This invention relates to heat transfer and, more particularly, to heat exchangers. Heat exchangers are widely known and used to transfer heat from one fluid to another fluid for a desired purpose. One conventional heat exchanger is a tube and fin type that generally includes fluid transfer tubes and heat conducting fins between the tubes. A fluid flows through the tubes and another fluid flows over the fins. Heat from the higher temperature one of the fluids is transferred through the tubes and fins to the other, lower temperature fluid to cool the higher temperature fluid and heat the lower temperature fluid.
Although conventional tube and fin heat exchangers are effective in many applications, alternative arrangements are sometimes desired to meet the needs of other applications. Thus, there is a desire for novel heat exchangers, such as a metal foam heat exchanger, and systems utilizing the same. This invention addresses those needs while avoiding the shortcomings and drawbacks of the prior art.
An example heat exchanger includes one or more passages and one or more metal foam sections adjacent the passage to promote an exchange of heat relative to the passage. The metal foam section includes a nominal thermal conductivity gradient there through to provide a desirable balance of heat exchange properties within the metal foam section.
In another aspect, an example heat exchanger includes a first passage and a second passage arranged in a heat exchange relation relative to the first passage such that the first passage is within the second passage. One or more metal foam sections are disposed within the first passage to promote an exchange of heat between the first passage and the second passage.
In another aspect, an example heat exchanger system for use in an aircraft includes an aircraft device operative to circulate a fluid through one or more heat exchangers having a passage for receiving the heated fluid and a metal foam section adjacent the passage to promote an exchange of heat for cooling of fluid.
The various features and advantages of this invention will become apparent to those skilled in the art from the following detailed description of the currently preferred embodiment. The drawings that accompany the detailed description can be briefly described as follows.
In the illustrated example, the second passage 14 includes a metal foam section 16 that promotes heat exchange between the first fluid and the second fluid. In this example, the metal foam section 16 is within the second passage 14, however, as will be described below, the metal foam section 16 may alternatively be located within the first passage 12. The metal foam section 16 provides the benefit of promoting heat conduction between the first passage 12 and the second passage 14 by providing surface area to conduct the heat through. The metal foam section 16 includes an open cell structure that permits fluid flow there through such that the second fluid flowing through the second passage 14 flows over the surfaces of the metal foam section 16 to exchange heat to or from the metal foam section 16. The meal foam section 16 thereby conducts the heat with the first passage 14. The metal foam section 16 also mixes the second fluid as it flows through the cells of the metal foam section 16. The mixing promotes greater contact between the second fluid and the surfaces of the metal foam section 16, thereby increasing heat exchange between the second fluid and the metal foam section.
In the illustrated example, the metal foam section 16 includes a nominal thermal conductivity gradient 18 there through. The nominal thermal conductivity gradient 18 provides a first nominal thermal conductivity within the metal foam section 16 near the first passage 12 that changes as a function of distance from the first passage 12. Although the nominal thermal conductivity gradient 18 is shown in a certain direction in the examples herein, it is to be understood that the nominal thermal conductivity gradient direction may be altered as desired using the principles described herein. As seen for example in
In one example, the line 20 represents a linear relation between the nominal thermal conductivity gradient 18 and distance from the first passage 12. In another example shown by the line 22, the nominal thermal conductivity drops sharply as a function of distance from the first passage 12. In two other examples represented by lines 24 and 26, respectively, the nominal thermal conductivity gradient 18 changes non-linearly as a function of distance from the first passage 12. It is to be understood that the nominal thermal conductivity gradient 18 may have other profiles than what is shown in examples in
Referring to the example of
In one example, the proximal section 36 has an effective density that is greater than the effective density of the distal section 38. Thus, the proximal section 36 provides a greater local heat exchanging effect, with a local relative pressure drop penalty. The distal section 38 provides relatively better local flow-through, with a relative local penalty in heat exchange properties. The metal foam section 16 thereby provides the benefit of greater heat exchange near the perimeter of the first passage (i.e., where a significant portion of thermal energy transfer occurs) without the overall pressure drop penalty that would occur if the entire metal foam section 16 were made of the greater effective density. In some embodiments however, the pressure drop or thermal energy transfer requirements may not be as much of a concern. Thus, the metal foam section 16 can also have a uniform nominal thermal conductivity (i.e., no nominal thermal conductivity gradient 18) with a nominally uniform effective density throughout.
