The present disclosure relates to heat exchangers, and in particular to ram mounting flanges for plate fin heat exchangers.
Heat exchangers are often used to transfer heat between two fluids. For example, in aircraft environmental control systems, heat exchangers may be used to transfer heat between a relatively hot air source (e.g., bleed air from a gas turbine engine) and a relatively cool air source (e.g., ram air). Some heat exchangers, often referred to as plate fin heat exchangers, include a plate fin core having multiple heat transfer sheets arranged in layers to define air passages there between. Closure bars seal alternating inlets of hot air and cool air inlet sides of the core. Accordingly, hot air and cool air are directed through alternating passages to form alternating layers of hot and cool air within the core. Heat is transferred between the hot and cool air via the heat transfer sheets that separate the layers. In addition, to facilitate heat transfer between the layers, each of the passages can include heat transfer fins, often formed of corrugated material (e.g., aluminum), that are oriented in a direction of the flow within the passage. The heat transfer fins increase turbulence and a surface area that is exposed to the airflow, thereby enhancing heat transfer between the layers.
As hot air passes over components of the plate fin heat exchanger (e.g., closure bars, heat transfer fins, and other components), differing thermal expansion properties of the various components can cause the components to expand at different rates. Overall expansion of the core is typically restricted by, for example, housings of the core or other peripheral components of the plate fin heat exchanger. Restricted thermal expansion of the core can cause thermally-induced stress to components of the core, thereby reducing longevity and reliability of the plate fin heat exchanger.
In one example, a plate fin heat exchanger includes a plate fin core having a plurality of plates defining a set of hot air passages extending from a hot air inlet region of the plate fin core to a hot air outlet region of the plate fin core and a set of cool air passages extending from a cool air inlet region of the plate fin core to a cool air outlet region of the plate fin core. The plate fin heat exchanger further includes a mounting flange circumscribing the cool air outlet region. At least a portion of the mounting flange has a plurality of heat transfer structures that extend into a flow path of cooling air exiting the cool air outlet region of the plate fin core.
In another example, a method includes directing hot air through a set of hot air passages of a core of a plate fin heat exchanger. The set of hot air passages extend in a first direction. The method further includes directing cool air through a set of cool air passages of the core of the plate fin heat exchanger. The set of cool air passages extend in a second direction. The method further includes flowing a portion of the cool air over a plurality of heat transfer structures of a mounting flange that circumscribes a cool air outlet region of the core of the plate fin heat exchanger.
According to techniques described herein, a plate fin heat exchanger includes a mounting flange that circumscribes a cool air outlet region of a core of the plate fin heat exchanger. The disclosed flange includes a plurality of heat transfer structures, such as heat transfer fins, that extend into a flow path of cooling air exiting the cool air outlet. In some examples, the heat transfer structures are disposed at a portion of the flange that is proximate a hot-hot region of the plate fin heat exchanger. The hot-hot region is a region of the heat exchanger that is proximate both a hot air inlet region and the cool air outlet region of the plate fin heat exchanger. The plurality of heat transfer structures of the flange transfer heat from the cooling air (which is at its hottest when exiting the cool air outlet) to the mounting flange, thereby causing the mounting flange to expand at a rate that is more similar to a rate of expansion of elements of the core of the heat exchanger. In this way, the disclosed mounting flange helps to decrease thermally-induced stress on components of the heat exchanger, such as those components near the hot-hot region, thereby increasing the longevity of such components.
Heat transfer plates 24 of plate fin core 16 are arranged in parallel to define a plurality of flow passages there between. As illustrated, heat transfer plates 24 can be generally rectangular plates arranged in parallel layers to define flow passages (e.g., air flow passages) through gaps between the layers. Heat transfer plates 24 can be formed of one or more materials having a relatively high heat transfer coefficient, such as aluminum, copper, silver, gold, or other materials, thereby facilitating efficient heat transfer between air flows through alternating layers.
