Patent Application
20100206535
1. Field of the Invention
The present disclosure relates to heat exchangers. More particularly, the present disclosure relates to heat exchangers having baffled manifolds.
2. Description of Prior Art
Refrigeration systems are well known in the art and ubiquitous in such industries as food service, chemical, residential and commercial cooling, and automotive. On a larger scale, heat exchangers are required for office buildings and for residential purposes. Lack of efficiency is a great concern with such systems.
Traditional refrigeration cycles, or air conditioners, include a compressor, a condenser, an expansion valve, an evaporator, and a refrigerant whose evaporation creates the cool temperature. In some refrigeration systems, the evaporator and condenser are heat exchangers having a series of parallel channels, which provide parallel refrigerant paths. When the refrigerant passes through the expansion valve, a pressure and temperature drop occurs.
In many refrigerant vapor-compression systems, as the refrigerant passes through the expansion valve, a portion of the fluid expands to a vapor-phase, while a second portion of the fluid remains in a liquid-phase. The resulting two-phase fluid can cause maldistribution in the evaporator. As used herein, the term “maldistribution” of two-phase fluid shall mean that one phase of the fluid (e.g., liquid-phase) predominantly flows through a particular. portion of the evaporator, while that the other phase of the fluid (e.g., vapor-phase) predominantly flows through a different portion of the evaporator.
It has been determined by the present disclosure that maldistribution of the two-phase fluid is a common problem with heat exchangers that use parallel refrigerant paths, resulting in poor heat exchanger efficiency. For heat exchangers that have relatively few parallel refrigerant paths (typically 20 or less), even distribution of the two-phase fluid is achieved through a distribution device that individually feeds each parallel refrigerant path. However, for heat exchanges with many parallel refrigerant paths (typically more than 20), individual distribution to each parallel refrigerant path is often not practical. In most cases, a simple inlet header is used, which can lead to significant refrigerant maldistribution to the heat exchanger. Additionally, gravity and the increase in overall volume as the flow transitions from the expansion device to the inlet header also act to cause the liquid-phase and vapor-phase to separate, causing maldistribution to the heat exchanger.
Previously, it has been proposed by U.S. Pat. No. 7,143,605 to include a distributor tube positioned within the inlet manifold to reduce maldistribution. While the distributor tube has proven to be helpful to reduce maldistribution, the maldistribution of the liquid-phase and vapor-phase within the heat exchanger remains problematic.
Therefore, there exists a need for heat exchangers that overcome, alleviate, and/or mitigate one or more of the aforementioned and other deleterious effects of prior art heat exchangers.
A heat exchanger having a plurality of parallel channels in fluid communication with a manifold. The manifold includes a mixing device and one or more baffles that work together to prevent maldistribution of the two-phases of the fluid within the channels.
The above-described and other features and advantages of the present disclosure will .be appreciated and understood by those skilled in the art from the following detailed description, drawings, and appended claims.
Referring now to the figures and in particular to
For purposes of clarity,
Heat exchanger 10 includes a first manifold 18 and a second manifold 20 that are in fluid communication with one another by way of a plurality of parallel channels 22. In the illustrated embodiment, heat exchanger 10 is a micro-channel heat exchanger having a plurality of micro-channels 22. However, it is contemplated by the present disclosure for baffles 12 to find equal use with any type of parallel path heat exchanger having channels 22 of any desired size.
First manifold 18 includes a first partition 24-1 and second manifold 20 includes a second partition 24-2. Partitions 24-1, 24-2 are configured to separate manifolds 18, 20 and channels 22 into first pass 14 and second pass 16, respectively, along a line 26. Partition 24-1 divides first manifold 18 into an inlet side 28 and an outlet side 30. Similarly, partition 24-2 divides second manifold 20 into an inlet side 32 and an outlet side 34.
Heat exchanger 10 includes a distribution insert 36 within inlet side 28 of first manifold 18. Further, heat exchanger 10 includes a collection insert 38 within outlet side 32 of second manifold 20 and a distribution insert 40 within inlet side 34 of second manifold 20. In the illustrated embodiment, collection insert 38 and distribution insert 40 are shown as one unitary member. However, it is contemplated by the present disclosure for collection and distribution inserts 38, 40 to be separate items.
Heat exchanger 10 finds particular use with a fluid 42, such as a refrigerant of a vapor-compression or air conditioning circuit. Fluid 42 can be a single-phase fluid or a two-phase fluid. Thus, fluid 42 traveling through heat exchanger 10 can be in a vapor-phase and/or a liquid-phase. In the illustrated embodiment, the flow of fluid 26 is represented by one or more directional arrows.
