Patent Grant
11353266
The present invention is related to heat exchangers, and more particularly to shell and tube heat exchangers.
Current heat exchanger designs involve structures of simple geometries, such as plates, sheets, and circular tubes as the main building blocks. This geometry limitation was mainly due to fabrication limitations. Recently new fabrication routes, such as additive manufacturing, in which intricate near net shaped parts are created by precise successive additions of material by fusion with laser and/or electron beams to form near net shaped parts without material removal, offers the opportunity of fabricating novel heat exchangers. Moreover, other hybrid manufacturing processes that involve additive manufacturing, which are referred to as additive manufacturing assisted fabrication, such as those for the fabrication of polymer patterns for the investment casting or lost wax casting have been used to fabricate complex heat exchanger designs. Thus, new heat exchanger designs have now an opportunity to be fabricated and further tested for their performance.
Recent studies have focused on optimizing heat exchanger flow architecture in order to enhance the heat transfer rate. The longitudinal configuration of the flow channel such as zigzag, curvy, step, single-layer, double-layer, tapered, wavy and converging channels for the same cross-sectional shape has been investigated and compared with the conventional straight channel with uniform cross-sectional shape. Several studies have been conducted to study the effect of the non-circular wetted perimeter shape only on fluid flow performance. The channels in printed circuit heat exchangers (PCHE) for supercritical CO2 Brayton cycle systems are semi-circular shape. The PCHE geometries involve very thick walls with very small effective areas open to flow, increasing the material cost. In summary, although the shape of the channel cross-section plays an important role in the performance of heat exchangers, alternative channel shapes to the circular ones is shell-and-tube like heat exchangers have not been used in industry due to fabrication difficulties or increase costs.
A counterflow heat exchanger is described in “Counterflow heat exchanger with core and plenums at both ends”, A. Bejan et al, International Journal of Heat and Mass Transfer 99 (2016) 622-629. The disclosure of this reference is incorporated fully by reference. There is a continuing need to improve the performance of such heat exchangers, and to provide designs which facilitate fabrication by such methods as additive manufacturing.
A shell and tube heat exchanger includes an elongated shell having first and second opposing ends and an open interior. A core divides the open interior of the shell into first and second enclosed portions. A first tube fluid opening can be at the first end of the elongated shell, and a second tube fluid opening can be at the second end of the elongated shell.
An end plate (or tube sheet) in the first enclosed portion is provided between the first tube fluid opening and the core, and divides the first enclosed portion into a first manifold portion and a first enclosed shell chamber. A second end plate is provided in the second end portion between the second tube fluid opening and the core, and divides the second enclosed portion into a second manifold portion and a second enclosed shell chamber.
A first plurality of tubes extend from the first end plate, through the first enclosed shell chamber to the core. The first plurality of tubes have open ends communicating with the first manifold portion and open ends communicating with the second enclosed shell chamber. A second plurality of tubes extend from the second end plate, through the second enclosed shell chamber to the core. The second plurality of tubes have open ends communicating with the second manifold portion and open ends communicating with the first enclosed shell chamber.
Shell fluid openings are provided at sides of the elongated shell. A first shell fluid opening communicates with the first enclosed shell chamber. A second shell fluid opening communicates with the second enclosed shell chamber.
The elongated shell has a long axis, and the end plates can be angled relative to the long axis. The angle can be from 15-75°. The core can be angled at the same angle as the end plates.
The tubes can be polygonal with rounded corners and straight sides. The rounded corners can have a radius r and a length L, and the ratio of r/L is less than 1.45. The ratio of r/L can be from 0.05-0.55. The polygonal tubes can be triangular shaped. The polygonal tubes can be diamond-shaped. The polygonal tubes can be square shaped. The tubes can have circular cross section.
The first enclosed shell chamber can have a volume greater than the volume of the second enclosed shell chamber, and the first plurality of tubes can be longer than the second plurality of tubes. In one embodiment, the first tube fluid opening can receive high temperature fluid, the second tube fluid opening can receive low temperature fluid, the first shell fluid opening can exhaust low temperature fluid, and the second shell fluid opening can exhaust high temperature fluid. In another embodiment, the first tube fluid opening exhausts low temperature fluid, the second tube fluid opening exhausts high temperature fluid, the first shell fluid opening receives high temperature fluid, and the second shell fluid opening receives low temperature fluid. In another embodiment, the first tube fluid opening receives low temperature fluid, the second tube fluid opening receives high temperature fluid, the first shell fluid opening exhausts high temperature fluid and the second shell fluid opening exhausts low temperature flow. In another embodiment, the first tube fluid opening exhausts high temperature fluid, the second tube fluid opening exhausts low temperature fluid, the first shell fluid opening receives low temperature fluid, and the second shell fluid opening receives high temperature fluid.
The core can have a length that is from 5%-75% of the length of the elongated shell. The core can have a minimum length that of 3 mm. The minimum core length can be the minimum of 3 mm or 5% of the length of the elongated shell. The maximum core length can be 75% of the length of the elongated shell.