As in the example of
Plate fin core 16 includes cool air closure bars 26 disposed at hot air inlet side 34 and hot air outlet side 36 of plate fin core 16. As illustrated, cool air closure bars 26 (i.e., a set of cool air closure bars 26) are arranged at hot air outlet side 36 in close physical proximity to the set of cool air flow passages 32 (e.g., by welding, brazing, or other attachment techniques) to seal the set of cool air flow passages 32 against ingress of hot air at hot air outlet side 36. While illustrated as including cool air closure bars 26 arranged at hot air outlet side 36, it should be understood that plate fin core 16 includes similar cool air closure bars 26 disposed at hot air inlet side 34 opposite hot air outlet side 36. That is, each of cool air flow passages 32 is sealed against ingress of hot air at both hot air inlet side 34 and hot air outlet side 36 of plate fin core 16 by a set of cool air closure bars 26. In this way, cool air closure bars 26 are configured to seal cool air flow passages 32 (i.e., a set of alternating flow passages of plate fin core 16) against ingress of hot air, thereby directing hot air received from a hot air source (e.g., engine bleed air from a gas turbine engine, compressed air from an air compressor such as a cabin air compressor, or other hot air sources) into hot air flow passages 30.
Plate fin core 16 further includes hot air closure bars 28 disposed at cool air inlet side 38 and cool air outlet side 40 of plate fin core 16. As illustrated, hot air closure bars 28 are arranged at cool air outlet side 40 in close physical proximity to the set of hot air flow passages 30 (e.g., by welding, brazing, or other attachment techniques) to seal the set of hot air flow passages 30 against ingress of cool air at cool air outlet side 40. While illustrated as including hot air closure bars 28 arranged at cool air outlet side 40, it should be understood that plate fin core 16 includes similar hot air closure bars 28 disposed at cool air inlet side 38 opposite cool air outlet side 40. That is, each of hot air flow passages 30 is sealed against ingress of cool air at both cool air inlet side 38 and cool air outlet side 40 of plate fin core 16 by a set of hot air closure bars 28. In this way, hot air closure bars 28 are configured to seal hot air flow passages 30 (i.e., a set of alternating flow passages of plate fin core 16) against ingress of cool air, thereby directing cool air received from a cool air source (e.g., ram air) into cool air flow passages 32.
As illustrated in
According to techniques disclosed herein, at least a portion of mounting flange 12 can include a plurality of heat transfer structures that extend into a flow path of cooling air exiting cool air outlet side 40 of plate fin core 16. For example, as illustrated in
Hot-hot region 46 is a region of plate fin heat exchanger 10 that is proximate both hot air inlet 18 and cool air outlet side 40. That is, as cooling air (e.g., ram air) travels from cool air inlet side 38 to cool air outlet side 40 of plate fin core 16, heat transfers from hot air flowing through hot air flow passages 30 to the cooling air flowing through cool air flow passages 32 via heat transfer plates 24 separating the passages. Accordingly, the temperature of the cooling air increases from cool air inlet side 38 to cool air outlet side 40, thereby achieving a maximum temperature of the cooling air proximate cool air outlet side 40. Hot air (e.g., engine bleed air from a gas turbine engine, compressed air from an air compressor such as a cabin air compressor, etc.) is received via hot air inlet 18 and directed toward hot air inlet side 34 of plate fin core 16 by, for example, a hot air manifold. As such, hot-hot region 46, proximate both hot air inlet 18 and cool air outlet side 40, can correspond to a highest temperature of air flowing through plate fin core 16. Accordingly, components of plate fin heat exchanger 10 near hot-hot region 46 (e.g., closure bars, heat transfer plates, heat transfer fins disposed between heat transfer plates, or other components) can be exposed to higher temperature air flow than components that are farther away from hot-hot region 46, thereby causing greater amounts and/or rates of expansion (e.g., volumetric and/or linear expansion) of those components near hot-hot region 46.
Heat transfer structures 22, extending into cool air flow path Ac of cooling air exiting cool air outlet side 40, can transfer heat from the cooling air to mounting flange 12, thereby increasing the rate of expansion of that portion of mounting flange 12. In this way, heat transfer structures 22 can help decrease a difference between a rate of expansion of mounting flange 12 and a rate of expansion of other components of plate fin core 16 (e.g., closure bars, heat transfer fins between heat transfer plates, and the like) that are exposed to air exiting cool air outlet side 40. As such, heat transfer structures 22 can help decrease thermally-induced stress to such components, thereby increasing longevity of the components.