In another example similar to the above example using effective density, the porosities of the sections 35 and 38 differ. The porosity of the metal foam section 16 is another factor that controls the heat exchange and flow-through properties of the heat exchanger 10. In this example, the proximal section 36 includes a first porosity and the distal section 38 includes a second porosity that is greater than the first porosity. In general, a relatively low porosity provides a greater local heat exchanging effect but obstructs flow of the second fluid, which results in a nominal pressure drop. In contrast, a relatively high porosity provides a lesser local heat exchanging effect but less obstruction of flow. Thus, selecting porosities of the proximal section 36 and the distal section 38 for a desired nominal thermal conductivity gradient 18 within the metal foam section 16 allows one to tailor the heat exchange and pressure drop effects within the heat exchanger 10. Given this description, one of ordinary skill in the art will recognize other metal foam features that can be varied to provide desirable thermal conductivity gradients.
In the illustrated example, the metal foam section 16 is made of a high temperature resistant material that is suitable to withstand the pressures and temperatures associated with operation within an aircraft. For example, the metal foam section 16 is made of nickel, titanium, nickel-based alloy, or mixtures thereof. These materials provide the advantage of relatively high strength, high temperature resistance, oxidation resistance, and chemical resistance to high temperature aircraft fluids. For some lower temperature applications, aluminum may also be used for the metal foam section 16.
In another example, a first type of material is used for the proximal section 36 and a second, different type of material is used for the distal section 38. For example, a material having a relatively high thermal conductivity is used for the proximal section 36 and a material having a relatively lower thermal conductivity is used for the distal section 38 to achieve the nominal thermal conductivity gradient 18. In this example, the pore densities within the proximal section 36 and the distal section 38 may be similar or may be different to further enhance the nominal thermal conductivity gradient 18 as desired. As will be described in the examples below, the principles explained for the previous examples (e.g., nominal thermal conductivity gradient 18, effective density gradient, uniform effective density, porosity, etc.) are applicable in a variety of different configurations.
For example, as seen in the embodiment shown in
In another example embodiment shown in
The examples above illustrate a few example constructions of the heat exchanger 10.
Optionally, the turbine cooling system 70 includes an upstream unit 84 that suppresses coking in the fuel and enables the fuel to function as a heat sink. For example, the upstream unit 84 includes a fuel deoxygenator unit, protective coatings on surfaces of the upstream unit 84 to prevent adherence of coking products, special fuel compositions that inhibit oxidation of the fuel, or combinations thereof.
The second cooling loop 102b includes an oil tank 110 associated with an aircraft gas turbine engine 72′. Oil from the oil tank 110 circulates through an oil circulation line 112 through a third heat exchanger 103 and fourth heat exchanger 104, which provide progressive cooling of the oil. In the illustrated example, the third heat exchanger 103 is an air-to-liquid heat exchanger and the fourth heat exchanger 104 is a liquid-to-liquid heat exchanger similar to heat exchangers 101 and 102, respectively. The oil circulates from the oil tank 110 through the heat exchangers 103 and 104 and is used for lubricating a gear box 114, fan gear 116, or gas turbine engine main bearing 118 of the gas turbine engine 72′.
As can be appreciated, the heat loads and pressures produced within either of the cooling loops 102a and 102a can be relatively high compared to non-aerospace applications. Thus, in some cases, it may be desirable to utilize the previously mentioned high temperature materials to withstand the temperatures and pressures associated with the circulation lines 106 and 112.
Although a preferred embodiment of this invention has been disclosed, a worker of ordinary skill in this art would recognize that certain modifications would come within the scope of this invention. For that reason, the following claims should be studied to determine the true scope and content of this invention.
This invention was made with support of the Office of Naval Research under Contract No.: N00014-00-2-0002. The government therefore has certain rights in this invention.