The present invention relates to fluid machinery, and more specifically to unloader assemblies for compressors.
Compressors for pressurizing or compressing fluids are known and are typically of either the rotary or reciprocating types. A reciprocating compressor basically includes a body or cylinder defining a compression chamber and a piston movably disposed within the cylinder chamber. With this structure, linear reciprocating displacement of the piston within the chamber compresses gas (commonly referred to as “process” fluid or gas) located within the chamber, which is subsequently discharged at the increased pressure.
To better control the maximum pressure in the compressor and/or the output rate of the compressed process gas, reciprocating compressors are often provided with an unloader assembly or unloader that provides a fixed volume chamber removably connectable with compression chamber. A valve assembly controls the flow between the compression and unloader chambers and determines when process fluid is able to move between the two chambers and alternatively when the chambers are sealed or isolated from each other.
In one aspect, the present invention is a closing element for a valve assembly of a compressor unloader, the compressor including a casing and a compression chamber defined within the casing and the unloader includes a housing defining a fixed volume chamber. The valve assembly has a base disposed generally between the compression and unloader chambers, a passage extending through the base and fluidly connecting the two chambers, a seat defined about a section of the passage, and a stem bore defined within the base and having a control chamber section and a central axis. The valve closing element comprises a generally cylindrical main body movably disposed at least partially within the stem bore so as to be displaceable generally along the bore axis. The main body has a sealing end surface, the sealing surface being disposeable against the valve seating surface so as to substantially obstruct the valve passage, and an opposing control end surface disposed within the bore control chamber section. A sealing member is disposed generally about the main body and is located generally between the sealing and control surfaces, the sealing member being configured to substantially prevent fluid flow between the control chamber section and the valve passage through the stem bore. At least one of the cylindrical main body and the sealing member is configured such that the main body is generally radially moveable with respect to the bore axis to at least generally align the main body sealing surface with the valve seat.
In another aspect, the present invention is a valve assembly for a compressor unloader, the compressor including a casing and a compression chamber defined within the casing and the unloader including a housing defining a fixed volume chamber. The valve assembly comprises a base disposed generally between the compression and unloader chambers, the base having a plurality of passages extending through the base and fluidly connecting the compression and unloader chambers, a plurality of valve seats each defined about a section of a separate one the passages, and plurality of stem bores each defined within the base proximal to a separate one of the passages and each having a control chamber section and a central axis. A plurality of valve closing elements are disposed within each stem bore, each closing element including a generally cylindrical main body movably disposed at least partially within the stem bore so as to be displaceable generally along the bore axis. The main body has a sealing end surface disposeable against the valve seating surface so as to substantially obstruct the valve passage, and an opposing control end surface disposed within the bore control chamber section. Further, a sealing member is disposed generally about each closing element main body and is located generally between the sealing and control surfaces. Each sealing member is configured to substantially prevent fluid flow between the control chamber section and the valve passage through the stem bore. Furthermore, the cylindrical main body and/or the sealing member is configured such that the main body is generally radially moveable with respect to the bore axis to at least generally align the main body sealing surface with the valve seat.
In a further aspect, the present invention is a compressor assembly comprising a compressor including a casing, a compression chamber defined within the casing, and a compression member movably disposed within the chamber. An unloader is mounted to the casing and includes a housing defining a fixed volume chamber fluidly connectable with the compression chamber. A valve assembly is configured to control flow between the compression chamber and the unloader chamber and includes a base disposed generally between the compression and unloader chambers. The base includes a passage extending through the base and fluidly connecting the two chambers, a seat defined about a section of the passage, and a stem bore defined within the base and having a control chamber section and a central axis. Further, a valve closing element includes a generally cylindrical main body movably disposed at least partially within the stem bore so as to be displaceable generally along the bore axis and a sealing member disposed generally about the main body. The main body has a sealing end surface disposeable against the valve seating surface so as to substantially obstruct the valve passage and an opposing control end surface disposed within the bore control chamber section. Furthermore, the sealing member is configured to substantially prevent fluid flow between the control chamber section and the fluid passage. At least one of the cylindrical main body and the sealing member is configured such that the main body is generally radially moveable with respect to the bore axis to at least generally align the main body sealing surface with the valve seat.
The foregoing summary, as well as the detailed description of the preferred embodiments of the present invention, will be better understood when read in conjunction with the appended drawings. For the purpose of illustrating the invention, there is shown in the drawings, which are diagrammatic, embodiments that are presently preferred. It should be understood, however, that the present invention is not limited to the precise arrangements and instrumentalities shown. In the drawings:
Certain terminology is used in the following description for convenience only and is not limiting. The words “upper”, “upward”, “down” and “downward” designate directions in the drawings to which reference is made. The words “inner”, “inwardly” and “outer”, “outwardly” refer to directions toward and away from, respectively, a designated centerline or a geometric center of an element being described, the particular meaning being readily apparent from the context of the description. Further, as used herein, the word “connected” is intended to include direct connections between two members without any other members interposed therebetween and indirect connections between members in which one or more other members are interposed therebetween. The terminology includes the words specifically mentioned above, derivatives thereof, and words of similar import.
