This invention relates in general to valves for controlling fluid flow. In particular, this invention relates to an improved structure for two-stage proportional control valve for use in a fluid system, such as a heating, ventilating, air conditioning, and refrigeration (HVAC-R) system.
One known two-stage proportional control valve is an expansion valve, such as a Modular Silicon Expansion Valve (MSEV). MSEVs are electronically controlled, normally closed, and single flow directional valves. MSEVs may be used for refrigerant mass flow control in conventional HVAC-R applications.
The first stage of the MSEV is a microvalve that acts as a pilot valve to control a second stage spool valve. When the microvalve receives a Pulse Width Modulation (PWM) signal, the microvalve modulates to change a pressure differential across the second stage spool valve. The spool valve will move to balance the pressure differential, effectively changing an orifice opening of the MSEV to control the flow of refrigerant.
There are however, undesirable manufacturing processes associated with known MSEVs. For example, the final machining steps necessary to ensure a required spool bore diameter in a valve body of the MSEV may only be accomplished after fluid inlet and fluid outlet connector tubes and capillary tubes have been brazed to the valve body. This sequence is required because bores machined into the valve body may become distorted by as much as about 30 μm by the heat used in the brazing operation. A typical machined spool bore in an MSEV valve body has a diameter tolerance of about +/−5 μm, and the brazing operation may cause the machined spool bore to become out of tolerance if the brazing operation is performed after the spool bore has been machined. Therefore, components such as the fluid inlet and fluid outlet connector tubes and the capillary tubes are commonly brazed to the valve body prior to the final machining steps. Because components such as the fluid inlet and fluid outlet connector tubes and the capillary tubes are brazed to the valve body prior to the final machining steps, fixtures and tools used to assemble the MSEV may be complex and costly, and manufacturing time may be undesirably lengthy.
MEMS (Micro Electro Mechanical Systems) are a class of systems that are physically small, having features with sizes in the micrometer range; i.e., about 10 μm or smaller. These systems have both electrical and mechanical components. The term “micromachining” is commonly understood to mean the production of three-dimensional structures and moving parts of MEMS devices. MEMS originally used modified integrated circuit (computer chip) fabrication techniques (such as chemical etching) and materials (such as silicon semiconductor material) to micromachine these very small mechanical devices. Today, there are many more micromachining techniques and materials available.
The term “micromachined device” as used in this application means a device having some features with sizes of about 10 μm or smaller, and thus by definition is at least partially formed by micromachining. More particularly, the term “microvalve” as used in this application means a valve having features with sizes of about 10 μm or smaller, and thus by definition is at least partially formed by micromachining. The term “microvalve device” as used in this application means a micromachined device that includes a microvalve, and that may include other components. It should be noted that if components other than a microvalve are included in the microvalve device, these other components may be micromachined components or standard sized (larger) components. Similarly, a micromachined device may include both micromachined components and standard sized (larger) components.
Various microvalve devices have been proposed for controlling fluid flow within a fluid circuit. A typical microvalve device includes a displaceable member or valve component movably supported by a body for movement between a closed position and a fully open position. When placed in the closed position, the valve component substantially blocks or closes a first fluid port that is otherwise in fluid communication with a second fluid port, thereby substantially preventing fluid from flowing between the fluid ports. Known microvalves thus allow some fluid to leak through a closed valve port, thus substantially preventing, but not completely preventing, fluid flow therethrough. When the valve component moves from the closed position to the fully open position, fluid is increasingly allowed to flow between the fluid ports.
U.S. Pat. Nos. 6,523,560; 6,540,203; and 6,845,962, the disclosures of which are incorporated herein by reference, describe microvalves made of multiple layers of material. The multiple layers are micromachined and bonded together to form a microvalve body and the various microvalve components contained therein, including an intermediate mechanical layer containing the movable parts of the microvalve. The movable parts are formed by removing material from an intermediate mechanical layer (by known micromachined device fabrication techniques, such as, but not limited to, Deep Reactive Ion Etching) to create a movable valve element that remains attached to the rest of the part by a spring-like member. Typically, the material is removed by creating a pattern of slots through the material to achieve the desired shape. The movable valve element will then be able to move in one or more directions an amount roughly equal to the slot width.
U.S. Pat. No. 7,156,365, the disclosure of which is also incorporated herein by reference, describes a method of controlling the actuator of a microvalve. In the disclosed method, a controller supplies an initial voltage to the actuator which is effective to actuate the microvalve. Then, the controller provides a pulsed voltage to the actuator which is effective to continue the actuation of the microvalve.
