WO1985004002A1 - Heat exchanger for mass transfer device - Google Patents

Heat exchanger for mass transfer device Download PDF

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Publication number
WO1985004002A1
WO1985004002A1 PCT/US1985/000127 US8500127W WO8504002A1 WO 1985004002 A1 WO1985004002 A1 WO 1985004002A1 US 8500127 W US8500127 W US 8500127W WO 8504002 A1 WO8504002 A1 WO 8504002A1
Authority
WO
WIPO (PCT)
Prior art keywords
fluid
core
mass transfer
heat exchanger
hose
Prior art date
Application number
PCT/US1985/000127
Other languages
French (fr)
Inventor
Ronald J. Leonard
Kenneth M. Johnson
Thomas L. Drehobl
Original Assignee
Omnis Surgical Inc.
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Omnis Surgical Inc. filed Critical Omnis Surgical Inc.
Priority to DE8585900917T priority Critical patent/DE3563477D1/en
Publication of WO1985004002A1 publication Critical patent/WO1985004002A1/en

Links

Classifications

    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F28HEAT EXCHANGE IN GENERAL
    • F28FDETAILS OF HEAT-EXCHANGE AND HEAT-TRANSFER APPARATUS, OF GENERAL APPLICATION
    • F28F21/00Constructions of heat-exchange apparatus characterised by the selection of particular materials
    • F28F21/06Constructions of heat-exchange apparatus characterised by the selection of particular materials of plastics material
    • F28F21/062Constructions of heat-exchange apparatus characterised by the selection of particular materials of plastics material the heat-exchange apparatus employing tubular conduits
    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61MDEVICES FOR INTRODUCING MEDIA INTO, OR ONTO, THE BODY; DEVICES FOR TRANSDUCING BODY MEDIA OR FOR TAKING MEDIA FROM THE BODY; DEVICES FOR PRODUCING OR ENDING SLEEP OR STUPOR
    • A61M5/00Devices for bringing media into the body in a subcutaneous, intra-vascular or intramuscular way; Accessories therefor, e.g. filling or cleaning devices, arm-rests
    • A61M5/44Devices for bringing media into the body in a subcutaneous, intra-vascular or intramuscular way; Accessories therefor, e.g. filling or cleaning devices, arm-rests having means for cooling or heating the devices or media
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F28HEAT EXCHANGE IN GENERAL
    • F28FDETAILS OF HEAT-EXCHANGE AND HEAT-TRANSFER APPARATUS, OF GENERAL APPLICATION
    • F28F9/00Casings; Header boxes; Auxiliary supports for elements; Auxiliary members within casings
    • F28F9/24Arrangements for promoting turbulent flow of heat-exchange media, e.g. by plates
    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61MDEVICES FOR INTRODUCING MEDIA INTO, OR ONTO, THE BODY; DEVICES FOR TRANSDUCING BODY MEDIA OR FOR TAKING MEDIA FROM THE BODY; DEVICES FOR PRODUCING OR ENDING SLEEP OR STUPOR
    • A61M2205/00General characteristics of the apparatus
    • A61M2205/36General characteristics of the apparatus related to heating or cooling
    • A61M2205/366General characteristics of the apparatus related to heating or cooling by liquid heat exchangers

