The present invention relates to a heat shield and, more specifically, to an air-cooled heat reflective shield.
Heat shields protect an object or gaseous area from heat. More specifically, in many applications heat shields attempt to limit conductive, convective, and/or radiant heat transfer. Conductive heat transfer refers to the transfer of heat across a medium, whether the medium is solid or fluid. Convective heat transfer occurs between a moving fluid and a surface of an object. Radiant heat transfer occurs when excited atoms emit electromagnetic radiation, which travels from the heat source to a distant object.
One method used to protect against the transfer of heat is to place a barrier, such as a sheet of metal, which is generally thermally conductive material, between the heat source and the protected object or gaseous area. A surface of the barrier exposed to the heat source may reflect some indirect heat, but it also absorbs some of the heat. As some of the heat is absorbed, the exposed surface becomes heated. One disadvantage of this prior art is that the conductive properties of the barrier cause the surface heat to flow through the barrier by way of conduction, ultimately heating the opposing or protected shield surface. The elevated temperature of the protected surface then increases heat transfer from the protected surface of the barrier to the object or area that the barrier is trying to protect.
Efforts to reduce the effects of radiant heat include constructing barriers from thicker, reflective, or low thermal conductivity materials. Also, numerous shields of complex design have been employed. While the trend has been to develop new materials and more complex designs, the industry has lost sight of providing an improved heat shield at a reasonable cost.
The foregoing illustrates limitations known to exist in heat shields. Thus, it is apparent that it would be advantageous to provide an alternative directed to overcoming one or more of the limitations set forth above.
In first embodiment, the invention comprises a heat shield having: a heat reflective sheet having a thickness bounded by a first sheet surface and a second sheet surface; and means for providing improved convective heat transfer from the sheet while substantially limiting the passage of radiant heat through the sheet, the means comprising: a plurality of convection improving protrusions having a free edge and extending from the first sheet surface; and a plurality of sheet apertures substantially adjacent to at least a portion of the plurality of protrusions, wherein each aperture is bounded by a first edge and a second edge.
In a second embodiment, the invention comprises a heat shield having a heat reflecting sheet, which has a thickness bounded by a first sheet surface and a second sheet surface, the improvement comprising: a plurality of convection improving protrusions having a free edge and extending from the first sheet surface; and a plurality of sheet apertures substantially adjacent to at least a portion of the plurality of protrusions, wherein each aperture is bounded by a first edge and a second edge.
In a third embodiment, the invention comprises a method of limiting the transfer of heat from a heat source to a shielded object, the method comprising the steps of: placing a heat shield of claim 1 between a heat source and a shielded object; wherein the first surface is exposed to an air flow.
The advantages of the improved heat shield will be apparent upon review of the detailed description of the present invention and associated drawings below.
Referring to
In the material of
Radiant heat shields attempt to reflect a portion of the radiant heat away from a protected object or area. However, a portion of the heat is inherently absorbed by the shield. In an effort to prevent the shield from arriving at the temperature of the heat source, the shield must be cooled. A primary means of cooling the shield is by way of convection with a surrounding fluid or medium, such as air. The protrusions 28 increase convective heat transfers rates by increasing the surface area and by generating turbulent flow when the surrounding fluid is moving there over. This increased rate allows more heat to be transferred away from the shield and into the fluid flow. Even though the fluid becomes more heated, the protected object is better protected since the fluid directs the additional heat downstream and, because the shield is cooler, the amount of heat radiating and convecting from the shield is reduced. The apertures 26 also provide cooling benefits by injecting cooler air to (or removing heated air from) the exposed side of shield 20. However, the apertures 26 provide the possibility of allowing radiant heat to transmit there through. Therefore, the apertures 26 may be sufficiently small to prevent any significant radiant heat transmission. Further, the protrusions 28 may also assist in preventing any significant radiant heat transmission through complementary apertures 26 by being angled toward the heat source so to be placed substantially between the heat source and the aperture 26. Further, protrusions 28 may fail to fully extend beyond the thickness of the sheet 20, thereby minimizing the size of any aperture 26. Consequently, radiant protection is substantially maintained, as the apertures 26 may be relatively very small and/or not directly exposed to a radiant heat source 8, as illustrated in
In one embodiment, sheet 20 is oriented to direct fluid flow over protrusions 28, such that the edge 32 of a protrusion 28 is on the upstream portion of the protrusion 28. To the contrary, it is contemplated that fluid flow may also be directed such that edge 32 of a protrusion 28 is on the downstream portion of the protrusion 28, as this may better exhume air from the opposing side by reducing the local fluid pressure (causing air to flow or be sucked from the opposing side to the air stream side). It is also contemplated that the fluid flow may be directed along the shielded or interior side, or the side opposite the side from which the protrusions 28 extend, as similar benefits may be realized. Further, it is contemplated that the protruding perforations 22 may be oriented such that free edge 32 is not the first portion of the perforation 22 contacted by any air flow (or the free edge 32 is on a downstream portion of perforation 22).