Because of the undesirable processes associated with manufacturing known two-stage proportional control valves, it would be desirable to provide an improved structure for a two-stage proportional control valve that is easier to manufacture, and in which the final machining steps necessary to manufacture the valve body may be accomplished before components such as the fluid inlet and fluid outlet connector tubes and the capillary tubes must been brazed thereto.
This invention relates to an improved structure for a two-stage proportional control valve for use in a fluid system, such as an HVAC-R system. In one embodiment, the two-stage proportional control valve configured for use in a fluid system includes a valve body having a longitudinally extending valve body bore formed therethrough. A first stage microvalve is mounted within the valve body bore, and a second stage spool assembly is mounted within the valve body bore downstream of the microvalve. The second stage spool assembly includes a sleeve and a spool slidably mounted within the sleeve.
In a second embodiment, a spool assembly configured for use in a two-stage proportional control valve in a fluid system includes a sleeve. The sleeve is substantially cylindrical and includes an axially extending sleeve bore formed therein and extending from an open first end to an open second end of the sleeve. A spool includes a spool bore extending axially from an open first end to a closed second end and slidably mounted within the sleeve bore.
In a third embodiment, a method of assembling a two-stage proportional control valve configured for use in a fluid system includes slidably mounting a spool within a sleeve to define a spool valve assembly. The spool valve assembly is mounted in a longitudinally extending valve body bore formed through a valve body of the two-stage proportional control valve. A first stage microvalve is also mounted within the valve body bore. The spool valve assembly defines a second stage spool assembly of the two-stage proportional control valve and is mounted within the valve body bore downstream of the microvalve.
Various aspects of this invention will become apparent to those skilled in the art from the following detailed description of the preferred embodiments, when read in light of the accompanying drawings.
Referring now to the drawings, there is illustrated in
As is well known in the art, the refrigeration system 10 circulates a refrigerant through a closed circuit, where it is sequentially subjected to compression, condensation, expansion, and evaporation. The circulating refrigerant removes heat from one area (thereby cooling that area) and expels the heat in another area.
To accomplish this, the illustrated refrigeration system 10 includes an evaporator 11, such as an evaporator coil. The evaporator 11 is conventional in the art and is adapted to receive a relatively low pressure liquid refrigerant at an inlet thereof. A relatively warm fluid, such as air, may be caused to flow over the evaporator 11, causing the relatively low pressure liquid refrigerant flowing in the evaporator 11 to expand, absorb heat from the fluid flowing over the evaporator 11, and evaporate within the evaporator 11. The relatively low pressure liquid refrigerant entering into the inlet of the evaporator 11 is thus changed to a relatively low pressure refrigerant gas exiting from an outlet of the evaporator 11.
The outlet of the evaporator 11 communicates with an inlet of a compressor 12. The compressor 12 is conventional in the art and is adapted to compress the relatively low pressure refrigerant gas exiting from the evaporator 12 and to move such relatively low pressure refrigerant gas through the refrigeration system 10 at a relatively high pressure. The relatively high pressure refrigerant gas is discharged from an outlet of the compressor 12 that communicates with an inlet of a condenser 13. The condenser 13 is conventional in the art and is configured to remove heat from the relatively high pressure refrigerant gas as it passes therethrough. As a result, the relatively high pressure refrigerant gas condenses and becomes a relatively high pressure refrigerant liquid.
The relatively high pressure refrigerant liquid then moves from an outlet of the condenser 13 to an inlet of an expansion device 14. In the illustrated embodiment, the expansion device 14 is a hybrid spool valve that is configured to restrict the flow of fluid therethrough. As a result, the relatively high pressure refrigerant liquid is changed to a relatively low pressure refrigerant liquid as it leaves the expansion device. The relatively low pressure refrigerant liquid is then returned to the inlet of the evaporator 11, and the refrigeration cycle is repeated.
The illustrated refrigeration system 10 additionally may include a conventional external sensor 15 that communicates with the fluid line that provides fluid communication from the evaporator 11 to the compressor 12. The external sensor 15 is responsive to one or more properties of the fluid (such as, for example, pressure, temperature, and the like) in such fluid line for generating a signal that is representative of that or those properties to a controller 16. In response to the signal from the external sensor 15 (and, if desired, other non-illustrated sensors or other inputs), the controller 16 generates a signal to control the operation of the expansion device 14. If desired, the external sensor 15 and the controller 16 may be embodied together as a conventional universal superheat sensor-controller, such as is commercially available from DunAn Microstaq, Inc. of Austin, Tex. U.S. Pat. No. 9,140,613 to Arunasalam et al. describes superheat sensors, controllers, and processors, and their operation. The disclosure of U.S. Pat. No. 9,140,613 is incorporated herein by reference.