Definitions

  • the present invention concerns a novel heat ex ⁇ changer and a novel method for making the heat exchang ⁇ er.
  • the heat exchanger of the illustrative embodiment may be used with a mass transfer device, such as an oxygenator or a dialyzer, and it may be enclosed within the mass transfer device housing.
  • Mass transfer devices such as oxygenators and dialyzers, are known in which the mass transfer device housing encloses a heat exchanger for controlling the temperature of the blood.
  • a combination blood oxygenator and heat exchanger is disclosed in U.S. Patent No. 3,764,271.
  • heat exchanger of the present inven ⁇ tion may be used in many different fields, and although no limitation is intended, for simplicity the heat ex ⁇ changer of the present invention will be described herein as being used in a blood oxygenator. Disposable blood oxygenators are widely used today in connection with the oxygenation of a patient's blood, and the present invention is ideally suited for this field of use, among others.
  • a disposable blood oxygenator be relatively compact, have a low prime volume, be easy to manufacture, and have a relatively low cost. It is important that a heat exchanger, used in connection with a disposable blood oxygenator, enable substantial ⁇ ly uniform flow of the fluids that will be in heat ex ⁇ change relationship with each other. It is also desirable that the oxygenator and heat exchanger be formed as a single unit, that the heat exchanger be po ⁇ sitioned close to the oxygenating medium, such as the oxygenator fiber bundle, and that the heat exchanger have high efficiency with a relatively low pressure drop.
  • the present invention provides a heat exchanger having the characteristics and abilities set forth above.
  • a heat exchanger which- comprises a core having an inside and an outside and formed of a corrugated metal having a high thermal conductivity.
  • Each of the corru ⁇ gations of the core comprises an outer wall, a contigu ⁇ ous first side wall, a contiguous inner wall, and a contiguous second side wall.
  • the first and second side walls are substantially parallel to each other and a plurality of the corrugations repeat contiguously.
  • a first fluid, such as blood is introduced onto the out ⁇ side of the core.
  • a second fluid such as water, is introduced into the inside of the core.
  • the first and second fluids are in heat exchange relationship with each other and the flow of the fluids is substantially uniform resulting from the substantially parallel first and second side walls of the corrugations.
  • the core is formed by the steps- of providing a flexible metal hose, annealing the flexible metal hose, compressing the annealed hose and expanding the compressed hose to a length that is substantially less than its original length but greater than its length during compression. These steps have been found to provide the substantial parallelism of the walls of the corrugations, enabling substantially uniform flow of the fluids.
  • the second fluid flows through a manifold which is located within the inside of the core.
  • the manifold comprises a generally S-shaped cross-sectional configuration.
  • the S-shape is defined by an intermediate wall having opposed ends with a first curved member extending from one end to- ward the other end but spaced therefrom to form a first slot, and with the second curved member extending from the other end and. toward the one end but spaced there ⁇ from to form a second slot.
  • the second fluid is intro ⁇ quizd into the first chamber defined by one side of the intermediate wall and the first curved member. In- this manner, the second fluid will exit from the second chamber defined by the opposite side of the intermedi ⁇ ate wall and the second curved member.
  • a mass transfer device in which the device has a housing enclosing a mass transfer medium and a spaced heat ex ⁇ changer.
  • the mass transfer medium is operative to ena ⁇ ble mass transfer between a first fluid, such as blood, and a third fluid, such as oxygen.
  • the mass transfer device includes the aforesaid heat exchanger and means are provided for conveying the first ' fluid, such as blood, that has been through the heat exchanger, from the heat exchanger to one area of the mass transfer me ⁇ dium.
  • the third fluid, such as oxygen is introduced to another area of the mass transfer medium to enable mass transfer to occur.
  • the. second fluid manifold which- is provided and which is located within the inside of the core comprises a first chamber defined by a first member, and a second chamber defined by a second member.
  • the second fluid is first intro ⁇ quizd into the first chamber and the second fluid is then directed from the first chamber to the second chamber.
  • Means are provided for creating turbulent flow of the second fluid as it exits from the first chamber.
  • the first mem ⁇ ber and second member define openings between the first chamber and the second chamber.
  • a screen member is lo ⁇ cated between the first chamber and the second chamber.
  • a proc- ess is provided for making a heat exchanger.
  • the proc ⁇ ess comprises the steps of providing a flexible metal hose, annealing the flexible metal hose, thereafter compressing the annealed hose, and thereafter expanding the compressed hose to a length that is substantially less than its original length but greater than its length during compression.
  • Figure 1 is a perspective view, partially broken for clarity, of a mass transfer device constructed in accordance with the principles of the present inven ⁇ tion.
  • Figure 2 is an exploded perspective view of the heat exchanger used in the mass transfer device of Fig ⁇ ure 1.
  • Figure 3 is a perspective diagrammatic view of a fluid manifold used in the heat exchanger of Figure. 2.
  • Figure 4 is an elevational view, partially shown in phantom for simplicity, of a heat exchanger con ⁇ structed in accordance with the principles of the pres ⁇ ent invention.
  • Figure 5 is a cross-sectional , elevation of a slightly modified mass transfer device.
  • Figure 6 is a cross-sectional view of the mass transfer device of Figure 5, taken along the plane of the line 6-6 of Figure 5.
  • Figure 7 is a flow chart of the steps comprising a process of making a heat exchanger core.
  • Figure 8a is a diagrammatic view of a cross- section of a high pressure flexible hose, without show ⁇ ing the metal thickness.
  • Figure 8b is a diagrammatic view of a cross- section of a heat exchanger core that has been con- structed from the Figure 8a hose, with the bottom por ⁇ tion of Figure 8b being a greatly enlarged section of the top portion of Figure 8b.
  • Figure 9 is an end view of a fluid manifold for the heat exchanger of the present invention, according to another form of the invention, and showing with arrowed lines the fluid flew.
  • Figure 10 is a perspective view of the manifold of Figure 9.
  • Figure 11 is a perspective view of an alternative manifold.
  • oxygenator 20 includes a molded plastic housing 22 with a first fluid inlet 24 for use as a blood inlet, a first fluid outlet 26 for use as a blood outlet, a second fluid inlet 28 which operates as a water outlet, a second fluid outlet 30 which operates as a water outlet, a third fluid in ⁇ let 32 which operates as an oxygen inlet, and a third fluid outlet 34 which operates as an oxygen outlet.
  • Housing 22 has a lower portion 36 which encloses the heat exchanger 38.
  • heat exchanger 38 in ⁇ cludes a core 40, a manifold 42, end caps 44, inlet port 46 and outlet port 48.
  • an oxygenator 20' is illustrated.
  • Oxygenator 20' is simi- lar to oxygenator 20 of Figure 1, but the blood inlet 24" and the blood outlet 26' are at the top of the oxygenator instead of being at the side of the oxygenator as in Figure 1.
  • mass transfer medium 52 comprises a hollow fiber bundle in tubular form as is well known in the art, wound about a plastic- core 54.
  • the hollow fi- ber bundle 52 is encapsulated at its ends by means of a potting compound 56, although the ends of the hollow fibers are open to ' form oxygen flow paths as is known in the art.
  • Housing end caps 58 and 60 secure the ends of the mass transfer device assembly.
  • the blood path is into inlet 24, around the out ⁇ side of heat exchange 38, then around the hollow fiber bundle 52 and out of outlet 26.
  • the cooling and/or heating water flows via inlet port 46 into inlet 28, through manifold 42 and inside the heat exchanger core 40, and out outlet 30 and outlet port.48.
  • the oxygen flows into inlet 32, the fiber bundle and out the out ⁇ let 34.
  • a snap-on coupling 62 and a corrugated ' portion 64 is formed with inlet port 46.
