This application is a U.S. National Phase application of PCT Application No. PCT/US2006/047966 filed Dec. 15, 2006.
This application relates to a parallel flow heat exchanger, wherein vapor refrigerant from an upstream location is utilized to provide additional momentum in driving liquid phase refrigerant along a manifold to improve refrigerant distribution among parallel tubes that are in fluid communication with this manifold, and thus enhance the heat exchanger and overall refrigerant system performance.
Refrigerant systems utilize a refrigerant to condition a secondary fluid, such as air, delivered to a climate controlled space. In a basic refrigerant system, the refrigerant is compressed in a compressor, and flows downstream to a condenser, where heat is typically rejected from the refrigerant to ambient environment, during heat transfer interaction with this ambient environment. Then refrigerant flows through an expansion device, where it is expanded to a lower pressure and temperature, and to an evaporator, where during heat transfer interaction with a secondary fluid (e.g., indoor air), the refrigerant is evaporated and typically superheated, while cooling and often dehumidifying this secondary fluid.
In recent years, much interest and design effort has been focused on the efficient operation of the heat exchangers (condenser and evaporator) in the refrigerant systems. One relatively recent advancement in the heat exchanger technology is the development and application of parallel flow, or so-called microchannel or minichannel, heat exchangers (these two terms will be used interchangeably throughout the text), as the condensers and evaporators.
These heat exchangers are provided with a plurality of parallel heat transfer tubes, typically of a non-round shape, among which refrigerant is distributed and flown in a parallel manner. The heat transfer tubes are orientated generally substantially perpendicular to a refrigerant flow direction in the inlet, intermediate and outlet manifolds that are in flow communication with the heat transfer tubes. The primary reasons for the employment of the parallel flow heat exchangers, which usually have aluminum furnace-brazed construction, are related to their superior performance, high degree of compactness, structural rigidity and enhanced resistance to corrosion.
When utilized in condenser applications, these heat exchangers are normally designed for a multi-pass configuration, typically with a plurality of parallel heat transfer tubes within each refrigerant pass, in order to obtain superior performance by balancing and optimizing heat transfer and pressure drop characteristics. In such designs, the refrigerant that enters an inlet manifold (or so-called inlet header) travels through a first multi-tube pass across a width of the condenser to an opposed, typically intermediate, manifold. The refrigerant collected in a first intermediate manifold reverses its direction, is distributed among the heat transfer tubes in the second pass and flows to a second intermediate manifold. This flow pattern can be repeated for a number of times, to achieve optimum condenser performance, until the refrigerant reaches an outlet manifold (or so-called outlet header). Typically, the individual manifolds are of a cylindrical shape (although other shapes are also known in the art) and are represented by different chambers separated by partitions within the same manifold construction assembly.
Heat transfer corrugated and typically louvered fins are placed between the heat transfer tubes for outside heat transfer enhancement and construction rigidity. These fins are typically attached to the heat transfer tubes during a furnace braze operation. Furthermore, each heat transfer tube preferably contains a plurality of relatively small parallel channels for in-tube heat transfer augmentation and structural rigidity.
However, there have been some obstacles to the use of the parallel flow heat exchangers in a refrigerant system. In particular, a problem, known as refrigerant maldistribution, typically occurs in the microchannel heat exchanger manifolds when the two-phase flow enters the manifold. A vapor phase of the two-phase flow has significantly different properties, moves at different velocities and is subjected to different effects of internal and external forces than a liquid phase. This causes the vapor phase to separate from the liquid phase and flow independently. The separation of the vapor phase from the liquid phase has raised challenges, such as refrigerant maldistribution in parallel flow heat exchangers. This phenomenon takes place due to unequal pressure drop inside the channels and in the inlet and outlet manifolds, as well as poor manifold and distribution system design. In the manifolds, the difference in length of refrigerant paths, phase separation and gravity are the primary factors responsible for maldistribution. Inside the heat exchanger channels, variations in the heat transfer rate, airflow distribution, manufacturing tolerances, and gravity are the dominant factors. Furthermore, a recent trend of heat exchanger performance enhancement promoted miniaturization of its channels, which in turn negatively impacted refrigerant distribution. Since it is extremely difficult to control all these factors, along with the complexity and inefficiency of the proposed techniques or prohibitively high cost of the solutions, many of the previous attempts to manage refrigerant distribution, have failed.
On the other hand, refrigerant maldistribution may causes significant heat exchanger and overall system performance degradation over a wide range of operating conditions. Therefore, it would be desirable to reduce or eliminate refrigerant maldistribution in parallel flow heat exchangers.
