The present disclosure relates to a heat exchanger and more specifically to a heat exchanger configured to perform heat exchange by flowing a fluid on the surface of a heat transfer member.
In a proposed configuration of a heat exchanger, wave-like concaves/convexes are provided on a flat surface of a flat tubular heat exchange tube, such that the wave-like concaves/convexes have a predetermined angle in a range of 10 degrees to 60 degrees to the main flow of the air and that the wave-like concaves/convexes have crests and troughs to be symmetrically folded back on folding lines at predetermined intervals along the main flow of the air (as described in, for example, Patent Literature 1). The wave-like concaves/convexes of this heat exchanger include crests (convexes) of continuing V shapes (or W shapes) and troughs (concaves) of continuing V shapes (or W shapes). Forming such wave-like concaves/convexes causes a secondary flow along the surfaces of the wave-like concaves/convexes to be generated, in addition to the main flow of the air and improves the heat exchange efficiency of the heat exchanger.
PTL 1: JP 2008-232592A
In the heat exchanger described above, it is desired to increase the amplitude (height difference between the crest and the trough) of the wave-like concaves/convexes, with a view to improving the heat exchange efficiency. Increasing the amplitude of the wave-like concaves/convexes, however, causes damages due to stress concentration at bends of the continuing shapes (or W shapes) of the crests (convexes) and the troughs (concaves) of the wave-like concaves/convexes in the process of press-forming the heat exchange tube. This reduces the yield of the heat exchange tube.
A heat exchanger of the present disclosure mainly aims to increase the yield of a heat transfer member at a fixed amplitude of wave-like concaves/convexes formed on the heat transfer member and to increase the amplitude of the wave-like concaves/convexes of the heat transfer member at a fixed yield of the heat transfer member.
In order to achieve the above primary object, the heat exchanger of the present disclosure employs the following configuration.
The present disclosure is directed to a heat exchanger configured to perform heat exchange by flowing a fluid on a surface of a heat transfer member. The heat transfer member includes wave-like concaves/convexes of smooth curve lines provided on the surface exposed to the fluid. The wave-like concaves/convexes are formed such that crest lines of continuing crests of wave and trough lines of continuing troughs wave are formed in a shape of continuing shapes in a horizontal direction, that bends of the V shapes form curve lines, and that a main flow of the fluid flows in a direction perpendicular to the V shapes.
In the heat exchanger of this aspect, the wave-like concaves/convexes of smooth curve lines are formed on the surface of the heat transfer member exposed to the fluid, such that the crest lines of continuing the crests of wave and the trough lines of continuing the troughs of wave are formed in the shape of continuing the V shapes in the horizontal direction and that the bends of the V shapes form curve lines, i.e., in a shape of continuing two V shapes in the horizontal direction to form a W shape and further continuing the W shapes. The wave-like concaves/convexes are also formed such that the main flow of the fluid flows in the direction perpendicular to the V shapes (i.e., in the vertical direction). Forming the crest lines and the trough lines to have curved V-shaped bends (i.e., curved W-shaped bends) reduces the stress concentration at the bends. As a result, this configuration increases the yield of the heat transfer member at a fixed amplitude of the wave-like concaves/convexes of the heat transfer member and increases the amplitude of the wave-like concaves/convexes of the heat transfer member at a fixed yield of the heat transfer member. In the heat exchanger of this aspect, the wave-like concaves/convexes of smooth curve lines are formed in the shape of continuing V shapes on the surface of the heat transfer member exposed to the fluid. This configuration enables a secondary flow along the surfaces of the wave-like concaves/convexes of the heat transfer member to be generated, in addition to the main flow of the fluid and thereby improves the heat transfer efficiency of the heat exchanger.
In the heat exchanger of this aspect, the crest line and the trough line may be formed by alternately arranging linear portions and arc portions in a continuous manner. This configuration increases the minimum radius of the bends, compared with a configuration that crest lines and trough lines are formed by sinusoidal curves. As a result, this configuration increases the yield of the heat transfer member at a fixed amplitude of the wave-like concaves/convexes of the heat transfer member and increases the amplitude of the wave-like concaves/convexes of the heat transfer member at a fixed yield of the heat transfer member, compared with the configuration that the crest lines and the trough lines are formed by sinusoidal curves. In this case, the arc portion may have a radius that is equal to or larger than one fifth a length of the linear portion.
