor 2. Inlet 52 is rigidly attached to bracket 56 by a conventional fastener 59. Bracket 56, preferably, is constructed of stainless steel. Bracket 56 is rigidly attached to drive assembly 100 by conventional fasteners 53. A conventional elastomeric O-ring 109 is located between bracket 56 and drive assembly 100. O-ring 109 is used to prevent gas leakage from gas feed assembly 50. 
     Located adjacent to bracket 56 is chamber 57 into which the gas is fed from inlet 52. Plate 58 separates chambers 57 and 61. Plate 58 includes holes 60 which are formed in plate 58 by conventional techniques. Holes 60 allow the gas to flow from chamber 57 to chamber 61. 
     Bracket 62 is rigidly attached to bracket 56 by conventional fasteners 63. Bracket 62, preferably, is constructed of stainless steel. Located between brackets 62 and 56 is a conventional pancake-type, water-cooled heat exchanger 64. A conventional vacuum grease 66 is placed at the surfaces where heat exchanger 64 contacts brackets 56 and 62 in order to ensure low thermal contact resistance between brackets 56 and 62 and heat exchanger 64. A conventional pressure transducer 68 is rigidly retained in bracket 56. Transducer 68 contacts channel 69 in bracket 56 such that the compression pressure within chamber 78 can be accurately measured. A conventional elastomeric O-ring 70 is located between brackets 56 and 62 in order to prevent gas leakage from compression chamber 78. 
     Located within bracket 56 is hollow piston 72. Piston 72, preferably, is a thin-walled piston and is constructed of stainless steel. Piston 72 reciprocates along the direction of arrow Y for approximately 1 inch. Coating 74 is located on the outer circumference of piston 72. Coating 74, preferably is a Teflon® non-stick coating which is placed on the outer circumference of piston 74 by conventional coating techniques. The purpose of coating 74 is to substantially prevent adverse wear between piston 72 and cylinder head 75 as piston 72 reciprocates and accidentally contacts cylinder head 75. A conventional one-way diaphragm 76 is rigidly attached to one end of piston 72 by a conventional fastener. Diaphragm 76 prevents gas that has entered compression chamber 78 from re-entering back into piston 72. 
     Exhaust valve 80 is located adjacent to chamber 78 and is rigidly retained within bracket 62. Valve 80 includes a conventional valve 81 and a valve spring 82. Spring 82, preferably, is constructed of high strength carbon steel and acts to keep valve 81 in a closed position during the compression stroke of piston 72 until a desired pressure in compression chamber 78 overcomes the spring force of spring 82 and causes valve 81 to open and the gas to escape out of outlet 88. Outlet 88 is rigidly attached to exhaust valve 80 by extension 84. A conventional elastomeric O-ring 86 located on extension 84 prevents gas from leaking from compressor 2 around bracket 62. 
     As shown in FIG. 4, located adjacent to gas feed assembly 50 is drive assembly 100. Driver and suspension assembly 100 includes, in part, spring lead 112 and driver coil 34. Located within drive assembly 100 are bracket 102 and window 106. Bracket 102, preferably, is constructed of stainless steel. Window 106 preferably, is constructed of any suitable transparent material and is fastened to bracket 106 by conventional fasteners 104. Bracket 102 is rigidly attached to bracket 56 by conventional fastener 53. A conventional elastomeric O-ring 109 is located between brackets 53 and 102 to prevent gas leakage from drive assembly 100. 
     Located on window 106 is a conventional AC connection 108. Connection 108 includes a conventional AC connector 110 which is electrically attached to spring lead 112. Spring lead 112, preferably, is constructed of the same high strength carbon steel material as spring 82 (FIG. 3). Lead 112 is rigidly held by one end with connector 108 and at the other end by a conventional fasteners 114. Fastener 114 includes AC connector 116 which is electrically connected to spring 112. Fastener 114 also rigidly connects the one end of spring 112 to bracket 140. Bracket 140 is rigidly attached to extension 40 by a conventional weldment. 
     Bracket 102 is rigidly attached to extension 122 by conventional fastener 120. Extension 122, preferably, is constructed of stainless steel. Extension 122 is rigidly attached to block 134 by weldment 123. Block 134, preferably, is constructed of stainless steel. Block 134 is rigidly attached to stator 12 by conventional fastener 138. A conventional elastomeric O-ring 136 is located between stator 12 and block 134 to prevent gas leakage from drive assembly 100. 
     Located within bracket 102 are springs 124 and 126. Springs 124,126, preferably, are constructed of laminated high strength, stainless steel, inconel, or titanium alloy having a high fatigue strength. Spring 124 is rigidly attached to bracket 130 by a conventional fastener 128. Bracket 130, preferably, is constructed of stainless steel. Springs 124 and 126 are rigidly attached to block 142 by a conventional fastener 144. Block 142, preferably, is constructed of stainless steel. Block 142 is rigidly attached to plate 58 by fastener 144. 
     FIG. 5 shows the radial section 124a of spring 124 and the circumferential section 124b of spring 124. Spring 126 also includes radial and circumferential sections. The radial section 124a deflects by bending while the circumferential section 124b accommodates the displacement of piston 72 (FIG. 3) by combined bending and torsion. Because of the symmetry of springs 124 and 126, the displacement of piston 72 is along a straight line. 
     In operation of compressor 2, gas is fed into inlet 52 (FIG. 3) by a conventional feed source (not shown) such that the inlet pressure is approximately 75 psi. DC field coil 18 (FIG. 2) produces a radial field in air gaps 35. The AC driver coils 34a and 34b are powered in opposite polarity so the interaction of the current in the driver coils 34a and 34b with the reversing radial field produced by field coil 18 produces axially additive driver forces. The axial reciprocation of along the direction of arrows X is transferred from coil 34 to spring 112 (FIGS. 2 and 4) and piston 72 (FIG. 3) via plate 58 and fastener 114. It is to be noted that coil 34, preferably, reciprocates at a rate of approximately 60 Hz. 
     As piston 72 is reciprocating, gas goes into chamber 57 (FIG. 3). The gas enters chamber 61 (FIG. 3) and is passed through holes 60 in plate 58. The gas enters through hollow piston 72. As piston 72 reciprocates towards chamber 61 along the one direction of arrow Y, gas enters compression chamber 78 through diaphragm 76. As piston 72 reciprocates towards exhaust valve 80 along the other direction of arrow Y, the pressure of the gas can rise up to 300 psi and reach temperatures exceeding 500 K. The high pressure, high temperature gas then is exhausted out of compression chamber 78 by exhaust valve 80. As piston 72 reaches the end of the stroke inside cylinder head 75, a trapped volume of gas is formed to act as a gas spring and assist in the return of piston 72. 
     In order to detect the proper motion of coil 34, piston 72 and spring 112, windows 106 and displacer sensor 125 are used. The operator can merely look through window 106 to determine if the various elements are reciprocating or flexing. Also, the operator can shine a conventional timing instrument, such as a strobe light to accurately measure the reciprocation rate. Finally, the operator can observe measurements from sensor 125 on a conventional display (not shown) in order to determine the reciprocation rate of piston 72. The procedure is designed to be continuous for approximately 10 10  cycles or approximately 5 years of operation at 60 Hz. 
     Once given the above disclosure, many other features, modifications and improvements will become apparent to the skilled artisan. Such features, modifications and improvements are, therefore, considered to be a part of this invention, the scope of which is to be determined by the following claims.