  • Snap-on portion 62 enables the water hose to be snapped onto inlet port 46 and corrugations 64 ena- ble the inlet port 46 to be bent for ease in connection and handling.
  • outlet port 48 is formed with snap-on portion 66 and with corrugations 68 to enable an outlet hose to be quick-coupled to outlet port 48 and to enable the. outlet port 48 to bend for ease in connection and handling.
  • the heat exchanger core 40 of the present inven ⁇ tion is novel and has been found to be effective to enable substantially uniform flow of the fluids that will be in heat exchange relationship with each other.
  • a construction of heat exchanger core 40 and its method of manufacture are explained as follows, with particu ⁇ lar reference to Figures 7-8.
  • the heat exchanger core 40 is formed from a high pressure flexible metal hose, of the type that is often sold in auto parts stores for use as the flexible metal hose for conveying cooling fluid within the engine com- partment.
  • the outer di ⁇ ameter of the flexible hose is 2 inches and the inner diameter is 1.5 inches.
  • this flexible metal hose is corrugated, with approximately six corrugations per inch.
  • FIG 8a A broken, enlarged diagrammatic view of portion of this flexible metal hose is presented in Figure 8a. Referring to Figure 8a, it can be seen that the side walls 70, 72 of each corrugation are not parallel to each other. It should be noted that Figures 8a to 8b are not to scale and are diagrammatic only.
  • the steps for forming heat exchanger core 40 are illustrated in Figure 7.
  • the flexible hose as des ⁇ cribed above is provided, and it is annealed in an oven.
  • the annealed hose is allowed to cool and is then compressed to between 5 percent and 25 percent of its original length, preferably about 20 percent of its original length.
  • the opposite ends are pulled apart so that it is expanded to 1.5 times to 3 times its compressed length, preferably about 2 times its compressed length.
  • Manifold 42 is then inserted into the heat exchanger core and thereafter the end caps and ports are connected and welded to form the re ⁇ sulting heat exchanger illustrated in Figure 4.
  • side walls 70, 72 are still curvilinear and are not parallel to each other.
  • the flexible hose is compressed to about 20 percent of its original length, but flow be ⁇ comes even more restricted because of the hairpin-type configuration.
  • the side walls 70, 72 be- come substantially parallel with each other, providing more constant volume with substantially uniform flow.
  • the result ⁇ ing heat exchanger core comprises a plurality of con- tiguous corrugations 74, with each of the corrugations having an outer wall 76, a contiguous first side wall 70, a contiguous inner wall 78, and a contiguous second side wall 72, with the first side wall 70 and the sec ⁇ ond side wall 72 being substantially parallel to each other.
  • the length of the original flexible hose was 22 inches and it had approx ⁇ imately 6 corrugations per inch.
  • This flexible metal hose is formed of a non-corrosive substance such as stainless steel or aluminum having a high thermal con ⁇ ductivity, and it was subjected to annealing in an oven . at approximately 1000° F. The annealed hose was then removed from the oven, air cooled and then compressed to a length of 4 inches, in which it had approximately 33 corrugations per inch. The compressed metal hose ' was then expanded so that its length became 7.5 inches having approximately 18 corrugations per inch.
  • Manifold 42 which is inserted into heat exchanger core 40 is illus- trated therein.
  • Manifold 42 operates to distribute the second fluid which flows from inlet 28 to outlet 30 ( Figure 1) .
  • Manifold 42 has a generally S-shaped cross sectional configuration, with the S-shape being defined by an intermediate wall 80 having opposed ends 82, 84.
  • first curved member 86 extends from end 82 and toward the other end 84 but spaced therefrom to form a first longitudinal slot 88.
  • a second curved member 90 ex ⁇ tends from end 84 and toward end 82 but is spaced therefrom to form a second longitudinal slot 92.
  • the second fluid i.e., water
  • the first fluid will flow in chamber 94, out of slot 88, around curved members 86 and 90 in the direction of arrows 96, 97, through slot 92 and into chamber 98 in the direction of arrows 99, 100, through chamber 98 and out of chamber 98.
  • Chamber 98 is defined by side 80b of intermediate member 80 and curved member 90.
  • cooling or heating water will flow on the inside of heat exchanger core 40 and the blood will flow on the outside thereof.
  • the blood that has been heat exchanged will then flow into the mass transfer area where it will be oxygenated with the oxygenated blood exiting via blood out let 26.
  • device for pro- viding turbulent flow is utilized.
  • Heat transfer in turbulent flow is significantly greater than heat transfer in laminar fluid flow, due to the turbulence induced mixing.
  • a turbulence inducer is illustrated in Figures 9-11, which turbulence inducer is intended to achieve greater overall heat transfer.
  • a manifold 42' is shown therein comprising a first chamber 104 and a sec ⁇ ond chamber 106.
  • the first chamber is defined by a first member having a planar base 108 defining a series of collinear spaced slots 110. Although not all of the slots are illustrated, in the embodiment of Figures 9 and 10, there may be between four and ten slots 110.
  • a first curved member 112 extends from end 114 of base 108 and a second curved member 116 extends from end 118 of base 108. Curved members 112 and 116 extend toward each other but are spaced from each other to define a longitudinal slot 120.
  • the second chamber 10-6 is defined by a second base member 122 having a third curved member 124 extending from end 126 thereof.
  • a fourth curved member 128 ex ⁇ tends from end 130 of base 122, with third and fourth curved members 124 and 128 extending toward each other, but being spaced from each other to define a longitudi ⁇ nal slot 132.
  • Slot 132 is on the opposite side of manifold 42" from slot 120, and the cross-sectional configuration of curved members 112, 116, 124 and 128 is substantially circular.
  • a screen 136 is interposed between base 108 and base 122 to aid in creating the turbulent flow desired.
  • Manifold 42' is inserted into heat exchanger core 40, in the same manner that mani- fold 42 ( Figure 2) is inserted into heat exchanger core 40.
  • Water inlet 28 ( Figure 1) will introduce the entry water to chamber 104 and most of the water will flow via slot 120, around the outside of the manifold (i.e., inside the heat exchanger core) in the direction of arrowed lines 140, 141, through slit 132 and into cham ⁇ ber 106, and out the end of chamber 106 opposite to the entry end of chamber 104.
  • Some of the water will flow through slots 110 and pass through screen 136 in the direction of arrowed flow lines 144, 145. This water- will enter the flow at about points 146 and 147 ( Figure 9) to enter the flow stream at substantially a right angle, to create turbulence.
  • a manifold 42" is illustrated, and it includes an upper member 148 comprising a base 150, a first curved member 152 extending from one end 154 of base 150 and a second curved member 156 extending from end 158 of base 150. Curved members 152 and 156 curve toward each other but are spaced to form a longitudinal slot 160. As illustrated, a series of collinear slots 162 are defined by second curved member 156 toward the junction between curved member 156 and base 150. Like ⁇ wise, first curved member 152 defines a plurality of collinear slots 164 adjacent the junction between first curved member 152 and base 150.
  • the upper member 148 illustrated in Figure 11 defines a first chamber 165.
  • a second chamber 167 is defined by a connected lower member 149 including base 168, third curved member 170 and fourth curved member 172. Curved members 170 and 172 curve toward each other and are spaced to form a slot 174.
  • the water will flow into the first chamber 165 de ⁇ fined by the upper member 148 with some of the water flowing up through slot 160 and around the outside of the manifold, then back into slot 174 and out the sec ⁇ ond chamber 167. Some of the water from the first chamber 165 will flow through slots 162 and 164 to en ⁇ ter the outside flow at an angle to the flow stream to create turbulence.
  • a disposable blood oxygenator has been disclosed that is relatively compact, has a low prime volume, is easy to manufacture and has a relatively low cost.
  • the heat exchanger in accordance with the present invention enables substantially uniform flow of the fluid that will be in heat exchange relationship with each other.