In the heat exchanger of another aspect, the wave-like concaves/convexes may be formed by alternately arranging straight lines and arcs in a continuous manner in cross section. This configuration increases the amplitude of the wave-like concaves/convexes, compared with a configuration that the wave-like concaves/convexes are formed by sinusoidal curves in cross section, and thereby further improves the heat transfer efficiency of the heat exchanger.
In the heat exchanger of another aspect, the heat transfer member may be a heat exchange tube formed as a flat hollow pipe, and the wave-like concaves/convexes may be formed on a flat surface of the heat exchange tube. Accordingly, the present disclosure may be applied to a fin-less heat exchanger. In the heat exchanger of still another aspect, the heat transfer member may be a fin coupled with a heat exchange tube. Accordingly, the present disclosure may be applied to a corrugated fin heat exchanger or the like.
The following describes some aspects of the disclosure with reference to embodiments.
Each of the heat exchange tubes 30 is formed by press-forming a plate member made of a metal material (for example, stainless steel or aluminum) to be a flat hollow pipe in an approximately rectangular shape as a whole. The respective heat exchange tubes 30 are stacked such that their longitudinal directions correspond to the vertical direction and are joined with one another at respective contact points by brazing. An inflow port 31 formed at a vertically lower position near to a lower end of each heat exchange tube 30 is joined with an inflow port 31 of another heat exchange tube 30 adjacent thereto in the stack of the respective heat exchange tubes 30. This forms a connecting pipe 31a to make the respective inflow ports 31 communicate with one another. Like the inflow ports 31, an outflow port 32 formed at a vertically upper position near to an upper end of each heat exchange tube 30 is joined with an outflow port 32 of another heat exchange tube 30 adjacent thereto in the stack of the respective heat exchange tubes 30. This forms a connecting pipe 32a to make the respective outflow ports 32 communicate with one another. This configuration enables a first heat exchange medium such as water or oil to flow in from the inflow ports 31 of the respective heat exchange tubes 31, to flow vertically upward, and to flow out from the outflow ports 32 of the respective heat exchange tubes 30.
The shell 50 is formed from a plate member made of a metal material (for example, stainless steel or aluminum) like the respective heat exchange tubes 30 and is configured as a case in an approximately rectangular parallelepiped shape to place therein the plurality of heat exchange tubes 30 that are coupled with one another by means of the connecting pipes 31a and 32a. A flow inlet 51 is formed in an upper portion of the shell 50, and a flow outlet 52 is formed in a lower portion of the shell 50. This configuration enables a second heat exchange medium such as the air or exhaust gas to flow in from the flow inlet 51 formed in the upper portion of the shell 50, to pass through between the plurality of heat exchange tubes 30 and to flow out from the flow outlet 52 formed in the lower portion of the shell 50.
A plurality of wave-like concaves/convexes 34 and 36 are formed by smooth curved surfaces on respective flat surfaces 33 and 35 of each of the heat exchange tubes 30.
According to the embodiment, the crest lines 34a and 36a and the trough lines 34b and 36b are formed such that linear portions 34c and 36c formed by straight lines and arc portions 34d and 36d formed by arcs are arranged alternately in a continuous manner. According to the embodiment, the radius of the arc portions 34d and 36d is equal to or larger than one fifth the length of the linear portions 34c and 36c. Such configuration of forming the bends of the V shapes (or the W shapes) by arcs (curve lines) reduces the stress concentration at the bends in the press-forming process, compared with the heat exchanger 920 of the comparative example of
The wave-like concaves/convexes 34 and 36 of the embodiment are formed such that straight lines and arcs are alternately arranged in a continuous manner in cross section as shown in
In the heat exchange tube 30 of the embodiment, the wave-like concaves/convexes 34 provided on one flat surface 33 and the wave-like concaves/convexes 36 provided on the other flat surface 35 are arranged parallel to each other, such that the crest lines 34a of the wave-like concaves/convexes 34 on one flat surface 33 are aligned with the trough lines 36b of the wave-like concaves/convexes 36 on the other flat surface 35 and that the trough lines 34b of the wave-like concaves/convexes 34 on one flat surface 33 are aligned with the crest lines 36a of the wave-like concaves/convexes 36 on the other flat surface 35.