In an example operation of plate fin heat exchanger 10, hot air is received by plate fin heat exchanger 10 via hot air inlet 18 from a hot air source, such as engine bleed air from a gas turbine engine. The hot air received via hot air inlet 18 is directed toward hot air inlet side 34 of plate fin core 16 by hot air inlet manifold 19. Cool air closure bars 26, arranged at hot air inlet side 34 of plate fin core 16, seal cool air flow passages 32 from ingress of the hot air, thereby directing the hot air into hot air flow passages 30 (i.e., an alternating set of air passages of plate fin core 16). Accordingly, hot air flows through hot air flow passages 30 of plate fin core 16 along hot air flow path AH and exits plate fin core 16 at hot air outlet side 36. Hot air exiting hot air outlet side 36 is collected by hot air outlet manifold 21 and directed toward hot air outlet 20. Cool air is received by plate fin heat exchanger 10 via a cool air inlet from a cool air source, such as ram air accumulated from an aircraft. The cool air is directed toward cool air inlet side 38 of plate fin core 16 by, for example, a cool air manifold. Hot air closure bars 28 seal hot air flow passages 30 from ingress of the cool air, thereby directing the cool air into cool air flow passages 32 (i.e., an alternating set of passages of plate fin core 16 that is complementary to the set of hot air flow passages 30). As such, cool air flows through cool air flow passages 32 of plate fin core 16 along cool air flow path AC and exits plate fin core 16 at cool air outlet side 40.
In operation, heat transfers between the alternating sets of hot air flow passages 30 and cool air flow passages 32 via heat transfer plates 24 that separate the layers. Hot air fins 15 disposed within hot air flow passages 30, and cool air fins 17 disposed within cool air flow passages 32 enhance heat transfer between the layers. Cooling air increases in temperature as it travels through cool air flow passages 32 from cool air inlet side 38 to cool air outlet side 40. As such, components of plate fin core 16 proximate hot-hot region 46 and exposed to airflow expand at a greater rate than those components farther away from hot-hot region 46 and/or not exposed to airflow. Such expansion can be restricted by mounting flange 12 and other peripheral components, such as a housing of plate fin heat exchanger 10. Heat transfer structures 22, extending from at least a portion of mounting flange 12 (e.g., a portion of mounting flange 12 proximate hot-hot region 46) into cool air flow path AC can transfer heat from cooling air exiting cool air outlet side 40 to mounting flange 12, thereby increasing a rate of expansion of mounting flange 12 and decreasing thermally-induced stress on components of plate fin core 16 that can result from restricted expansion. In this way, mounting flange 12, including heat transfer structures 22, can increase longevity of components of plate fin core 16.
While mounting flange 12 is illustrated in the example of
As illustrated, heat transfer structures 22 extend from first face 50 in a direction toward cool air flow path AC, thereby extending into cool air flow path AC of cooling air exiting cool air outlet side 40. In some examples, heat transfer structures 22 and mounting flange 12 can be formed of a contiguous piece of material, such as a contiguous piece of aluminum, stainless steel, or other materials. For instance, heat transfer structures 22 can be machined out of mounting flange 12, such that heat transfer structures 22 and mounting flange 12 are formed from a single piece of the same material. In other examples, heat transfer structures 22 can be attached to mounting flange 12, such as by welding, brazing, or other attachment techniques. In such examples, heat transfer structures 22 can be formed of a same or different material than mounting flange 12.
While heat transfer structures 22 are illustrated in the example of
The following are non-exclusive descriptions of embodiments of the present disclosure.
A plate fin heat exchanger includes a plate fin core having a plurality of plates defining a set of hot air passages extending from a hot air inlet region of the plate fin core to a hot air outlet region of the plate fin core and a set of cool air passages extending from a cool air inlet region of the plate fin core to a cool air outlet region of the plate fin core. The plate fin heat exchanger further includes a mounting flange circumscribing the cool air outlet region. At least a portion of the mounting flange has a plurality of heat transfer structures that extend into a flow path of cooling air exiting the cool air outlet region of the plate fin core.
The plate fin heat exchanger of the preceding paragraph can optionally include, additionally and/or alternatively, any one or more of the following features, configurations, and/or additional components:
The plurality of heat transfer structures can comprise a plurality of heat transfer fins.
