The present invention relates, in general, to a distributor expansion valve of a heat pump system, and in particular, to a distributor expansion valve having a radial mixing chamber wherein the hot gas inlet to the chamber is offset from axial centerline of the valve to promote mixing of hot gas and liquid entering the radial mixing chamber.
A heat pump system can be used to control the temperature of a certain medium such as, for example, the air inside of a building. A heat pump system generally comprises an evaporator, a condenser, a compressor and a series of lines (e.g., pipes, tubes, ducts) connecting these components together so that a refrigerant fluid can cycle therethrough. Typically, the evaporator is located adjacent to or within the medium (e.g., it is located inside the building) and the condenser is located remote from the medium (e.g., it is located outside of the building).
A heat pump system can operate in a first (forward) direction, wherein it cools the temperature-controlled environment, and a second (reverse) direction, wherein it heats the temperature-controlled environment. In the forward (i.e., cooling) direction, the evaporator is the heat-absorbing component (i.e., it absorbs heat from, and thus cools, the medium) and the condenser is the heat-rejecting component (i.e., it rejects the absorbed heat to the remote location). In the reverse (i.e., heating) direction, the evaporator is the heat-rejecting component and the condenser is the heat-absorbing component.
In a heat pump cycle, refrigerant fluid enters the heat-absorbing component as a low pressure and low-temperature vapor-liquid. As the vapor-liquid passes through the heat-absorbing component, it is boiled into a low pressure gas state. From the heat-absorbing component, the fluid passes through the compressor, which increases the pressure and temperature of the gas. From the compressor, the high pressure and high temperature gas passes through the heat-rejecting component whereat it is condensed to a liquid.
A heat pump system will often include an expansion valve immediately (or almost immediately) upstream of the heat-absorbing component. When the high pressure and high temperature liquid from heat-rejecting component passes through the expansion valve, the pressure of the fluid is reduced (e.g., the expansion valve throttles the fluid) and fluid is converted to a low pressure and low temperature vapor/liquid state. This low pressure and low temperature vapor/liquid is received by the heat-absorbing component to complete the cycle.
A heat pump cycle will often also include a distributor downstream of the expansion valve. A distributor commonly includes a mixing compartment whereat fluid is evenly distributed to a plurality of tubes which feed the multiple circuits of the heat-absorbing component. A distributor can also include a flow restriction (e.g., a nozzle) upstream of its mixing compartment which increases the velocity of the fluid just prior to its entry into the mixing compartment to promote a turbulent mixing of liquid and vapor phases.
As was indicated above, when a heat pump system is operating in a first (i.e., forward and/or cooling) direction, the evaporator is the heat-absorbing component, and when it is operating in a second (i.e., reverse and/or heating) direction, the condenser is the heat-absorbing component. Thus, an expansion-distribution assembly may be positioned at the end of the evaporator which is its inlet when fluid travels in the first direction and/or may be positioned at the end of the condenser, which is its inlet when fluid travels in the second direction.
When a heat pump system is operating in a direction corresponding to the expand-then-distribute direction, liquid (at a high pressure and high temperature) will pass through the expansion-distribution assembly and will be converted into a vapor/liquid (at a lower pressure and a lower temperature) for receipt by the heat-absorbing component. When the heat pump system is operating in the opposite direction, fluid passes “backwards” through the expansion-distribution assembly. A reverse flow bypass is provided so that the fluid does not have to pass (backwards) through the throttling flow path.
The problem with certain applications, for example an environmental chamber, is that there is a need for the system to run at a nominal capacity rating for one set-point and a lower capacity rating for another set-point. With this two-staged system, the expansion valve, distributor and nozzle are sized for the first set-point to allow maximum capacity. When the system is required to run at the second set-point, for instance low load conditions, the existing expansion valve, distributor, and nozzle become grossly oversized. During operation at low load, refrigerant velocities become very low and distribution of the refrigerant suffers. Oil logging in the coil may also become an issue due to the low refrigerant velocities. The logged oil, in return, reduces heat transfer and compounds the distribution issues.
