The present invention relates to corrugated fins for heat exchanger to be interposed between flat tubes or to be installed in the flat tube, ridges and furrows being alternately arranged on a rising wall surface and a falling wall surface thereof.
As the corrugated fins for heat exchanger which make clogging difficult to occur and which can be applied also to a gaseous body which contains many particulate matters such as dust, for example, the fin described in the following Patent Literature 1 is known and is used in a heat changer and an exhaust heat exchanger of construction machinery.
The invention described in Japanese Patent Laid-Open No. 2007-78194 is a rectangular-wave-shaped corrugated fin in which peak parts and valley parts of the wave have run meandering in a longitudinal direction as shown in
Although the conventional type corrugated fin described in Japanese Patent Laid-Open No. 2007-78194 has the effect of suppressing development of the boundary layer, it was not sufficient. In addition, there was a problem in productivity such as a warp in a fin height direction in association with machining of the wave shape.
Therefore, a corrugated fin which is higher in heat transfer performance and is high in productivity has been required.
Accordingly, as a result of various experiments and fluid analyses, the inventors of the present invention have found the specification of the fin which is higher in heat transfer performance and is easier to produce than the corrugated fin of the above-mentioned Japanese Patent Laid-Open No. 2007-78194.
That is, they have developed the corrugated fin which is higher in heat transfer performance and is easier to manufacture than the fin described in the above-mentioned Japanese Patent Laid-Open No. 2007-78194 by specifying a plate thickness thereof, a period of ridges and furrows, a height of the ridges and the furrows and a period of the corrugated fins to fixed ranges, when alternately and repetitively forming the ridges and the furrows on wall surfaces which serve as a rising surface and a falling surface of the corrugated fin.
The present invention according to a first aspect thereof is corrugated fins for heat exchanger to be interposed between flat tubes which are arrayed side by side separately from each other or to be installed in the flat tube, in which
the material of the fin is aluminum or an aluminum alloy,
the fin is 0.06 to 0.16 mm in plate thickness and has respective wall surfaces (3) of a rising part and a falling part between a peak part and a valley part which are bent into a waveform in a longitudinal direction of the fin,
ridges (4) and furrows (5) which are 10 degrees to 60 degrees in angle of inclination relative to a width direction of the fin and are in the same direction are alternately arrayed side by side on the respective wall surfaces (3), and
when a height of the ridges and furrows (an external dimension from the valley of a furrow part to the peak of a ridge part, including a plate thickness) is set to Wh [mm],
a period of the ridges and furrows (a period from a certain ridge to the next ridge) is set to Wp [mm],
a period of the corrugated fins is set to Pf [mm] and
the plate thickness of the fin is set to Tf [mm],
the corrugated fins satisfy the following conditions and a gaseous body flows in the width direction of the fins,
Wh≦0.3674·Wp+1.893·Tf−0.1584 [Formula 1]
0.088<(Wh−Tf)/Pf<0.342 [Formula 2]
a·Wp
2
+b·Wp+c<Wh [Formula 3]
where
a=0.004·Pf2−0.0696·Pf+0.3642
b=−0.0036·Pf2+0.0625·Pf−0.5752, and
c=0.0007·Pf2+0.1041·Pf+0.2333.
The present invention according to a second aspect thereof is the corrugated fins for heat exchanger according to the first aspect, in which
the corrugated fins satisfy the following conditions and a gaseous body flows in the width direction of the fins,
0.100<(Wh−Tf)/Pf<0.320 [Formula 4]
a′Wp
2
+b′·Wp+c′<Wh [Formula 5]
where
a′=0.004·Pf2−0.0694·Pf+0.3635
b′=−0.0035·Pf2+0.0619·Pf−0.5564, and
c′=0.0007·Pf2+0.1114·Pf+0.2304.