In a disclosed embodiment of this invention, refrigerant vapor is tapped from an upstream location, and directed into a location in a parallel flow heat exchanger intermediate manifold where two-phase refrigerant flow is present, and a liquid phase is likely to separate from a vapor phase and accumulate, causing refrigerant maldistribution in the downstream heat transfer tubes that are in fluid communication with this intermediate manifold. The refrigerant vapor from an upstream location has a higher velocity and enough momentum to create predominantly homogeneous flow conditions, while mixing, atomizing and redistributing the initially separated two-phase refrigerant in the intermediate manifold.
In one embodiment the vapor refrigerant is tapped from a line connecting a compressor to the parallel flow heat exchanger.
In another embodiment, the predominantly vapor or homogeneous two-phase refrigerant is tapped from a location in an upstream manifold and redirected to a location in a downstream manifold.
In further features, the flow of the refrigerant vapor may be pulsed or periodically modulated to enhance the refrigerant distribution effects. Also, multiple taps may be utilized to tap a portion of refrigerant from the same manifold and redirect it to different downstream manifolds. On the other hand, a portion of refrigerant from different upstream manifolds may be delivered to the same downstream manifold.
Furthermore, the disclosed invention can be implemented in parallel flow heat exchanger installations functioning as condensers as well as evaporators.
These and other features of the present invention can be best understood from the following specification and drawings, the following of which is a brief description.
A basic refrigerant system 20 is illustrated in
As shown in
As shown in the
Since, in many cases, a somewhat insignificant amount of liquid refrigerant is accumulated within the chamber 34A, refrigerant maldistribution does not have a profound effect on the performance of the condenser 24 yet, and no special measures may be required (although, in some cases, special design provisions may be implemented). The refrigerant in the second bank of heat transfer tubes 36 is flowing in generally parallel (although counterflow) direction to the refrigerant flow in the first bank of heat transfer tubes 32. As shown in the
In such circumstances, vapor refrigerant will predominantly flow into the upper portion of the heat transfer tubes of the third pass 38 with liquid refrigerant flowing through the lower portion of the third bank 38 of heat transfer tubes. Therefore, refrigerant maldistribution may have a profound effect on performance of the condenser 24.
The refrigerant flows from the intermediate chamber 30B of the manifold structure 30 into a third bank of parallel heat transfer tubes 38 generally positioned in parallel arrangement to the first and second banks of heat transfer tubes 32 and 36, across the condenser 24 and into an intermediate chamber 34B of the manifold structure 34. The liquid refrigerant level in the manifold chamber 34B, as shown at 244, is even higher than in the chambers 34A and 30B.
The refrigerant flowing through the chamber 34B has even lower vapor quality and potentially creating similar maldistribution conditions for the fourth (and last) bank of heat transfer tubes 40. Again, a separator plate 42 positioned between the chambers 30B and 30C ensures the refrigerant flow in the desired downstream direction without short-circuiting or bypass. From the chamber 30C, the liquid refrigerant exits condenser 24 through the liquid line 25. As known, corrugated, and typically louvered, fins 33 are located between and attached to the heat transfer tubes (typically during a furnace brazing process) to extend the heat transfer surface and improve structural rigidity of the condenser 24.
As shown in
In the present invention, refrigerant is tapped from the discharge line 23 into a line 46 and directed to a location 47, that may or may not be directly associated with the separator plate 42 dividing the chambers 30B and 30C, where a significant amount of accumulated liquid refrigerant 144 is expected (e.g., due to separation under gravity force). This high pressure compressed refrigerant vapor will tend to mix (creating more homogeneous conditions) and redistribute the liquid refrigerant phase amongst the third bank of the heat transfer tubes 38 in more uniform manner.
Similarly, another line 48 may be directed to a location 49, providing favorable conditions for more uniform distribution of the liquid refrigerant phase 244 within the manifold chamber 34B and amongst the forth bank of the heat transfer tubes 40. Valves 50 associated with a control 10 may be placed on the lines 46 and/or 48 to allow the flow of this discharge gas to be pulsed, modulated or completely shutdown. In this manner, a refrigerant system designer can achieve precise control over the desired amount of bypassed high pressure refrigerant vapor, which can be tailored, for instance, to specific operating conditions, to provide uniform distribution of liquid and vapor refrigerant phases amongst the heat transfer tubes.
It should be understood that the liquid levels 35, 144 and 244 may be somewhat exaggerated to illustrate the concept of the present invention as well as may vary with operating and environmental conditions.