Distribution insert 36 includes a plurality of openings 44 defined therein. Openings 44 place distribution insert 36 in fluid communication with inlet side 28 of first manifold 18. Collection insert 38 includes a plurality of openings 46 defined therein. Openings 46 place collection insert 38 in fluid communication with outlet side 32 of second manifold 20. Distribution insert 40 includes a plurality of openings 48 defined therein. Openings 48 place distribution insert 40 in fluid communication with inlet side 34 of second manifold 20.
During use, fluid 42 enters heat exchanger 10 through distribution insert 36 within inlet side 28 of first manifold 18. The fluid 42 is prevented from flowing from inlet side 28 to outlet side 30 by partition 24-1. Rather, distribution insert 36 distributes fluid 42 into inlet side 28 of first manifold 18 through openings 44.
It has been determined by the present disclosure that distribution insert 36 assists in passing fluid 42 in a substantially homogeneous state to inlet side 28 of first manifold 18. More particularly, it has been determined that distribution insert 36 assists in mixing fluid 42 so that the fluid within inlet side 28 of first manifold 18 is a substantially homogeneous mixture of liquid-phase fluid and vapor-phase fluid.
Openings 44 are preferably of variable size to effectively mix and distribute fluid 42 flowing into inlet side 28 of first manifold 18. Openings 44 can have a dimension that can be uniform across distribution insert 36, or the dimension of the openings can increase in size in a direction from first pass 14 to second pass 16. For example, openings 44 can increase in dimension further downstream of the fluid flow path can achieve a greater degree of fluid distribution.
Within inlet side 28, baffles 12 are configured to limit the movement of fluid 42 within the inlet side 28 of first manifold 18. More specifically, and without wishing to be bound by any particular theory, it has been determined by the present disclosure that the liquid and vapor phases of fluid 42 can be separated by the fluidic forces within heat exchanger 10 such that these forces can cause one of the two phases to be forced towards partition 24-1. This movement of fluid 42 along the axis of first manifold 18 towards partition 24-1 can be limited by baffles 12. Thus, baffles 12 assist in mitigating maldistribution of fluid 42 within channels 22 of first pass 14.
In sum, heat exchanger 10 includes a mixing device, illustrated as distribution insert 36, to effectively mix fluid 42 as the fluid enters inlet side 28 so that both phases of the fluid are in a substantially homogeneous two-phase mixture within inlet side 28. Further, heat exchanger 10 includes one or more baffles 12 (two show) to prevent the fluidic forces within inlet side 28 from separating the two phases from one another and forcing one of the two phases towards partition 24-1. In this manner, baffles 12 ensure that fluid 42 enters channels 22 of first pass 14 in the substantially homogeneous two-phase mixture, which mitigates maldistribution of the fluid within the channels.
Fluid 42 enters channels 22 from inlet side 28 of first manifold 18, flows through the channels and exits the channels into outlet side 32 of second manifold 20. Here, fluid 42 is prevented from flowing directly to inlet side 34 of second manifold 20 by partition 24-2.
Rather, fluid 42 flows from outlet side 32 to collection insert 38 through openings 46. Then, fluid 42 flows from collection insert 38 to distribution insert 40. In this manner, fluid 42 flows from first pass 14 across line 26 into second pass 16. Next, fluid 42 flows from distribution insert 40 through openings 48 into inlet side 34 of second manifold 20.
It has been determined by the present disclosure that collection insert 38 and/or distribution insert 40 assists in passing fluid 42 in a substantially homogeneous two-phase state to inlet side 34 of second manifold 20. More specifically, collection insert 38 and distribution insert 40 each mix fluid 42 as the fluid passes therethrough.
Baffles 12 within second manifold 20 are configured to limit the movement of fluid 42 within inlet side 34 along the axis (A) of the second manifold. Thus, baffles 12 can also assist in mitigating maldistribution of fluid 42 within channels 22 of second pass 16.
Fluid 42 enters channels 22 from inlet side 34 of second manifold 20, flows through the channels and exits the channels into outlet side 30 of first manifold 18. In the illustrated embodiment where heat exchanger 10 is a two-pass exchanger, fluid 42 flows out of the heat exchanger. However, it is contemplated by the present disclosure for heat exchanger 10 to have more than two passes 14, 16, such that fluid 42 flowing from second manifold 20 can enter a third pass (not shown) of channels.
An alternate embodiment of heat exchanger 10 having baffles 12 is shown in
As such, it is contemplated by the present disclosure for heat exchanger 10 to have distribution insert 36 with openings 44 at any desired angle with respect to the direction of flow through channels 22. For example, it is contemplated for heat exchanger 10 to have distribution insert 36 with openings 44 at an angle such as zero degrees (
Also shown in the embodiment of
Referring now to
Referring now to
External collection-distributor 56 is in fluid communication with outlet side 32 of second manifold 20 via one or more ports 58 (only one shown). Further, external collection-distributor 56 is in fluid communication with inlet side 34 of second manifold 20 via one or more ports 60 (three shown).