The present invention according to a third aspect thereof is the corrugated fins for heat exchanger according to the first aspect, in which
the corrugated fins satisfy the following conditions and a gaseous body flows in the width direction of the fins,
0.118<(Wh−Tf)/Pf<0.290 [Formula 6]
a″·Wp
2
+b″·Wp+c″<Wh [Formula 7]
where
a″=0.0043·Pf2−0.0751·Pf+0.3952
b″=−0.0038·Pf2+0.0613·Pf−0.6019, and
c″=0.0017·Pf2+0.1351·Pf+0.2289.
The corrugated fin of the present invention can be produced by a general purpose manufacturing method for roll machining and so forth and the specification thereof is made to satisfy [Formula 1] to [Formula 3], and thus it is possible to provide the corrugated fin which is improved in heat dissipation and is easy to machine in comparison with the conventional type corrugated fin by forming. In a cell region which is surrounded by flat tubes and a rising wall and a falling wall of the fin as shown in
Next, embodiments of the present invention will be described on the basis of the drawings.
In this heat exchanger, corrugated fins 2 are arranged between many flat tubes 1 which are arrayed side by side and are integrally brazed and fixed together between contact parts thereof to form a core 11. Then, upper and lower both end parts of each flat tube 1 communicate into tanks 12 via header plates 10.
As shown in
Although the wall surfaces 3 having such many ridges 4 and furrows 5, the peak parts 8 and the valley parts 9 are integrally formed, when shown intentionally by a development diagram, it can be expressed as in
That is, in the corrugated fin 2, the peak parts 8 and the valley parts 9 are alternately formed in a longitudinal direction of the fin separately from each other and the wall surface 3 is present between them. The linear ridges 4 and furrows 5 which are symmetrical to the peak part 8 are formed obliquely on the respective wall surfaces 3 facing each other when the fin is formed.
Incidentally, as shown in the same drawing, the ridges 4 and the furrows 5 are not formed on a leading end of the corrugated fin 2 and a flat part 6 is provided thereon.
A feature of the present invention lies in the point that the height Wh of the ridges and furrows, the period Pf of the corrugated fins and the plate thickness Tf of the fin in
Although within a range that the influence of the reduction in flow rate caused by the increase in pressure loss does not become predominant, the larger the height Wh of the ridges and furrows of the fin becomes, the higher the heat transfer performance becomes, the height Wh of the ridges and furrows is limited also by the machining limit of the fin.
Likewise, when Wp is 2.0 mm, 0.7 mm is the upper limit of the height Wh. Further, when Wp is 2.5 mm, about 0.87 mm is the upper limit.
Likewise, the machining limit in the case of the plate thickness 0.1 mm and the machining limit in the case of the plate thickness 0.16 mm are plotted by (▪) and (♦), respectively.
[Formula 1] expresses the machining limit shown in this
Wh≦0.3674·Wp+1.893·Tf−0.1584 [Formula 1]
Next,
The following matters were clarified therefrom.
The fan matching heat radiation amount ratio of the present invention has a maximum value and the value thereof is about 120% relative to that of the conventional type corrugated fin.
Incidentally, the reason why the maximum value is present is that although a heat transfer enhancement effect owing to generation of the swirling flow is increased up to some extent in association with an increase in (Wh−Tf)/Pf, when it is further increased, the influence of the reduction in flow rate caused by the increase in pressure loss becomes predominant and the heat transfer amount is lowered.
[Formula 2] expresses a range of (Wh−Tf)/Pf within which the fan matching heat radiation amount ratio which is shown in this
0.088<(Wh−Tf)/Pf<0.342 [Formula 2]
Next,
In
a·Wp
2
+b·Wp+c<Wh [Formula 3]
where
a=0.004·Pf2−0.0696·Pf+0.3642
b=−0.0036·Pf2+0.0625·Pf−0.5752, and
c=0.0007·Pf2+0.1041·Pf+0.2333.
A straight line B is a machining upper limit (see [Formula 1]) in a case where the plate thickness Tf of the fin is 0.06 mm, and a straight line C is the machining upper limit (see [Formula 1]) in a case where the plate thickness Tf of the fin is 0.16 mm.