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Abstract

A heat exchanger (38) which may be used in a mass transfer device (20), such as an oxygenator or a dialyzer. The heat exchanger comprises a core (40) formed of a corrugated metal having a high thermal conductivity. Each of the corrugations of the core comprises substantially parallel side walls (70, 72). A first fluid, such as blood, is introduced onto the outside of the core. A second fluid, such as water, is introduced into the inside of the core. The first and second fluids will be in heat exchange relationship with each other and the flow of the fluids is substantially uniform resulting from the substantially parallel side walls of the corrugations. The core is formed by providing a flexible metal hose, annealing the flexible metal hose, compressing the annealed hose and expanding the compressed hose to a length that is substantially less than its original length but greater than its length during compression.

Description

HEAT EXCHANGER FOR MASS TRANSFER DEVICE
TECHNICAL FIELD
The present invention concerns a novel heat ex¬ changer and a novel method for making the heat exchang¬ er. The heat exchanger of the illustrative embodiment may be used with a mass transfer device, such as an oxygenator or a dialyzer, and it may be enclosed within the mass transfer device housing.
BACKGROUND ART
Mass transfer devices, such as oxygenators and dialyzers, are known in which the mass transfer device housing encloses a heat exchanger for controlling the temperature of the blood. For example, a combination blood oxygenator and heat exchanger is disclosed in U.S. Patent No. 3,764,271.
Although the heat exchanger of the present inven¬ tion may be used in many different fields, and although no limitation is intended, for simplicity the heat ex¬ changer of the present invention will be described herein as being used in a blood oxygenator. Disposable blood oxygenators are widely used today in connection with the oxygenation of a patient's blood, and the present invention is ideally suited for this field of use, among others.
It is desirable that a disposable blood oxygenator be relatively compact, have a low prime volume, be easy to manufacture, and have a relatively low cost. It is important that a heat exchanger, used in connection with a disposable blood oxygenator, enable substantial¬ ly uniform flow of the fluids that will be in heat ex¬ change relationship with each other. It is also desirable that the oxygenator and heat exchanger be formed as a single unit, that the heat exchanger be po¬ sitioned close to the oxygenating medium, such as the oxygenator fiber bundle, and that the heat exchanger have high efficiency with a relatively low pressure drop. The present invention provides a heat exchanger having the characteristics and abilities set forth above.
DISCLOSURE OF THE INVENTION
In accordance with the present invention, a heat exchanger is provided which- comprises a core having an inside and an outside and formed of a corrugated metal having a high thermal conductivity. Each of the corru¬ gations of the core comprises an outer wall, a contigu¬ ous first side wall, a contiguous inner wall, and a contiguous second side wall. The first and second side walls are substantially parallel to each other and a plurality of the corrugations repeat contiguously. A first fluid, such as blood, is introduced onto the out¬ side of the core. A second fluid, such as water, is introduced into the inside of the core. The first and second fluids are in heat exchange relationship with each other and the flow of the fluids is substantially uniform resulting from the substantially parallel first and second side walls of the corrugations. in the illustrative embodiment, the core is formed by the steps- of providing a flexible metal hose, annealing the flexible metal hose, compressing the annealed hose and expanding the compressed hose to a length that is substantially less than its original length but greater than its length during compression. These steps have been found to provide the substantial parallelism of the walls of the corrugations, enabling substantially uniform flow of the fluids.
In the illustrative embodiment, the second fluid flows through a manifold which is located within the inside of the core. The manifold comprises a generally S-shaped cross-sectional configuration. The S-shape is defined by an intermediate wall having opposed ends with a first curved member extending from one end to- ward the other end but spaced therefrom to form a first slot, and with the second curved member extending from the other end and. toward the one end but spaced there¬ from to form a second slot. The second fluid is intro¬ duced into the first chamber defined by one side of the intermediate wall and the first curved member. In- this manner, the second fluid will exit from the second chamber defined by the opposite side of the intermedi¬ ate wall and the second curved member.
In the illustrative embodiment, a mass transfer device is provided in which the device has a housing enclosing a mass transfer medium and a spaced heat ex¬ changer. The mass transfer medium is operative to ena¬ ble mass transfer between a first fluid, such as blood, and a third fluid, such as oxygen. The mass transfer device includes the aforesaid heat exchanger and means are provided for conveying the first' fluid, such as blood, that has been through the heat exchanger, from the heat exchanger to one area of the mass transfer me¬ dium. The third fluid, such as oxygen, is introduced to another area of the mass transfer medium to enable mass transfer to occur.
In one embodiment of the invention, the. second fluid manifold which- is provided and which is located within the inside of the core comprises a first chamber defined by a first member, and a second chamber defined by a second member. The second fluid is first intro¬ duced into the first chamber and the second fluid is then directed from the first chamber to the second chamber. Means are provided for creating turbulent flow of the second fluid as it exits from the first chamber. In an illustrative embodiment, the first mem¬ ber and second member define openings between the first chamber and the second chamber. A screen member is lo¬ cated between the first chamber and the second chamber. In accordance with the present invention, a proc- ess is provided for making a heat exchanger. The proc¬ ess comprises the steps of providing a flexible metal hose, annealing the flexible metal hose, thereafter compressing the annealed hose, and thereafter expanding the compressed hose to a length that is substantially less than its original length but greater than its length during compression. - A more detailed explanation of the invention is provided in the following description and claims, and is illustrated in the accompanying drawings.
BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 is a perspective view, partially broken for clarity, of a mass transfer device constructed in accordance with the principles of the present inven¬ tion.
Figure 2 is an exploded perspective view of the heat exchanger used in the mass transfer device of Fig¬ ure 1.
Figure 3 is a perspective diagrammatic view of a fluid manifold used in the heat exchanger of Figure. 2. Figure 4 is an elevational view, partially shown in phantom for simplicity, of a heat exchanger con¬ structed in accordance with the principles of the pres¬ ent invention.
Figure 5 is a cross-sectional , elevation of a slightly modified mass transfer device. Figure 6 is a cross-sectional view of the mass transfer device of Figure 5, taken along the plane of the line 6-6 of Figure 5.
Figure 7 is a flow chart of the steps comprising a process of making a heat exchanger core. Figure 8a is a diagrammatic view of a cross- section of a high pressure flexible hose, without show¬ ing the metal thickness.
Figure 8b is a diagrammatic view of a cross- section of a heat exchanger core that has been con- structed from the Figure 8a hose, with the bottom por¬ tion of Figure 8b being a greatly enlarged section of the top portion of Figure 8b.
Figure 9 is an end view of a fluid manifold for the heat exchanger of the present invention, according to another form of the invention, and showing with arrowed lines the fluid flew.
Figure 10 is a perspective view of the manifold of Figure 9.
Figure 11 is a perspective view of an alternative manifold.
DETAILED DESCRIPTION OF THE ILLUSTRATIVE EMBODIMENT
Referring to the drawings, a heat exchanger con¬ structed in accordance with the principles of the pres¬ ent invention is disclosed therein, used in a blood oxygenator environment. In the perspective view of Figure 1, partially broken for clarity, oxygenator 20 includes a molded plastic housing 22 with a first fluid inlet 24 for use as a blood inlet, a first fluid outlet 26 for use as a blood outlet, a second fluid inlet 28 which operates as a water outlet, a second fluid outlet 30 which operates as a water outlet, a third fluid in¬ let 32 which operates as an oxygen inlet, and a third fluid outlet 34 which operates as an oxygen outlet. Housing 22 has a lower portion 36 which encloses the heat exchanger 38.
Referring to Figures 1-6, heat exchanger 38 in¬ cludes a core 40, a manifold 42, end caps 44, inlet port 46 and outlet port 48. In Figures 5 and 6, an oxygenator 20' is illustrated. Oxygenator 20' is simi- lar to oxygenator 20 of Figure 1, but the blood inlet 24" and the blood outlet 26' are at the top of the oxygenator instead of being at the side of the oxygenator as in Figure 1.
As illustrated most clearly in Figures 1 and 5, a passageway 50 couples the heat exchanger 38 with the outside of a mass transfer medium 52. In the illustra¬ tive embodiment, mass transfer medium 52 comprises a hollow fiber bundle in tubular form as is well known in the art, wound about a plastic- core 54. The hollow fi- ber bundle 52 is encapsulated at its ends by means of a potting compound 56, although the ends of the hollow fibers are open to 'form oxygen flow paths as is known in the art. Housing end caps 58 and 60 secure the ends of the mass transfer device assembly. The blood path is into inlet 24, around the out¬ side of heat exchange 38, then around the hollow fiber bundle 52 and out of outlet 26. The cooling and/or heating water flows via inlet port 46 into inlet 28, through manifold 42 and inside the heat exchanger core 40, and out outlet 30 and outlet port.48. The oxygen flows into inlet 32, the fiber bundle and out the out¬ let 34.
To enable the inlet water hose (not shown) and the outlet water hose (not shown) to be connected to inlet port 46 and outlet port 48, respectively, more effec¬ tively, and to alleviate spillage, a snap-on coupling 62 and a corrugated' portion 64 is formed with inlet port 46. Snap-on portion 62 enables the water hose to be snapped onto inlet port 46 and corrugations 64 ena- ble the inlet port 46 to be bent for ease in connection and handling. Likewise, outlet port 48 is formed with snap-on portion 66 and with corrugations 68 to enable an outlet hose to be quick-coupled to outlet port 48 and to enable the. outlet port 48 to bend for ease in connection and handling.
The heat exchanger core 40 of the present inven¬ tion is novel and has been found to be effective to enable substantially uniform flow of the fluids that will be in heat exchange relationship with each other. A construction of heat exchanger core 40 and its method of manufacture are explained as follows, with particu¬ lar reference to Figures 7-8.
The heat exchanger core 40 is formed from a high pressure flexible metal hose, of the type that is often sold in auto parts stores for use as the flexible metal hose for conveying cooling fluid within the engine com- partment. In the illustrative embodiment, the outer di¬ ameter of the flexible hose is 2 inches and the inner diameter is 1.5 inches. Typically, this flexible metal hose is corrugated, with approximately six corrugations per inch.
A broken, enlarged diagrammatic view of portion of this flexible metal hose is presented in Figure 8a. Referring to Figure 8a, it can be seen that the side walls 70, 72 of each corrugation are not parallel to each other. It should be noted that Figures 8a to 8b are not to scale and are diagrammatic only.
The steps for forming heat exchanger core 40 are illustrated in Figure 7. The flexible hose as des¬ cribed above is provided, and it is annealed in an oven. The annealed hose is allowed to cool and is then compressed to between 5 percent and 25 percent of its original length, preferably about 20 percent of its original length. Thereafter the opposite ends are pulled apart so that it is expanded to 1.5 times to 3 times its compressed length, preferably about 2 times its compressed length. Manifold 42 is then inserted into the heat exchanger core and thereafter the end caps and ports are connected and welded to form the re¬ sulting heat exchanger illustrated in Figure 4.' As the flexible metal hose is compressed, side walls 70, 72 are still curvilinear and are not parallel to each other. This will prevent the desirable uniform flow because the flow will favor the more open areas and there will be unsuitable flow in the relatively closed areas. The flexible hose is compressed to about 20 percent of its original length, but flow be¬ comes even more restricted because of the hairpin-type configuration. However, we have discovered that after compression, when the flexible hose is expanded to 1.5 times to 3 times its compressed length, preferably 2 times its compressed length, the side walls 70, 72 be- come substantially parallel with each other, providing more constant volume with substantially uniform flow. Referring to Figure 8b, it can be seen that the result¬ ing heat exchanger core comprises a plurality of con- tiguous corrugations 74, with each of the corrugations having an outer wall 76, a contiguous first side wall 70, a contiguous inner wall 78, and a contiguous second side wall 72, with the first side wall 70 and the sec¬ ond side wall 72 being substantially parallel to each other.