A metal stamping process may form the apertures 26 and adjacent protrusions 28 of the protruding perforations 22. The metal stamping process uses a shaped stamping die to sequentially manipulate a sheet of material into the heat reflective sheet of the present invention. Referring to
The die shape and displacement causes the material 24 to deform adjacent to the separation or perforation, displacing the second edge 32 and creating the protrusion 28. The die shape may be tapered, creating a continuous, tapered protrusion 28 as illustrated in
The size and shape of aperture 26 may vary depending on the application. In the embodiment of
It is contemplated that the amount of deformation of material 24 may vary with the requirements of the specific application. More deformation, and consequently larger apertures 26, may be needed when more pass-through air flow is required, for example, or if the application requires more internal heat release. In the embodiment of
The number of protruding perforations 22 may vary with the size of the protruding perforations 22, the size of the apertures 26, and the heat transfer requirements of the specific application. In the embodiment of
In an alternate embodiment, the amount of deformation or the direction of deformation varies in a uniform or non-uniform pattern across the heat reflective sheet 20. In one embodiment, a portion of the protruding perforations 22 are deformed to extend beyond the exterior surface (or the air flow exposed surface) of the sheet, and a second portion of protruding perforations 22 are deformed to extend in the opposite direction, or beyond the interior surface of the sheet. In one embodiment the amount of deformation of material 24 (or the extension of protrusion 28, or the size of the aperture 26) varies in a uniform or non-uniform pattern across the heat reflective sheet. In yet another embodiment, perforations 22 may be oriented in varied directions in relation to sheet 20, such that certain edges 32 of certain perforations 22 may be oriented different that other edges 32 on other perforations 22.
The sheet material thickness typically ranges between 0.25 to 1.0 millimeters before forming protruding perforations 22, and may comprise carbon steel, stainless steel, copper, aluminum, or other alloys. It is contemplated that thicker or thinner sheets may be required in other applications.
Referring to
The heat shield material of
Depending on the application, the apertures 26, 126 may allow internal heat to escape, or may provide openings for interjecting an internal airflow. In one embodiment, the external airflow is directed to allow a portion to flow onto a face of the protruding perforations 22, 122, through the apertures 26, 126 to the interior 2, and across the interior surface. It is contemplated that the flow may change when disrupted by other turbulence-generating features in alternative perforation 22, 122 geometries.
The protruding perforations 22, 122 also provide improved convection cooling of the shield 10. Improved convection from the shield's 10 external surface results from increased external surface area and the creation of turbulent flow by the surface irregularities. It is commonly known that increasing surface area alone increases the amount of energy transferred. It is also commonly known that turbulent flow increases convection rates. Thus, the protruding perforations 22 allow for more heat to dissipate externally from the heat shield by both increased surface area and turbulent flow, thereby maintaining the exterior surface of the shield 10 at a lower relative temperature. Ultimately, less heat is available to transfer to the object or area being protected.
In an automotive application such as an exhaust pipe heat shield, the movement of the automobile generates airflow over the heat shield. The protruding perforations 22, 122 take advantage of the airflow by causing the flow over the shield 10 to be turbulent. Further, the flow of air passes through the apertures 26, 126 providing enhanced cooling of the interior and exterior surfaces of the shield 10. Experiments show that the apertures 26, 126 can be effectively oriented toward or away from the direction of the airflow. When the apertures 26, 126 are directed into the airflow, the air is forced into the openings. When the apertures 26, 126 are positioned facing away from the airflow, air is drawn through the openings by a venturi effect.
In the application of
In another application, the shield 10 of
While this invention has been described with reference to preferred embodiments thereof, it shall be understood that such description is by way of illustration and not by way of limitation. Accordingly, the scope and content of the present invention are to be defined only by the terms of the appended claims.
This application is a divisional application of U.S. patent application Ser. No. 11/263,309, filed Oct. 31, 2005 which is currently pending and claims priority to, and the benefit of, U.S. provisional application Ser. No. 60/623,496, each of which are hereby incorporated by reference.
Number | Date | Country | |
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60623496 | Oct 2004 | US |
Number | Date | Country | |
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Parent | 11263309 | Oct 2005 | US |
Child | 12785094 | US |