Referring now to
An opening 56 (see
The microvalve assembly 64 may be made leak-tight by a metal to metal interference seal S1 defined between the annular sealing ridge 69 and the annular sealing groove 53a, and one or more annular seals, such as O-rings 70 and 72. Similarly, the second plug 68 may be made leak tight by a metal to metal interference seal S2 defined between an outside surface of the second plug 68 and a shoulder 63 formed in the spool assembly bore 62. The second plug 68 may be further made leak tight by an O-ring 73. It will be understood however, that the metal interference seal S2 may be sufficient to seal the second plug 68 within the spool assembly bore 62, and the O-ring 73 may not be required. An electrical connector 74 extends outwardly from an outside axial end of the microvalve assembly 64. A microvalve 76 may be mounted to an inboard axial end of the microvalve assembly 64 (the lower end of the microvalve assembly 64 when viewing
Electrical connectors, such as posts or pins 78, extend between a cavity 65 formed in the first end 64a of the microvalve assembly 64 and a second end 64b of the microvalve assembly 64. First electrical connectors, such as wires 83, electrically connect the pins 78 to a source of electrical power (not shown) via the electrical connector 74. Second electrical connectors, such as wires 84 electrically connect the microvalve 76 to the pins 78 at the second end 64b of the microvalve assembly 64.
A substantially cup-shaped cap 80 is attached to an outside surface of the microvalve assembly 64 at a second end 64b thereof. The cap 80 has a substantially cylindrical outer surface and includes an opening 81 in an end wall thereof that defines a flow path for fluid between the microvalve 76 and the spool assembly bore 62. An interior of the cap 80 defines a cavity 82 within which the microvalve 76 is mounted. The illustrated cap 80 is preferably formed from glass filled nylon. Alternatively, the cap 80 may be formed from any desired polymer or other material.
Referring to
The valve body 52 further includes a transversely extending fluid inlet port 88 and a transversely extending fluid outlet port 90 in fluid communication with the spool assembly bore 62 via the fluid flow grooves 85 and 86, respectively. As shown in
As shown in
Referring to
The conventional MSEV 14 illustrated in
The spool bore 26 also includes a circumferentially extending first groove defining a fluid inlet chamber 28, and a circumferentially extending second groove defining a fluid outlet chamber 30.
The valve body 20 further includes a transversely extending inlet port 32 and a transversely extending outlet port 34. The inlet port 32 is in fluid communication with the condenser 13 via an inlet connector conduit 36. The outlet port 34 is in fluid communication with the evaporator 11 via an outlet connector conduit 38.
Capillary tubes 40 extend between the inlet and outlet ports 32 and 34 and fluid flow conduits (not shown) formed in the microvalve assembly 64. These fluid flow conduits supply fluid to the first stage microvalve (not shown). The joints between the capillary tubes 40 and the valve body 20 are typically brazed joints and are shown at B1 in
When manufacturing the conventional MSEV 14, the valve body 20, the capillary tubes 40, and the inlet and outlet connector conduits 36 and 38 are first assembled and brazed as shown in
Referring to
A first circumferentially extending groove 120 is formed on an outside surface of the spool 110 intermediate the first and second ends 110a and 110b. The circumferentially extending groove 120 defines a fluid flow path. A second circumferentially extending groove 122 is formed on an outside surface of the spool 110 near the first end 110a thereof, and a third circumferentially extending groove 124 is formed on an outside surface of the spool 110 near the second end 110b thereof. A circumferentially extending pressure groove 126 is also formed on an outside surface of the spool 110 between the second axial end 110b and the third circumferentially extending groove 124.
A first transverse fluid passageway 128 is formed through a side wall of the spool 110 between the bore 114 and the second circumferentially extending groove 122, and a second transverse fluid passageway 130 is formed through a side wall of the spool 110 between the bore 114 and the third circumferentially extending groove 124. A third transverse fluid passageway 132 is formed through a side wall of the spool 110 between the bore 114 and the circumferentially extending pressure groove 126.
The sleeve 112 is substantially cylindrical and includes an axially extending spool bore 134 formed therein and extending from an open first end 112a to an open second end 112b of the sleeve 112.
A first circumferentially extending sealing portion 136 is formed on an outside surface of the sleeve 112 and defines a first circumferentially extending sealing groove 136a. A second circumferentially extending sealing portion 138 is also formed on an outside surface of the sleeve 112 and defines a second circumferentially extending sealing groove 138a. Additionally, a third circumferentially extending sealing portion 140 is formed on an outside surface of the sleeve 112 and defines a third circumferentially extending sealing groove 140a.