In the illustrative embodiment, the length of the original flexible hose was 22 inches and it had approx¬ imately 6 corrugations per inch. This flexible metal hose is formed of a non-corrosive substance such as stainless steel or aluminum having a high thermal con¬ ductivity, and it was subjected to annealing in an oven . at approximately 1000° F. The annealed hose was then removed from the oven, air cooled and then compressed to a length of 4 inches, in which it had approximately 33 corrugations per inch. The compressed metal hose ' was then expanded so that its length became 7.5 inches having approximately 18 corrugations per inch.
Referring to Figures 2 and 3, the manifold 42 which is inserted into heat exchanger core 40 is illus- trated therein. Manifold 42 operates to distribute the second fluid which flows from inlet 28 to outlet 30 (Figure 1) . Manifold 42 has a generally S-shaped cross sectional configuration, with the S-shape being defined by an intermediate wall 80 having opposed ends 82, 84. first curved member 86 extends from end 82 and toward the other end 84 but spaced therefrom to form a first longitudinal slot 88. A second curved member 90 ex¬ tends from end 84 and toward end 82 but is spaced therefrom to form a second longitudinal slot 92. The second fluid, i.e., water, is introduced into a first chamber 94 defined by one side 80a of intermediate wall 80 and the first curved member 94. The first fluid will flow in chamber 94, out of slot 88, around curved members 86 and 90 in the direction of arrows 96, 97, through slot 92 and into chamber 98 in the direction of arrows 99, 100, through chamber 98 and out of chamber 98. Chamber 98 is defined by side 80b of intermediate member 80 and curved member 90.
It can be seen that the cooling or heating water will flow on the inside of heat exchanger core 40 and the blood will flow on the outside thereof. The blood that has been heat exchanged will then flow into the mass transfer area where it will be oxygenated with the oxygenated blood exiting via blood out let 26.
In another form of the invention, device for pro- viding turbulent flow is utilized. Heat transfer in turbulent flow is significantly greater than heat transfer in laminar fluid flow, due to the turbulence induced mixing. To this end, a turbulence inducer is illustrated in Figures 9-11, which turbulence inducer is intended to achieve greater overall heat transfer.
Referring to Figures 9 and 10, a manifold 42' is shown therein comprising a first chamber 104 and a sec¬ ond chamber 106. The first chamber is defined by a first member having a planar base 108 defining a series of collinear spaced slots 110. Although not all of the slots are illustrated, in the embodiment of Figures 9 and 10, there may be between four and ten slots 110. A first curved member 112 extends from end 114 of base 108 and a second curved member 116 extends from end 118 of base 108. Curved members 112 and 116 extend toward each other but are spaced from each other to define a longitudinal slot 120.
The second chamber 10-6 is defined by a second base member 122 having a third curved member 124 extending from end 126 thereof. A fourth curved member 128 ex¬ tends from end 130 of base 122, with third and fourth curved members 124 and 128 extending toward each other, but being spaced from each other to define a longitudi¬ nal slot 132. Slot 132 is on the opposite side of manifold 42" from slot 120, and the cross-sectional configuration of curved members 112, 116, 124 and 128 is substantially circular. A screen 136 is interposed between base 108 and base 122 to aid in creating the turbulent flow desired. Manifold 42' is inserted into heat exchanger core 40, in the same manner that mani- fold 42 (Figure 2) is inserted into heat exchanger core 40. Water inlet 28 (Figure 1) will introduce the entry water to chamber 104 and most of the water will flow via slot 120, around the outside of the manifold (i.e., inside the heat exchanger core) in the direction of arrowed lines 140, 141, through slit 132 and into cham¬ ber 106, and out the end of chamber 106 opposite to the entry end of chamber 104. Some of the water will flow through slots 110 and pass through screen 136 in the direction of arrowed flow lines 144, 145. This water- will enter the flow at about points 146 and 147 (Figure 9) to enter the flow stream at substantially a right angle, to create turbulence.
In Figure 11, a manifold 42" is illustrated, and it includes an upper member 148 comprising a base 150, a first curved member 152 extending from one end 154 of base 150 and a second curved member 156 extending from end 158 of base 150. Curved members 152 and 156 curve toward each other but are spaced to form a longitudinal slot 160. As illustrated, a series of collinear slots 162 are defined by second curved member 156 toward the junction between curved member 156 and base 150. Like¬ wise, first curved member 152 defines a plurality of collinear slots 164 adjacent the junction between first curved member 152 and base 150. The upper member 148 illustrated in Figure 11 defines a first chamber 165. A second chamber 167 is defined by a connected lower member 149 including base 168, third curved member 170 and fourth curved member 172. Curved members 170 and 172 curve toward each other and are spaced to form a slot 174. The water will flow into the first chamber 165 de¬ fined by the upper member 148 with some of the water flowing up through slot 160 and around the outside of the manifold, then back into slot 174 and out the sec¬ ond chamber 167. Some of the water from the first chamber 165 will flow through slots 162 and 164 to en¬ ter the outside flow at an angle to the flow stream to create turbulence.
A disposable blood oxygenator has been disclosed that is relatively compact, has a low prime volume, is easy to manufacture and has a relatively low cost. The heat exchanger in accordance with the present invention enables substantially uniform flow of the fluid that will be in heat exchange relationship with each other.
Although illustrative embodiments of the invention have been shown and desribed, it is to be understood that various modifications and substitutions may be made by those skilled in the art without departing from the novel spirit and scope of the present invention.