The plate fin heat exchanger can further comprise a hot air inlet proximate the hot air inlet region of the plate fin core. The plurality of heat transfer structures of the mounting flange can be proximate the hot air inlet.
The hot air inlet can be configured to receive at least one of bleed air from a gas turbine engine and compressed air from an air compressor.
The mounting flange and the plurality of heat transfer structures can be formed of a contiguous piece of material.
The material can comprise aluminum.
The hot air inlet region of the plate fin core can be disposed at a first side of the plate fin core. The hot air outlet region of the plate fin core can be disposed at a second side of the plate fin core opposite the first side of the plate fin core.
The cool air inlet region of the plate fin core can be disposed at a third side of the plate fin core that is orthogonal to the first and second sides of the plate fin core. The cool air outlet region of the plate fin core can be disposed at a fourth side of the plate fin core that is opposite the third side and orthogonal to the first and second sides of the plate fin core.
The plurality of heat transfer structures of the mounting flange can be disposed along a leg of the mounting flange that extends along an intersection of the first and fourth sides of the plate fin core.
The mounting flange can comprise a first face disposed parallel the flow path of the cooling air exiting the cool air outlet region of the plate fin core and a second face disposed orthogonal the first face and extending in a direction away from the flow path of the cooling air. The plurality of heat transfer structures can extend from the first face into the flow path of the cooling air exiting the cool air outlet region of the plate fin core.
The second face of the mounting flange can be configured to mount with at least one external component.
The set of hot air passages and the set of cold air passages can comprise alternating sets of passages.
The plate fin heat exchanger can further comprise a cool air inlet proximate the cool air inlet region of the plate fin core.
The cool air inlet can be configured to receive ram air.
A method includes directing hot air through a set of hot air passages of a core of a plate fin heat exchanger. The set of hot air passages extend in a first direction. The method further includes directing cool air through a set of cool air passages of the core of the plate fin heat exchanger. The set of cool air passages extend in a second direction. The method further includes flowing a portion of the cool air over a plurality of heat transfer structures of a mounting flange that circumscribes a cool air outlet region of the core of the plate fin heat exchanger.
The method of the preceding paragraph can optionally include, additionally and/or alternatively, any one or more of the following features, configurations, additional components and/or operations:
The plurality of heat transfer structures can comprise a plurality of heat transfer fins.
Flowing the portion of the cool air over the plurality of heat transfer structures of the mounting flange can comprise flowing the portion of the cool air over the plurality of heat transfer structures of the mounting flange disposed at a hot-hot region of the plate fin heat exchanger.
The hot-hot region of the plate fin heat exchanger can comprise a region of the plate fin heat exchanger that is proximate a hot air inlet region of the plate fin heat exchanger and the cool air outlet region of the plate fin heat exchanger.
The first direction can be orthogonal to the second direction.
Directing the hot air through the set of hot air passages of the core of the plate fin heat exchanger can comprise directing the hot air through a hot air inlet region of the core of the plate fin heat exchanger disposed at a first side of the core of the plate fin heat exchanger, and directing the hot air through a hot air outlet region of the core of the plate fin heat exchanger disposed at a second side of the core of the plate fin heat exchanger. The second side can be opposite the first side.
Directing the cool air through the set of cool air passages of the core of the plate fin heat exchanger can comprise directing the cool air through a cool air inlet region of the core of the plate fin heat exchanger disposed at a third side of the core of the plate fin heat exchanger that is orthogonal to the first and second sides of the core of the plate fin heat exchanger, and directing the cool air through the cool air outlet region of the core of the plate fin heat exchanger. The cool air outlet region can be disposed opposite the third side and orthogonal to the first and second sides of the core of the plate fin heat exchanger.
While the invention has been described with reference to an exemplary embodiment(s), 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 of the invention. In addition, many modifications may be made to adapt a particular situation or material to the teachings of the invention without departing from the essential scope thereof. Therefore, it is intended that the invention not be limited to the particular embodiment(s) disclosed, but that the invention will include all embodiments falling within the scope of the appended claims.
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The European Search Report mailed Apr. 2, 2015 for European Application No. 14171812. |
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