A first annular seal 142a, such as an O-ring, may be disposed within the first circumferentially extending sealing groove 136a. Similarly, second and third annular seals 142b and 142c, such as O-rings, may be disposed within the second and third circumferentially extending sealing groove 138a and 140a, respectively.
A circumferentially extending inlet fluid flow groove 144 is defined in the outside surface of the sleeve 112 between the second and third sealing portions 138 and 140. Similarly, a circumferentially extending outlet fluid flow groove 146 is defined in the outside surface of the sleeve 112 between the first and second sealing portions 136 and 138.
At least one main fluid flow inlet passageway 148 is formed through a side wall of the sleeve 112 between the bore 134 and the inlet fluid flow groove 144, and at least one main fluid flow outlet passageway 150 is formed through the side wall of the sleeve 112 between the bore 134 and the outlet fluid flow groove 146. Additionally, at least one feedback flow inlet passageway 152 is formed through the side wall of the sleeve 112 between the bore 134 and the inlet fluid flow groove 144, and at least one feedback flow outlet passageway 154 is formed through the side wall of the sleeve 112 between the bore 134 and the outlet fluid flow groove 146.
A first cap cavity 156 is formed in the first end 112a of the sleeve 112 and a second cap cavity 158 is formed in the second end 112b of the sleeve 112. A closure member or cap 160 is mounted within each of the first and second cap cavities 156 and 158, and may be attached therein by any desired means, such as by threaded attachment, staking, or by welding. The cap 160 may include one or more fluid passageways 162 (see
In operation, when it is desired to operate the spool assembly 66 and move fluid therethrough, the microvalve 76 may be actuated. The fluid discharged from the microvalve 76 controls a command pressure on the second end 110b of the spool 110. The command pressure acting on the second end 110b of the spool 110 urges the spool 110 against the force of the spring 164 (downward when viewing
Thus, when actuated, the microvalve 76 causes the spool 110 to move from the closed position to a fully actuated or fully open position as shown in
The circumferentially extending pressure groove 126 and the fluid passageway 132 are in fluid communication with the bore 114 and are configured to isolate the command chamber 166 from fluid that may leak around the spool 110 (i.e., from the right of the pressure groove 126 when viewing
During manufacture and assembly of the MSEV 50, the spool assembly bore 62 may be machined in the valve body 52 prior to the capillary tubes 40 and the inlet and outlet connector conduits 36 and 38 being brazed to the valve body 52.
The spool 110, the sleeve 112, and the caps 160 may be formed and assembled to define the spool assembly 66 independently of the valve body 52. The piston bore 134 may thus be machined having a diameter tolerance of about +/−5 μm, without being negatively affected by heat from the brazing operation on the valve body 52. Once assembled, the spool assembly 66 may then be mounted within the spool assembly bore 62.
The spool assembly bore 62 in the valve body 52 is configured to receive, and have fixedly mounted therein, the spool sleeve 112 rather than the slidable spool 110, as in the conventional MSEV 14. Because the spool assembly 66 may be sealed within the spool assembly bore 62 by the metal to metal interference seal S1, and by the O-rings 142a, 142b, and 142c, the diameter tolerance for the spool assembly bore 62 may relatively larger than the tolerance for the spool bore 26 in the conventional valve body 20, such as about +/−50 μm.
Thus, the spool assembly bore 62 may be machined prior to brazing, and therefore the capillary tubes 40 and the inlet and outlet connector conduits 36 and 38 may be thereafter brazed without causing the spool assembly bore 62 to become out of tolerance. The relatively small tolerance of about +/−5 μm between the spool 110 and the sleeve 112 in the spool assembly 66 may also be achieved and maintained in a manufacturing process independent of, and at a location separate from, the machining and brazing steps required to manufacture and assemble the valve body 52.
Because the spool 110 is enclosed within the sleeve 112 by the caps 160, the spool assembly 66 may be easily and safely moved, and may be easily tested independently and separately from the valve body 52 of the MSEV 50, thus saving time and reducing cost.
The principle and mode of operation of this invention have been explained and illustrated in its preferred embodiments. However, it must be understood that this invention may be practiced otherwise than as specifically explained and illustrated without departing from its spirit or scope.
Number | Date | Country | |
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62290489 | Feb 2016 | US |
Number | Date | Country | |
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Parent | 15399792 | Jan 2017 | US |
Child | 16184620 | US |