Claims

WHAT IS CLAIMED IS:
1. A heat exchanger which comprises: a core having an inside and an outside and formed of a corrugated metal having a high thermal conductivi- ty, each of the corrugations of the core comprising an outer wall, a contiguous first side wall, a contiguous inner wall, and a contiguous second side wall, with the first and second side walls being substantially paral¬ lel to each other, and with a plurality of said corru- gations repeating contiguously; means for introducing a first fluid onto the out¬ side of the core and means for introducing a second fluid into the inside of the core, whereby the first and second fluids will be in heat exchange relationship with each other and the flow of the fluids is substan¬ tially uniform resulting from the substantially paral¬ lel first and second side- walls of the corrugations.
2. A heat exchanger as described in Claim 1, wherein the core is formed by the steps of providing a flexible metal hose, annealing the flexible metal hose, compressing the annealed hose and expanding the com¬ pressed hose to a length that is substantially less than its original length but greater than its length during compression.
3. A heat exchanger as described in Claim 2, in¬ cluding the step of cooling the annealed hose prior to compression.
4. A heat exchanger as described in Claim 2, wherein the hose is compressed to between 5 percent and 25 percent of its original length and is expanded to 1.5 times to 3 times its compressed length.
5. A heat exchanger as described in Claim 4, in which the hose is compressed to about 20 percent of its original length and is expanded to about two times its compressed length.
6. A heat exchanger as described in Claim 1, in which the core has between about 12 and about 24 corru¬ gations per inch.
7. A heat exchanger as described, in Claim 6, in which the core has about 18 corrugations per inch.
8. A heat exchanger as described in Claim 1, in¬ cluding a second fluid manifold located within the in¬ side of the core, the manifold comprising a generally S-shaped cross-sectional configuration.
9. A heat exchanger as described in Claim 8, wherein the S-shape is defined by an intermediate wall having opposed ends with a first curved member extend¬ ing from one end and toward the other end but spaced therefrom to form a first slot, and with a second curved member extending from the other end and toward said one end but spaced therefrom to form a second slot; said second fluid-introducing means operating to introduce the second fluid into a first chamber defined by one side of said intermediate wall and said first curved member, whereby the second fluid will exit from a second chamber defined by the opposite side of said intermediate wall and said curved member.
10. A heat exchanger as described in Claim 9, the S-shape being configurated so that the second fluid will move in said first chamber, through said first slot, around the outside of said first and second curved members, into said second slot and out from said second chamber.
11. A heat exchanger which comprises: a core having an inside and an outside and formed of a corrugated metal having a thermal conductivity; means for introducing a first fluid onto the out¬ side of the core and means for introducing a second fluid into the inside of the core, whereby the first and second fluids will be in heat exchange relationship with each other; a second fluid manifold located within the inside of the core, the manifold comprising a generally S- shaped cross-sectional configuration, with the S-shape being defined by an intermediate wall having opposed ends with a first curved member extending from one end and toward the other end but spaced therefrom to form a first slot, and with a second curved member extending from the other end and toward said one end but spaced therefrom to form a second slot; said second fluid-introducing means operating to introduce the second fluid into a first chamber defined by one side of said intermediate wall and said first curved member, whereby the second fluid will exit from a second chamber defined by the opposite side of said intermediate wall and said .second curved member; . the S-shape being configurated so that the second fluid will move in said first chamber, through said first slot, around the outside of said first and second curved members, into said second slot, and out from said second chamber.
12. A heat exchanger as described in Claim 11, in which each of the corrguations of the core comprises an outer wall, a contiguous first side wall, a contigu¬ ous inner wall, and a contiguous second side wall, with the first and second side, walls being substantially - -
parallel to each other, and with a plurality of said corrugations repeating contiguously; said core being formed by the steps of providing a flexible metal hose, annealing the flexible metal hose, compressing the annealed hose and expanding the com¬ pressed hose to a length that is substantially less than its original length but greater than its length during compression.
13. In a mass transfer device having a housing which encloses a mass transfer medium and a spaced heat exchanger, with the mass transfer medium being opera¬ tive to enable mass transfer between a first fluid and a third fluid, the improvement comprising: a heat exchanger comprising a core having an in¬ side and an outside and formed of a corrugated metal having a high- thermal conductivity, each of -the corru¬ gations of the core comprising an outer wall, a contig¬ uous first side wall, a contiguous inner wall, and a contiguous second side wall, with the first and second side walls being substantially parallel to each other, and with a plurality of said corrugations repeating contiguously; means for introducing said first fluid onto the outside of the core and means for introducing a second fluid into the inside of the core, whereby the first and second fluids will be in heat exchange relationship with each other and the flow of the fluids is substan¬ tially uniform resulting from the substantially paral¬ lel first and second side walls of the corrugations; means for conveying the first fluid that has been heat exchanged from the heat exchanger to one area of the mass transfer medium; and means for introducing said third fluid to another area of the mass transfer medium to enable mass trans¬ fer to occur.
14. In a mass transfer device as described in Claim 13, wherein said first fluid is blood, said sec¬ ond fluid is water, said third fluid is oxygen; and said mass transfer medium is a medium for oxygenating blood.
15. In a mass transfer device as described in Claim 14, wherein said mass transfer medium is a fiber bundle.
16. In a mass transfer device as described in Claim 13, wherein said first fluid is blood, said sec¬ ond fluid is water, said third fluid is dialysis solu¬ tion; and said mass transfer medium is a medium for dialyzing blood.
17. In a mass transfer device as described in Claim 13, wherein the core is formed by the steps of providing a flexible metal hose, annealing the flexible metal hose, compressing .the annealed hose and expanding the compressed hose to a length that is substantially less than its original length but greater than its length during compression.
18. In a mass transfer device as described in Claim 13, a second fluid manifold located within the inside of the core, the manifold comprising a generally S-shaped cross-sectional configuration.
19. In a mass transfer device as described in Claim 18, wherein the S-shape is defined by an interme¬ diate wall having opposed ends with a first curved mem¬ ber extending from one end and toward the other end but spaced therefrom to form a first slot, and with a sec- ond curved member extending from the other end and to¬ ward said one end but spaced therefrom to form a second slot; said second fluid-introducing means operating to introduce the second fluid into a first chamber defined by one side of said intermediate wall and said first curved member, whereby the second fluid will exit from a second chamber defined by the opposite side of said intermediate wall and said second curved member.