In the heat exchanger 20 of the embodiment described above, the wave-like concaves/convexes 34 and 36 provided on the respective flat surfaces 33 and 35 of each of the heat exchange tubes 30 are formed such that the crest lines and 36a and the trough lines 34b and 36b are arranged alternately in the shape of continuing V shapes (or W shapes) in the horizontal direction and that the respective bends of the V shapes (or the W shapes) form the curved lines. This configuration increases the yield in the press-forming process at the fixed amplitude of the wave-like concaves/convexes 34 and 36 and increases the amplitude of the wave-like concaves/convexes 34 and 36 at the fixed yield in the press-forming process, compared with the heat exchange tubes 930 of the heat exchanger 920 of the comparative example configured such that the crest lines 934a and 936a and the trough lines 934b and 936b have the bends formed in the shape of continuing sharply-angled V shapes (or W shapes) in the horizontal direction. Additionally, the crest lines 34a and 36a and the trough lines 34b and 36b are formed by alternately arranging the linear portions 34c and 36c and arc portions 34d and 36d in a continuous manner. This configuration increases the minimum radius of the bends and reduces the stress concentration at the bends in the press-forming process compared with the configuration that the crest lines and the trough lines are formed by sinusoidal curves. Accordingly, this configuration further increases the yield in the press-forming process at the fixed amplitude of the wave-like concaves/convexes 34 and 36 and further increases the amplitude of the wave-like concaves/convexes 34 and 36 at the fixed yield in the press-forming process.
The configuration that the crest lines 34a and 36a and the trough lines 34b and 36b are formed in the shape of continuing V shapes (or W shapes) in the horizontal direction on the respective flat surfaces 33 and 35 of the heat exchange tube 30. This configuration enables the secondary flow effective for heat exchange to be generated, in addition to the main flow of the second heat exchange medium, on the surfaces of the wave-like concaves/convexes 34 and 36 and provides the heat exchange having a high heat exchange efficiency. Furthermore, the configuration of the wave-like concaves/convexes 34 and 36 by alternately arranging the straight lines and the arcs in a continuous manner in cross section increases the minimum radius of the crest and the trough of wave and accordingly increases the amplitude, compared with the configuration of sinusoidal curves in cross section. This configuration provides the heat exchanger having the higher heat exchange efficiency.
In the heat exchanger 20 of the embodiment, the wave-like concaves/convexes 34 and 36 have the crest lines 34a and 36a and the trough lines 34b and 36b formed by alternately arranging the linear portions 34c and 36c and the arc portions 34d and 36d in a continuous manner. The requirement is that the crest lines and the trough lines have curved V-shaped (or W-shaped) bends. According to a modification, the crest lines and the trough lines may be formed by alternately arranging S-shaped curves and arcs in a continuous manner, or the crest lines and the trough lines may be formed by continuing sinusoidal curves.
In the heat exchanger 20 of the embodiment, the wave-like concaves/convexes 34 and 36 are formed by alternately arranging the straight lines and the arcs in a continuous manner in cross section. According to a modification, the wave-like concaves/convexes 34 and 36 may be formed by alternately arranging S-shaped curves and arcs in a continuous manner in cross section or may be formed by continuing sinusoidal curves in cross section.
In the heat exchanger 20 of the embodiment, the first heat exchange medium and the second heat exchange medium form opposed flows. According to a modification, the first heat exchange medium and the second heat exchange medium may form cross flows, or one or both of the first heat exchange medium and the second heat exchange medium may form a bypass flow.
The embodiment describes the application of the present disclosure to the heat exchange tubes in the fin-less heat exchanger 20. The present disclosure may, however, be applied to a fin in a corrugated fin heat exchanger. In this modification, the fin may be configured such that wave-like concaves/convexes of smooth curve lines are formed by alternately arranging crest lines of continuing V shapes (or W shapes) in the horizontal direction and trough lines of continuing V shapes (or W shapes) in the horizontal direction, that bends of the V shapes (or W shapes) form curved lines, and that the main flow of a fluid flows in the fin in an perpendicular direction of the V shapes.
The aspect of the disclosure is described above with reference to the embodiment. The disclosure is, however, not limited to the above embodiment but various modifications and variations may be made to the embodiment without departing from the scope of the disclosure.
The technique of the disclosure is preferably applicable to the manufacturing industries of the heat exchanger and so on.
This is a national phase application of PCT/JP2015/086562 filed Dec. 28, 2015, the contents of which are incorporated herein by reference.
Filing Document | Filing Date | Country | Kind |
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PCT/JP2015/086562 | 12/28/2015 | WO | 00 |