This invention relates to heat exchangers, and in particular to heat exchangers formed of a plurality of stacked or nested dish-type plates with overlapping peripheral walls.
Nested dish plate heat exchangers have been made in the past where a plurality of stacked plates having overlapping peripheral side walls are put together to define hollow fluid passages between the plates, usually with different fluids in heat exchange relationship in alternating spaces between the plates. Usually, a base plate or mounting plate is attached to an uppermost or a lowermost one of the stacked plates, and the mounting plate has holes or fasteners to attach the heat exchanger to a piece of equipment, such as an automobile engine. Oil from the engine passes through openings in the mounting plate and engine coolant passes through other inlet and outlet holes in the mounting plate, or fittings attached to the heat exchanger in order to cool the engine oil in use.
In the nested dish plate heat exchangers made in the past, the plates are usually made of thin material. Also, the plates are often made of aluminum which has inherently lower mechanical strength relative to ferrous alloys, particularly after brazing. A difficulty with this is that some of the dish plates, usually the ones attached to the mounting plate, are prone to fatigue fracture due to vibration, mounting plate deformation, thermal stresses and internal pressure stresses transmitted from the engine to the nested dish plates through the mounting plate, and also from the coolant hoses attached to the heat exchanger. Base plate or mounting plate deformation, in particular, presents a significant problem since mounting plates may tend to form poor braze joints with the lowermost plate in the stack of nested dish plates and are, therefore, prone to failure.
In U.S. Pat. No. 5,927,394 issued to Robert Mendler, et al., an attempt is made to ameliorate the difficulties mentioned above by adding an extra thick reinforcing dish plate below the lowermost regular dish plate. The reinforcing dish plate is formed with a generally flat base portion and has upright tabs formed on its longitudinal and transverse sides which are bent upwards at an angle from the plane of the base portion. A difficulty with this is that the extra reinforcing plate adds height and weight to the heat exchanger. The reinforcing plate also requires a unique and costly die, as well as increased care and handling during assembly and thus adds cost to its manufacture.
In the present invention, a reinforcing element surrounds at least a portion of a regular heat exchanger dish plate attached to the mounting plate. The reinforcing element has a base flange attached to the mounting plate, and a peripheral flange in parallel, overlapping contact with the inclined peripheral wall of the regular heat exchanger dish plate.
According to one aspect of the invention, there is provided a reinforcing element for a dish plate heat exchanger having a mounting plate and a plurality of nested dish plates mounted thereon, the dish plates having inclined peripheral, overlapping walls and the mounting plate extending beyond the outer periphery of the walls of the nested dish plates. The reinforcing element comprises a base flange adapted to be attached to the mounting plate extending beyond the outer periphery of the walls of the nested dish plates. Also, a peripheral flange is attached to the base flange. The peripheral flange is adapted to be in parallel, overlapping contact with the inclined peripheral wall of at least one dish plate attached to the mounting plate.
According to another aspect of the invention, there is provided a dish plate heat exchanger comprising a mounting plate and a plurality of nested dish plates mounted on the mounting plate. The dish plates have inclined, peripheral, overlapping walls, the mounting plate extending beyond the outer periphery of the walls of the nested dish plates. A reinforcing element has a base flange attached to the mounting plate extending beyond the outer periphery of the nested dish plates. Also, the reinforcing element has a peripheral flange attached to the base flange. The peripheral flange is attached in parallel, overlapping engagement with the inclined peripheral wall of at least one dish plate attached to the mounting plate.
According to a further aspect of the invention, there is provided a reinforcing element for a dish plate heat exchanger having a mounting plate and a plurality of nested dish plates mounted thereon, the dish plates having inclined, peripheral, overlapping walls, the mounting plate extending beyond the outer periphery of the walls of the nested dish plates. The reinforcing element comprises a base portion adapted to be positioned between the mounting plate and the plurality of nested dish plates. A peripheral flange is attached to the periphery of at least a portion of the base portion, the peripheral flange being adapted to be in parallel, overlapping contact with the inclined peripheral wall of at least one dish plate in the plurality of nested dish plates. The reinforcing element also includes a tongue portion extending outwardly from the base portion, the tongue portion being configured to overlap a high-stress area of the mounting plate extending beyond the outer periphery of the walls of the nested dish plates.
Embodiments of the invention will now be described, by way of example, with reference to the accompanying drawings, in which:
Referring firstly to
The nested dish plates 12 have bottom walls 15 defining inlet and outlet openings 14, 16 for a first heat exchange fluid, such as engine oil, and embossments or bosses 18 defining further inlet and outlet openings 20, 22 for a second heat exchanger fluid, such as engine coolant. Inlet and outlet fittings (not shown) are also provided for the supply and return of engine coolant to inlet and outlet openings 20, 22. However, mounting plate 13 could be provided with inlet and outlet openings (not shown) communicating with dish plate inlet and outlet openings 20, 22, if desired. Alternatively, mounting plate 13 could have one inlet opening communicating with dish plate inlet openings 20, and one outlet fitting (not shown) could be provided in heat exchanger 10 communicating with dish plate outlet openings 22.
The dish plates 12 are stacked with alternating plates turned 180 degrees to one another, so that inlet and outlet openings 14, 16 communicate with spaces or flow passages 24 between every other pair of adjacent plates. Similarly, inlet and outlet openings 20, 22 communicate with spaces or flow passages 26 in between every other alternating pair of adjacent plates. In other words, a first heat exchange fluid, such as engine oil, and a second heat exchange fluid, such as engine coolant, would flow through alternate flow passage 24, 26 in heat exchanger 10.
As seen best in
Referring next, in particular to
Referring next to
Reinforcing element 40 preferably is made by roll forming and is then bent into an annular configuration to surround dish plate 12. Reinforcing element 40 thus would have a small gap 46 (emphasized in
While the reinforcing element shown in
While the present invention has been described with reference to certain preferred embodiments, it will be understood by persons skilled in the art that the invention is not limited to these precise embodiments and that variations or modifications can be made without departing from the scope of the invention as described herein. For example, as described in connection with
This application is a continuation application of U.S. patent application Ser. No. 11/538,919 filed on Oct. 5, 2006, which is currently pending and claims priority to U.S. Patent Application Ser. No. 60/723,755 filed on Oct. 5, 2005. Both applications are incorporated by reference in their entireties herein.
Number | Date | Country | |
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60723755 | Oct 2005 | US |
Number | Date | Country | |
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Parent | 11538919 | Oct 2006 | US |
Child | 13455447 | US |