Referring now to the drawings in detail, wherein like numbers are used to indicate like elements throughout, there is shown in
More specifically, the closing element main body 24 is displaceable with respect to the associated stem bore 20 (i.e., along the bore axis 20a) between a closed position pC (
Further, the one or more sealing member(s) 26 of each closing element 12 is configured to substantially prevent fluid flow between the control chamber section 22 and the valve fluid passage 16 through the associated stem bore 20, i.e., through any space between the main body 24 and the stem bore 20. Specifically, each sealing member 26 has an outer circumferential sealing surface 27 disposeable against or engageable with the stem bore 20 so as to prevent fluid flow between the stem bore chamber section 22 and the associated valve passage 16. Furthermore, the sealing member(s) 26 are each configured such that at least a portion of the outer circumferential sealing surface 27 remains disposed against/engaged with the stem bore 20 as the main body 24 displaces between the closed and open positions pC, pO. Preferably, each closing element 12 includes a single sealing member 26 (e.g., formed as a tube, sleeve, ring, etc.) having an axial length LS (
Referring particularly to
More specifically, the cylindrical main body 24 (and thus also the sealing member 26) of each closing element 12 is displaceable in first and second, opposing directions D1, D2 along the stem bore axis 20a generally toward the associated valve seat 18. The main body 24 and/or the sealing member 26 are/is configured such that when the sealing surface 28 is misaligned with the valve seat 18 (i.e., axes 24a, 18a being spaced radially apart), contact between a radially-outermost portion 28a (
Referring to
Furthermore, the main body 24 preferably has at least one and most preferably two second, radially-larger outer circumferential surfaces 38A, 38B each having an outside diameter ODM2 greater than the diameter ODM1 “first” or radially-smaller outer surface 32, and preferably larger than the sealing member inner surface inside diameter IDS, for reasons described below. The outside diameter ODS of the sealing member outer surface 27 (i.e., which is engaged with the bore surface 21) is sufficiently larger/greater than the outside diameter ODM2 of each main body second outer surface 38A, 38B such that “outer” clearance spaces SCO1, SCO2 are each defined between the bore inner surface 21 and each main body second outer surfaces 38A, 38B, as best shown in
As described in detail above, the capability of radially moving/displacing the closing element main body 24 with respect to the bore axis 20a is preferably provided by forming or sizing both the main body 24 and the sealing member 26 so as to define the generally annular clearance spaces SCI, SCO1, SCO2 between the sealing member 26, the main body 24, and stem bore 20. However, the main body 24 and/or the sealing member 24 may be configured or constructed in any other appropriate manner that enables or permits radial movement of the main body 24 within the bore 20. For example, the sealing member 26 may be coupled to the main body 24 without any substantial clearance and be formed so as to be radially deflectable or compressible, or formed/provided with a radially deflectable/moveable portion. As such, the main body 24 is radially displaceable with respect to the bore axis 20a by deflection, compression, or displacement of the sealing member 26. The scope of the present invention encompasses these and all other structures of the main body 24 and sealing member 26 that enable radial movement and other functioning of the valve closing element 12 as generally described herein.
Referring to
Further, the two radially-larger outer surfaces 38A, 38B are spaced axially apart and are each located generally proximal to a separate body end surface 28, 30, respectively, and the radially smaller outer surface 32 is disposed generally axially between the two larger outer surfaces 38A, 38B. As such, a generally annular recess 42 is defined generally between the radially larger outer surfaces 38A, 38B, which is configured to receive a portion of the sealing member 26 so as to couple the sealing member 26 to the main body 24. More specifically, the sealing member 26 has opposing axial ends 26a, 26b and an axial length LS that is preferably slightly lesser (or even substantially equal or slightly greater) than the axial length LM1 of the main body radially-smaller outer surface 32 (see
Referring now to
More specifically, the compressor 1 preferably further has an inlet 7 and an outlet 8 (see
Referring particularly to
With the above-described structure, the valve assembly 10 of the present invention functions generally as follows. As the preferred piston 4 displaces within the compressor casing 3 to pressurize or compress fluid, e.g., process gas, located within the compressor chamber CC, the pressure within the chamber section cV1, cV2 (discussed below) to which the unloader chamber is fluidly connectable (i.e., through the valve 10) begins to increase. At some point in the piston displacement cycle, the pressure PC in the compressor chamber section CC increases to the point that the pressure PS on the valve sealing end surface 28 of each closing element 12 is greater than the pressure on the pressure PC on the associated control end surface 30. As such, the one or more valve closing elements 12 are displaced toward an open position pO, thereby fluidly coupling the compressor chamber section cV1 or cV2 with the unloader chamber CU. Process fluid flows into the unloader chamber CU through the valve passage(s) 16 until the pressure PS at the closing element sealing surface 28 becomes lesser than the control chamber pressure PC acting on the control end surface 30, at which point the net pressure acting on each closing element main body 24 causes the main body 24 to displace to the closed position pC. At this point, the unloader chamber CU is again isolated or sealed from the compressor chamber CC.