Also, as shown in
The multiple taps in
The pulsing of the main refrigerant can also be accomplished by using, for example, a flow control device installed between the evaporator and compressor. In this case, the function of such flow control device can be combined with a function of so-called suction modulation valve (SMV) 228 that is often installed in refrigeration units to selectively reduce the unit capacity by throttling the flow at the compressor suction to control the amount of refrigerant reaching the compressor. A smaller amount of opening through the SMV valve allows less refrigerant to be delivered to the compressor. The SMV 228 can be rapidly cycled (opened and closed) to generate pulses of refrigerant through the condenser 224, with the pulsing refrigerant flow in turn enhancing the mixing of liquid and vapor refrigerant phases in the condenser 224 in a similar fashion as it was accomplished by the electronic expansion valve 226. Both, an electronic expansion valve and a suction modulation valve, can be utilized individually or in combination with each other and controlled by a controller 200 that would selectively open and close these valves to enhance the mixing of the vapor and liquid refrigerant phases. The suction modulation valve 228 can be substituted, for example, by a solenoid valve which would cycle between open and closed position (some limited amount of flow still might be permitted through the valve in its closed position to prevent compressor suction approaching deep vacuum). Further, it has to be understood that other location for such flow control devices are feasible within the refrigerant system. Analogously, for instance, a valve located on the discharge refrigerant line or liquid refrigerant line can perform the same function and may be controlled in a similar manner.
In summary, the present invention utilizes a small portion of predominantly vapor refrigerant from an upstream location, such as a discharge line or upstream manifold, and redirects this refrigerant to a location within a parallel flow heat exchanger, such as an intermediate manifold, downstream along the refrigerant path, where the vapor and liquid phase separation is likely to occur. This high pressure vapor refrigerant allows for better mixing and promotes homogeneous conditions for a two-phase refrigerant, such that maldistribution is appreciably reduced or eliminated for a refrigerant entering a downstream bank of heat transfer tubes positioned generally in a parallel arrangement.
While the main focus of the invention is on the condenser applications, refrigerant system evaporators can also benefit from the invention. In the case of an evaporator, a small portion of refrigerant vapor would be redirected to an inlet or intermediate manifolds from any number of a higher pressure locations within the refrigerant system, such as a discharge line, condenser manifolds, etc. The flow pulsing, though illustrated for the condenser heat exchangers, can be used in a similar fashion as described above to enhance refrigerant distribution in the evaporator heat exchangers. While the invention is disclosed for parallel flow heat exchangers, it does have applications for other heat exchanger types, for instance, for the heat exchangers having intermediate manifolds in the condenser applications. Also, the four-pass heat exchangers of
Although a preferred embodiment of this invention has been disclosed, a worker of ordinary skill in the art would recognize that certain modifications would come within the scope of this invention. For that reason the following claims should be studied to determine the true scope and content of this invention.
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/US2006/047966 | 12/15/2006 | WO | 00 | 12/29/2009 |
Publishing Document | Publishing Date | Country | Kind |
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WO2008/073111 | 6/19/2008 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
2310234 | Haug | Feb 1943 | A |
3450197 | Fieni | Jun 1969 | A |
3675710 | Ristow | Jul 1972 | A |
4972683 | Beatenbough | Nov 1990 | A |
5095972 | Nakaguro | Mar 1992 | A |
5168715 | Nakao et al. | Dec 1992 | A |
5168925 | Suzumura et al. | Dec 1992 | A |
5752566 | Liu et al. | May 1998 | A |
5765633 | Hu | Jun 1998 | A |
5988267 | Park et al. | Nov 1999 | A |
6047556 | Lifson | Apr 2000 | A |
6267173 | Hu et al. | Jul 2001 | B1 |
6318118 | Hanson et al. | Nov 2001 | B2 |
6341648 | Fukuoka et al. | Jan 2002 | B1 |
7000415 | Daddis, Jr. et al. | Feb 2006 | B2 |
20040159121 | Horiuchi et al. | Aug 2004 | A1 |
Number | Date | Country |
---|---|---|
473888 | Mar 1992 | EP |
886113 | Dec 1998 | EP |
10332226 | Dec 1998 | JP |
Entry |
---|
Supplementary European Search dated Apr. 1, 2011. |
International Preliminary Report mailed Jun. 29, 2011. |
Search Report and Written Opinion mailed on Oct. 19, 2007 for PCT/US2006/47966. |
Number | Date | Country | |
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20100139313 A1 | Jun 2010 | US |