In this manner, fluid 42 enters channels 22 from inlet side 28 of first manifold 18, flows through the channels and exits the channels into outlet side 32 of second manifold 20. Here, fluid 42 is prevented from flowing directly to inlet side 34 of second manifold 20 by partition 24-2.
Rather, fluid 42 flows from outlet side 32 to external collection-distributor 56 through openings 58. Then, fluid 42 flows through external collection-distributor 56 from first pass 14 across line 26 into second pass 16. Next, fluid 42 flows from external collection-distributor 56 through openings 60 into distribution insert 40, which further mixes fluid 42 as the fluid flows from the distribution insert through openings 48 into inlet side 34 of second manifold 20. As discussed above, baffles 12 within second manifold 20 are configured to limit the movement of fluid 42 along axis A of the second manifold. Thus, baffles 12 can also assist in mitigating maldistribution of fluid 42 within channels 22 of second pass 16.
External collection-distributor 56 assists in passing fluid 42 in a substantially homogeneous state to inlet side 34 of second manifold 20. The combination of external collection-distributor 56 along with distribution insert 40 adds an additional mixing stage as compared to the embodiment of
Referring now to
In this embodiment, first manifold 18 includes inlet port 66 and outlet port 68 that are configured so that the flow of fluid 42 is in a direction substantially parallel (e.g., about zero degrees) to the flow of fluid through channels 22. By way of contrast, heat exchanger 10 illustrated in
Also illustrated in this embodiment, first manifold 18 includes collection insert 38 within outlet side 30 of the first manifold. Collection insert 38 within outlet side 30 of first manifold 18 functions as described with respect to collection insert 38 within outlet side 32 of second manifold 20 of the embodiment of
Also illustrated in this embodiment, heat exchanger 10 includes a second collection-distributor 70 at second manifold 20. Second collection-distributor 70 is in fluid communication with collection insert 38 via one or more (only one shown) openings 72 and with distributing insert 40 via one or more (only one shown) openings 74. In addition, partition 24-2 includes an extension 76 preventing direction fluid communication between collection insert 38 and distributing insert 40. Thus, heat exchanger 10 in the embodiment of
Advantageously, heat exchanger 10 finds use in any refrigeration circuit. For example, and referring now to
Heat exchanger 10 can be arranged within circuit 80 so that the plurality of channels 22 are arranged in any desired manner. In some embodiments, heat exchanger 10 can be arranged within circuit 80 so that channels 22 are vertically arranged. In this manner, heat exchanger 10 can be arranged within circuit 80 so that refrigerant 42 flows through the channels in an up-and-down manner. In other embodiments, heat exchanger 10 can be arranged within circuit 80 so that channels 22 are horizontally arranged. In this manner, heat exchanger 10 can be arranged within circuit 80 so that refrigerant flows through channels 22 in a side-to-side manner.
Circuit 80 can find use in any vapor-compression device such as, but not limited to, an air conditioner, a heat pump, a dehumidifier, a refrigerator, a freezer, and others. For example, circuit 80 can find use in an air conditioner in a vehicle such as, but not limited to, an automobile, a truck, a ship, an airplane, and other mobile vehicles. Further, circuit 80 can find use in an air conditioner in a stationary conditioning device such as that used in a refrigerator, freezer, home air conditioner, or commercial air conditioner, a chiller unit, and others.
As described herein, heat exchanger 10 includes parallel channels 22 in fluid communication with one another via a pair of manifolds 18, 20. One or more of the manifolds can include mixing devices (e.g., inserts 36, 38, 40, 56, 70) to keep fluid 42 passing through heat exchanger 10 in a substantially uniform two-phase mixture. Advantageously, heat exchanger 10 also includes one or more baffles 12 within one or more of the manifolds 18, 20. The baffles 12 prevent movement of fluid 22 along the axis of the manifolds 18, 20 so that fluid 42 remains in the uniform two-phase mixture when entering channels 22.
It should also be noted that the terms “first”, “second”, “third”, “upper”, “lower”, and the like may be used herein to modify various elements. These modifiers do not imply a spatial, sequential, or hierarchical order to the modified elements unless specifically stated.
While the instant disclosure has been described with reference to one or more exemplary embodiments, it will be understood by those skilled in the art that various changes may be made and equivalents may be substituted for elements thereof without departing from the scope thereof. In addition, many modifications may be made to adapt a particular situation or material to the teachings of the disclosure without departing from the scope thereof. Therefore, it is intended that the disclosure not be limited to the particular embodiment(s) disclosed as the best mode contemplated for carrying out the apparatus in present disclosure, but that the disclosed apparatus will include all embodiments falling within the scope of the disclosure.
| Filing Document | Filing Date | Country | Kind | 371c Date |
|---|---|---|---|---|
| PCT/US07/21858 | 10/12/2007 | WO | 00 | 4/8/2010 |