One current prior art solution would be to run parallel liquid lines with separate distributors and nozzles matched for each set-point. Solenoid valves would control which liquid line to use. However, this solution is complicated and expensive.
At least one embodiment of the invention provides an expansion valve assembly comprising: a distributor body having a liquid inlet, a port having a selectively moveable pin to allow liquid from the liquid inlet past the port, a gas inlet, a mixing chamber, and a plurality of circuits; wherein the mixing chamber is positioned between the port and the plurality of circuits, the mixing chamber having an axial centerline that is the axial centerline of the valve; wherein the gas inlet has an axial centerline that is offset from the axial centerline of the mixing chamber.
At least one embodiment of the invention provides an expansion valve assembly comprising: a distributor body having a liquid inlet, a port having a selectively moveable pin to allow liquid from the liquid inlet past the port, a gas inlet, a mixing chamber, and a plurality of circuits; wherein the mixing chamber is positioned between the port and the plurality of circuits, the mixing chamber having an axial centerline that is the axial centerline of the valve; wherein the gas inlet has an axial centerline that is offset and perpendicular to a radial centerline of the mixing chamber; wherein a wall of the gas inlet is generally tangentially oriented with the wall of the radial mixing chamber.
At least one embodiment of the invention provides an expansion valve assembly comprising a distributor body having a liquid inlet, a port having a selectively moveable pin to allow liquid from the liquid inlet past the port, a gas inlet, a mixing chamber, and a plurality of circuits; wherein the mixing chamber is positioned between the port and the plurality of circuits, the mixing chamber having an axial centerline that is the axial centerline of the valve; wherein the port extends into the mixing chamber forming an annular interior wall of the mixing chamber; wherein the gas inlet has an axial centerline that is offset from the axial centerline of the mixing chamber; wherein the axial end of the mixing chamber is blended radially inward toward an axial inlet to the plurality of circuits.
Embodiments of this invention will now be described in further detail with reference to the accompanying drawings, in which:
The present invention relates to U.S. patent application Ser. No. 11/739,069, filed Apr. 23, 2007, and herein incorporated by reference. The referenced application is a device that combines a stepper motor actuator into a distributor body to provide proper system pressure drop and variable orifice control of refrigerant entering the evaporating coil via circuit tubes.
Referring now to
Referring now to
The amount of hot gas flow entering the mixing chamber 32 can be mechanically or electronically controlled separately in response to system conditions. It is advantageous to flow hot gas at low load conditions into the chamber 32 to properly mix low velocity two-phase refrigerant leaving the port 34. This addition of hot gas at low flow provides proper refrigerant mixing, helps maintain high refrigerant velocities for proper distribution and may also aid in reducing the potential of oil logging in the refrigerant coil. It is also contemplated that a properly sized nozzle 52 can be inserted into the hot gas tube at the entrance to the mixing chamber to accelerate the hot gas as it enters the mixing chamber 32, as best shown in
As best shown in
Referring to the problem of the prior art discussed in the Background, the proposed invention would provide one component to operate and meet all demands, assuming the component is sized to meet maximum capacity. Hot gas from the discharge line could be supplied to the proposed invention at low load operation. This, in turn, would provide rapid mixing of low velocity two-phase refrigerant inside the “radial mixing chamber”. Increased homogenous refrigerant velocities help feed each coil circuit with the same amount of refrigerant for improved distribution. Oil logging would also be reduced or eliminated due to the increase of refrigerant velocity. The compressors would also remain loaded to avoid “short cycling” or hard starts.
Although the principles, embodiments and operation of the present invention have been described in detail herein, this is not to be construed as being limited to the particular illustrative forms disclosed. They will thus become apparent to those skilled in the art that various modifications of the embodiments herein can be made without departing from the spirit or scope of the invention.
The present application claims the benefit of the filing date of U.S. Provisional Patent Application Ser. No. 61/059,902, filed Jun. 9, 2008, the disclosure of which is incorporated herein by reference in its entirety.
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/US2009/046690 | 6/9/2009 | WO | 00 | 3/7/2011 |
Number | Date | Country | |
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61059902 | Jun 2008 | US |