A straight line D indicates a lower limit of (Wh−Tf)/Pf at which the fan matching heat radiation amount ratio becomes larger than 100% in consideration of the machining upper limit and is obtained by simultaneously setting up the upper limit of Wh (Wh=0.3674·Wp+1.893·Tf−0.1584) in [Formula 1] and the lower limit (0.088=(Wh·Tf)/Pf) of (Wh−Tf)/Pf in [Formula 2] and by deleting Tf.
Likewise, a straight line E indicates an upper limit of (Wh−Tf)/Pf at which the fan matching heat radiation amount ratio becomes larger than 100% in consideration of the machining upper limit and is obtained by simultaneously setting up the upper limit of Wh in [Formula 1] and the upper limit of (0.342=(Wh−Tf)/Pf) of (Wh−Tf)/Pf in [Formula 2] and by deleting Tf.
That is, in the case where the plate thickness Tf of the fin is 0.06 mm, machining of the fin is possible and the fan matching heat radiation amount ratio thereof becomes larger than 100% in comparison with the conventional type corrugated fin within a range surrounded by the curved line A and the straight line B.
In addition, in the case where the plate thickness Tf of the fin is 0.16 mm, machining of the fin is possible and the fan matching heat radiation amount ratio thereof becomes larger than 100% in comparison with the conventional type corrugated fin within a range surrounded by the curved line A, the straight line C, the straight line D and the straight line E.
Next,
In addition, [Formula 4] expresses a range of (Wh−Tf)/Pf within which the fan matching heat radiation amount ratio becomes larger than 105% by a numerical formula, and [Formula 5] expresses the lower limit of the height Wh of the ridges and furrows in that case.
0.100<(Wh−Tf)/Pf<0.320 [Formula 4]
a′·Wp
2
+b′·Wp+c′<Wh [Formula 5]
a′·Wp
2
+b′·Wp+c′<Wh [Formula 5]
where
a′=0.004·Pf2−0.0694·Pf+0.3635
b′=−0.0035·Pf2+0.0619·Pf−0.5564, and
c′=0.0007·Pf2+0.1114·Pf+0.2304.
Further, [Formula 6] expresses a range of (Wh−Tf)/Pf within which the fan matching heat radiation amount ratio becomes larger than 110% by a numerical formula, and [Formula 7] expresses the lower limit of the height Wh of the ridges and furrows in that case.
0.118<(Wh−Tf)/Pf<0.290 [Formula 6]
a″·Wp
2
+b″·Wp+c″<Wh [Formula 7]
where
a″=0.0043·Pf2−0.0751·Pf+0.3952
b″=−0.0038·Pf2+0.0613·Pf−0.6019, and
c″=0.0017·Pf2+0.1351·Pf+0.2289.
Next,
In this example, the ridges and the furrows of the fin move from the center rightward in the drawing to h1, h2 and h3 as they go toward the downstream side. In association therewith, the fluid between the ridge and the furrow is guided rightward in the drawing, is deflected toward the facing fin by a right-side tube surface, flows leftward together with the flow from the facing fin, and is deflected toward the original fin by a left-side tube surface.
The swirling flow is generated in this way and also the fluid at a part remote from the fin sequentially comes close to the fin and transfers heat thereto, and thereby the heat transfer performance is improved relative to the conventional type corrugated fin.
Incidentally, also in the corrugated fin of the present invention which is exemplified in
On the other hand, although
This corrugated fin can be applied to various heat exchangers such as a radiator, a capacitor, and an EGR cooler and can be also applied to a case of heating or cooling the gaseous body which flows into that corrugated fin. In addition, the entire shape of the corrugated waveform of the corrugated fin may be any of a rectangular wave-shape, a sinusoidal wave-shape, and a trapezoidal wave-shape. In addition, the ridges and the furrows which are formed on the wall surface of the fin other than the peak part and the valley part of the corrugated fin may be any of a sinusoidal wave, a triangular wave, a trapezoidal wave, a curved shape, a combination thereof in cross sections thereof.
Number | Date | Country | Kind |
---|---|---|---|
2014-191512 | Sep 2014 | JP | national |
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/JP2015/077002 | 9/15/2015 | WO | 00 |