20. In a mass transfer device as described in Claim 19, the S-shape being configurated so that the second fluid will move in said first chamber, through said first slot, around the outside of said first and second curved members, into said second slot and out from said second chamber.
21. In a mass transfer device as described in Claim 13, said means for introducing said second fluid including an inlet member that is corrugated to permit manual flexing thereof.
22. ' In a mass transfer device as described in Claim 13, wherein said first fluid is blood and said second fluid is water.
23. A mass transfer device which comprises: a mass transfer medium; a heat exchanger spaced from said mass tran'sfer medium; a housing enclosing said mass transfer medium and heat exchanger; a first fluid inlet to said housing; a first fluid outlet from said housing; a second fluid inlet to said housing; a second fluid outlet from said housing; a third fluid inlet to said housing; a third fluid outlet from said housing; said mass transfer medium being positioned and op- erable to enable mass transfer between said first fluid and said third fluid; said heat exchanger comprising a core having an inside and an outside and formed of a corrugated metal having a high thermal conductivity, each of the corru¬ gations of the core comprising an outer wall, a contig¬ uous first side wall, a contiguous inner wall, and a contiguous second side wall, with the first and second side walls being substantially parallel to each other, and with a plurality of said corrugations repeating contiguously; said first inlet being operative to introduce the first fluid onto the outside of the core; said second inlet being operative to introduce said second fluid into the inside of said core; said third inlet being operative to introduce said third fluid into said mass transfer medium; .and means for conveying the first fluid that has been through the heat exchanger, from the heat exchanger to one area of the mass transfer medium.
24. A mass transfer device as described in Claim 23, in which said first fluid is blood, said second fluid is water, said third fluid is oxygen, and said mass transfer medium is a medium for oxygenating blood.
25. A mass transfer device as described in Claim 23, wherein said first fluid is blood, said second fluid is water, said third fluid is dialysis solution, and said mass transfer medium is a medium for dialyzing blood.
26. A mass transfer device as described in Claim 23, wherein the core is formed by the steps of provid¬ ing a flexible metal hose, annealing the flexible metal hose, compressing the annealed hose and expanding the compressed hose to a length that is substantially less than its original length but greater than its length during compression.
27. A mass transfer device as described in Claim 23, including a second fluid manifold located within the inside of the core, the manifold comprising a gen¬ erally S-shaped cross-sectional configuration.
28. A mass transfer device as de-scribed in Claim
27, in which the S-shape is defined by an intermediate wall having opposed ends with a first curved member ex¬ tending from one end and toward the other end but spaced therefrom to form a first slot, and with a sec¬ ond curved member extending from the other end and to¬ ward said one end but spaced therefrom to form a second slot; said second fluid-introducing means operating to introduce the second fluid into a first chamber defined by one side of said intermediate wall and said first curved member, whereby the second fluid will exit from a second chamber defined by the opposite side of said intermediate wall and said second curved member.
29. A mass transfer device as described in Claim
28, the S-shape being configurated so that the second fluid will move in said first chamber, through said first slot, around the outside of said first and second curved members, into said second slot, and out from said second chamber.
30. A mass transfer device as described in Claim 23, said means for introducing said second fluid -in¬ cluding an inlet member that is corrugated to permit manual flexing thereof.
31. A process for making a heat exchanger, com¬ prising the steps of: providing a flexible metal hose; annealing the flexible metal hose; thereafter compressing the annealed hose; and thereafter expanding the compressed hose to a length that is substantially less than its original length but greater than its length during compression.
32. A process as described in Claim 31, including the step of cooling the annealed hose prior to compres¬ sion.
33. A process as described in Claim 31, wherein the hose is compressed to between 5 percent and 20 per¬ cent of its original length and is expanded to about 1.5 times to about 3 times its compressed length.
34. A process, as described in Claim 33, in which the hose is compressed to about 20 percent of its original length and is expanded to about 2 times its compressed length.
35. A process as described in Claim 31, in which the resulting hose is. used as a heat exchanger core and has between about 12 and about 24 corrugations per inch.
36. A heat exchanger which comprises: a core having an inside and an outside and formed of a corrugated metal having a high thermal conductivi¬ ty, each of the corrugations of the core comprising an outer wall, a contiguous first side wall, a contiguous inner wall, and a contiguous second side wall, with the first and second side walls being substantially paral¬ lel to each other, and with -a plurality of said corru- gations repeating contiguously; means for introducing a first fluid onto the out¬ side of the core and means for introducing a second fluid into the inside of the core, whereby the first and second fluids will be in heat exchange relationship with each other and the flow of the fluids is substan¬ tially uniform resulting from the substantially paral¬ lel first and second side walls of the corrugations; a second fluid manifold located within the inside of the hose, the manifold comprising a first chamber defined by a first member, a second chamber defined by a second member, said means for introducing the second fluid being connected to first introduce the second fluid to said first chamber, means for directing the second fluid from said first chamber to said second chamber, and means for creating turbulent flow of the second fluid as it exits .from .the first chamber.
37. A heat exchanger as described in Claim 36, said members defining openings between said first cham- ber and said second chamber.
38. A heat exchanger as described in Claim 37, including a screen member located between the first chamber and the second chamber.
39. A heat exchanger as described in Claim 36, wherein said creating means comprise openings defined by said first member.
PCT/US1985/000127 1984-02-27 1985-01-25 Heat exchanger for mass transfer device WO1985004002A1 (en)

Priority Applications (1)

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Applications Claiming Priority (2)

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US58385384A 1984-02-27 1984-02-27
US583,853 1984-02-27

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JP (1) JPS61501279A (en)
CA (1) CA1272711A (en)
DE (1) DE3563477D1 (en)
IT (1) IT1183416B (en)
WO (1) WO1985004002A1 (en)

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Also Published As

Publication number Publication date
EP0174319A1 (en) 1986-03-19
EP0174319B1 (en) 1988-06-22
IT8519635A0 (en) 1985-02-25
DE3563477D1 (en) 1988-07-28
JPS61501279A (en) 1986-06-26
JPH0559354B2 (en) 1993-08-30
EP0174319A4 (en) 1986-07-08
CA1272711A (en) 1990-08-14
IT1183416B (en) 1987-10-22

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