There are shown in the drawings embodiments that are presently preferred it being understood that the invention is not limited to the arrangements and instrumentalities shown, wherein:
A shell and tube heat exchanger includes an elongated shell having first and second opposing ends and an open interior. A core divides the open interior of the shell into first and second enclosed portions. A first tube fluid opening can be at the first end of the elongated shell, and a second tube fluid opening can be at the second end of the elongated shell. An end plate (or tube sheet) in the first enclosed portion core is provided between the first tube fluid opening and the core, and divides the first enclosed portion into a first manifold portion and a first enclosed shell chamber. A second end plate is provided in the second end portion between the second tube fluid opening and the core, and divides the second enclosed portion into a second manifold portion and a second enclosed shell chamber.
A first plurality of tubes extend from the first end plate, through the first enclosed shell chamber to the core. The first plurality of tubes have open ends communicating with the first manifold portion and open ends communicating with the second enclosed shell chamber. A second plurality of tubes extend from the second end plate, through the second enclosed shell chamber to the core. The second plurality of tubes have open ends communicating with the second manifold portion and open ends communicating with the first enclosed shell chamber. Shell fluid openings are provided at sides of the elongated shell. A first shell fluid opening communicates with the first enclosed shell chamber. A second shell fluid opening communicates with the second enclosed shell chamber.
Any number of tube fluid openings and shell fluid openings are possible. The description that follows refers to a minimum number of tube fluid openings, shell fluid openings, and tubes for ease of depiction and description, and to facilitate an understanding of the invention. In practice, however multiple tubes are commonly used in shell and tube heat exchangers. Further, although the following describes a single heat exchanger in operation, multiple heat exchangers can be used and connected in series and/or in parallel depending upon the intended use. See, for example, “Design, additive manufacturing, and performance of heat exchanger with a novel flow path architecture”, A. Sabau et al, Applied Thermal Engineering 180 (2020) 115775, the disclosure of which is incorporated fully by reference.
The elongated shell has a long axis, and the end plates can be angled relative to the long axis. The angle can be denoted as a and can be from 15-75°. The core can be angled at the same angle as the end plates. The angle α can be 15°, 20°, 25°, 30°, 35°, 40°, 45°, 50°, 55°, 60°, 65°, 70°, and 75°, and can be within a range of any high value and low value selected from these values.
The tubes can be polygonal with rounded corners and straight sides. Sharp corners result in stagnant fluid flow in the vertex regions, and heat transfer would be poor. The invention eliminates such stagnation by providing corners which do not result stagnant fluid flow regions. The rounded corners can have a radius r and a length L, and the ratio of r/L is less than 1.45. The ratio of r/L can be from 0.05-0.55. The ratio of r/L can be 0.05, 0.1, 0.15, 0.2, 0.25, 0.3, 0.35, 0.4, 0.45, 0.5, and 0.55, and can be within a range of any high value and low value selected from these values. The polygonal tubes can be triangular shaped. The polygonal tubes can be diamond-shaped. The polygonal tubes can be square shaped. The tubes can have circular cross section.
The first enclosed shell chamber can have a volume greater than the volume of the second enclosed shell chamber, and the first plurality of tubes can be longer than the second plurality of tubes. This permits a great variety of permutations and arrangements, for example in evaporation and condensation processes, where the enclosed shell chamber can be larger to accommodate the larger volume of the gas. In one embodiment, the first tube fluid opening can receive high temperature fluid, the second tube fluid opening can receive low temperature fluid, the first shell fluid opening can exhaust low temperature fluid, and the second shell fluid opening can exhaust high temperature fluid. In another embodiment, the first tube fluid opening exhausts low temperature fluid, the second tube fluid opening exhausts high temperature fluid, the first shell fluid opening receives high temperature fluid, and the second shell fluid opening receives low temperature fluid. In another embodiment, the first tube fluid opening receives low temperature fluid, the second tube fluid opening receives high temperature fluid, the first shell fluid opening exhausts high temperature fluid and the second shell fluid opening exhausts low temperature flow. In another embodiment, the first tube fluid opening exhausts high temperature fluid, the second tube fluid opening exhausts low temperature fluid, the first shell fluid opening receives low temperature fluid, and the second shell fluid opening receives high temperature fluid.
The dimensions of the core can also be changed to optimize a particular heat exchange requirement. The core can have a length that is from 5%-75% of the length of the elongated shell. The core can have a length that is 5, 10, 15, 20, 25, 30, 35, 40, 45, 50, 55, 60, 65, 70, or 75% of the length of the elongated shell, and can be within a range of any high value and low value selected from these values. Particularly for long heat exchangers some of the desirable configurations will have a very thin core. The core can have a minimum length that of 3 mm. The minimum core length can be the minimum of 3 mm or 5% of the length of the elongated shell. The maximum core length can be 75% of the length of the elongated shell.