By having the improved closing element(s) 12 of the present invention, leakage of control fluid about each closing element 12 is at least reduced, and preferably substantially prevented. As such, the closing elements 12 are operable with a lesser required control pressure PC acting on the main body 24, as fluid leakage would require a greater control gas pressure PC to accommodate for the fluid loss due to leakage. As such, the closing elements 12 and the required tubing or other components to establish the control fluid line 50 may be used for a greater range of operating conditions and with a variety of different sized compressors 1. Further, by substantially isolating the control fluid from the process gas, a fluid (e.g., nitrogen) different than the process fluid (e.g., natural gas) may be used for the control fluid, such that a completely separate control fluid assembly 54 with a source of control gas (not shown) may be constructed and used to control the unloader valve assembly 10.
Having discussed the basic elements and functions above, these and other features of the valve assembly 10 and the valve closing element 12 of the present invention are described in greater detail below.
Referring to
Further, each unloader hole 9 is located such that a variable volume chamber section cV1 or cV2 of the compressor chamber CC, i.e., each located on an opposing side of the piston 4, is fluidly coupled with each unloader 2 through the one or more passages 16 of the unloader valve assembly 10. The preferred compressor 1 is configured or constructed such that movement of the compression member or piston 4 varies the volume and pressure within each compressor chamber section cV1 or cV2. The control fluid line 50 is configured to fluidly connect the one or more stem bore control chambers 22 with the compressor inlet 7 and/or outlet 8 such that pressure variation within the compressor chamber variable section cV1, cV2 adjusts or varies the pressure PS on both the closing element sealing end surface(s) 28 and the pressure PC on the control end surface(s) 30. Such pressure variations displace each closing element 12 between the closed and open positions pC, pO, as discussed above.
Referring now to
Referring now to
Further, the cylindrical valve base body 80 also includes a plurality of bore holes 88 axially aligned with a separate one of the second valve passage holes 84 and having a first end 88a fluidly connected with at least one connective passage 86 and an opposing second end 88a. Each body bore hole 88 provides a separate one of the stem bores 20 and as such, are sized to receive a separate one of the closing elements 12 such that a control chamber section 22 is defined between the closing element main body 24 and the body bore hole second end 88b. Furthermore, a plurality of control ports 90 extending generally into the control chamber section 22 of a separate one of the stem bore holes 88 and a central control fluid hole 92 extends into the valve body 80 from the first end 80a and partially therethrough generally toward the body second end 80b, the control hole 92 being connectable with a source of control pressure, as discussed above. At least one control connective passage 94 extends generally radially within the valve body 80 and fluidly connects the control hole 92 with one or more of the control ports 90, thereby fluidly connecting the control pressure source, i.e., the inlet 7 and/or outlet 8 or separate source (none shown), with each of the stem bore control chamber sections 20.
Most preferably, the above-discussed cylindrical valve base body 80 is formed of an assembly of three connected-together, generally circular plates 100, 102, 104. Specifically, a first or outer plate 100 has an outer axial end 100a providing the valve body first end 80a, an opposing inner axial end 100b, a plurality of through holes 106 each providing an outer section of a separate one of the first valve passage holes 82, and a central through bore providing the control fluid hole 92. A second or middle plate 102 has first and second opposing axial ends 102a, 102b, the middle plate first end 102a being disposed against the outer plate inner end 100a, a plurality of through holes 108 each providing an inner section of a separate one of the first valve passage holes 82 and a plurality of counterbore holes 110 each providing a separate one of the stem bore holes 20 and the connected control ports 90. A plurality of radially-extending recesses 112 each extend into the second plate 102 from the plate first end 102a and are each connected with at least one control port 90 and provide one control connective passage 94. Further, a generally annular recess 114 extends into the middle plate 102 from the plate second end 102b and provides a common connective passage 86 for all the valve passages 14. Furthermore, a third or inner plate 104 has an outer axial end 104b providing the valve body second end 80b, an opposing inner axial end 104a disposed against the middle plate second end 102b and a plurality of through holes 116 each providing a separate one of the second valve passage holes 84.
Referring to
Referring now to
It will be appreciated by those skilled in the art that changes could be made to the embodiments described above without departing from the broad inventive concept thereof. It is understood, therefore, that this invention is not limited to the particular embodiments disclosed, but it is intended to cover modifications within the spirit and scope of the present invention as generally defined in the appended claims.
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/US2007/008149 | 4/2/2007 | WO | 00 | 10/30/2008 |
Publishing Document | Publishing Date | Country | Kind |
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WO2007/120506 | 10/25/2007 | WO | A |
Number | Name | Date | Kind |
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7270145 | Koezler | Sep 2007 | B2 |
20020141884 | Sperry | Oct 2002 | A1 |
20040007261 | Cornwell | Jan 2004 | A1 |
Number | Date | Country |
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2323639 | Sep 1998 | GB |
Number | Date | Country | |
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20090238699 A1 | Sep 2009 | US |
Number | Date | Country | |
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60787952 | Mar 2006 | US |