There is shown in
A first plurality of tubes 64 extend from the first end plate, through the first enclosed shell chamber 48 to the core 40. The tubes 64 have open ends 68 communicating with the first manifold portion and open ends 70 communicating with the second enclosed shell chamber 56. A second plurality of tubes 78 extend from the second end plate 52, through the second enclosed shell chamber 56 to the core 40. The second tubes 78 have open ends 82 communicating with the second manifold portion 74 and open ends 86 communicating with the first enclosed shell chamber 48. A single first tube 64 and second tube 78 are shown for ease of depiction and understanding, however, in practice multiple such tubes would be used. The number of tubes will depend on the design of the particular heat exchanger.
Fluid enters the tube fluid opening 22 as shown by arrow 90, and as shown by arrow 94 enters the opening 68 of the tube 64. The fluid then leaves the opening 70 of the tube 64 whereupon the fluid circulates within the second enclosed shell chamber 56 and exchanges heat with the tube 78 as shown by the arrow 98. The fluid is exhausted through the shell fluid opening 26 as shown by arrow 102. Fluid also enters the tube fluid opening 30 as shown by arrow 106 and enters the tube 78 through the opening 82 as shown by the arrow 110. The fluid leaves opening 86 of the tube 78 and circulates within the enclosed shell chamber 48 and exchanges heat with the tube 64 as shown by the arrow 114. Fluid leaves the shell chamber 48 through the shell to fluid opening 34 as shown by arrow 118.
The heat exchanger 10 can be made by any suitable process. The angled end plates 44 and 52 and core 40 make the heat exchanger 10 particularly well-suited for additive manufacturing. A first manifold cover 122 and second manifold cover 136 can be provided. The first manifold cover 122 can be secured by suitable structure such as flanges 124 and 128 adhered by a weld 132. The second manifold cover 136 can be secured by flanges 140 and 144 adhered by weld 148. Other constructions are possible.
A feature of the invention is that the tubes on either side of the core can have different lengths for different heat transfer operations.
Hot fluid enters the tube fluid opening 618 as shown by arrow 674 and enters the tube 662 and exchanges heat while in the longer tube 662. The hot fluid enters the enclosed chamber 642 and circulates around the shorter tube 646, and exits through the shell fluid opening 622 as shown by arrow 678. A cold fluid enters the tube fluid opening 614 as shown by arrow 666, flows into the shorter tube 646 and circulates in the enclosed chamber 658 around the longer tube 662. The cold fluid thereby exchanges heat with the longer tube 662 and the hot fluid flowing through the longer tube 662. The cold fluid exits the heat exchanger 600 through the shell fluid opening 626 as shown by arrow 670.
A second mode of operation is shown in
Hot fluid enters through the shell fluid opening 726 as shown by arrow 774. The hot fluid flows around and exchanges heat with the longer tube 762 and then enters the shorter tube 746 and exits through the tube fluid opening 714 as shown by arrow 778. Cold fluid enters through the shell fluid opening 722 as shown by arrow 766. The cold fluid flows around and exchanges heat with the shorter tube 746 and enters the longer tube 762 and exits through the tube fluid opening 718 as shown by arrow 770.
A third mode of operation is shown in
Hot fluid enters the tube fluid opening 818 as shown by arrow 874 and enters the shorter tube 862 and exchanges heat while in the shorter tube 862. The hot fluid enters the enclosed chamber 842 and circulates around the longer tube 846, and exits through the shell fluid opening 822 as shown by arrow 878. A cold fluid enters the tube fluid opening 814 as shown by arrow 866, flows into the longer tube 846 and circulates in the enclosed chamber 858 around the shorter tube 862. The cold fluid thereby exchanges heat with the shorter tube 862 and the hot fluid flowing through the shorter tube 862. The cold fluid exits the heat exchanger 800 through the shell fluid opening 826 as shown by arrow 820.
A fourth mode of operation is shown in
Hot fluid enters through the shell fluid opening 926 as shown by arrow 974. The hot fluid flows around and exchanges heat with the shorter tube 962 and then enters the longer tube 946 and exits through the tube fluid opening 914 as shown by arrow 978. Cold fluid enters through the shell fluid opening 922 as shown by arrow 966. The cold fluid flows around and exchanges heat with the longer tube 946 and enters the shorter tube 962 and exits through the tube fluid opening 918 as shown by arrow 970.
The invention as shown in the drawings and described in detail herein disclose arrangements of elements of particular construction and configuration for illustrating preferred embodiments of structure and method of operation of the present invention. It is to be understood however, that elements of different construction and configuration and other arrangements thereof, other than those illustrated and described may be employed in accordance with the spirit of the invention, and such changes, alternations and modifications as would occur to those skilled in the art are considered to be within the scope of this invention as broadly defined in the appended claims. In addition, it is to be understood that the phraseology and terminology employed herein are for the purpose of description and should not be regarded as limiting.
This invention was made with government support under Contract No. DE-AC05-00OR22725 awarded by the U.S. Department of Energy. The government has certain rights in this invention.
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| 1987325 | Jun 2007 | CN |
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| Number | Date | Country | |
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| 20220099377 A1 | Mar 2022 | US |
