Riblet structure and object

Abstract

The present invention provides a riblet structure that further reduces drag, which is a sum of turbulent friction drag and pressure drag, and an object including such a riblet structure. An object such as an aircraft, plant, and pipeline includes a wavelike riblet pattern on a surface. The wavelike riblet pattern includes a large number of wavelike riblets. Each of the large number of wave riblets includes a wavelike ridge line, and a height thereof changes cyclically with respect to a fluid flow direction. With such a configuration, drag, which is a sum of turbulent friction drag and pressure drag, can be further reduced.

Claims

1. A riblet structure, comprising a plurality of wavelike riblets, a height of each of the plurality of wavelike riblets being set in a first direction to become smaller as an angle formed between a ridge line and a surface of the riblet structure becomes larger, wherein a fluid flow direction is parallel to the surface of the riblet structure, wherein the first direction is perpendicular to the fluid flow direction, wherein the ridge line of each of the plurality of wavelike riblets has a sinusoidal shape of a first wavelength, and the height of each of the plurality of wavelike riblets increases/decreases in a sinusoidal shape of a second wavelength as a half wavelength of the first wavelength in the fluid flow direction.

2. The riblet structure according to claim 1, wherein when a reference height of the wavelike riblets is represented by h, an amplitude a of the second wavelength satisfies
0<a0.2 h.

3. The riblet structure according to claim 1, wherein the plurality of wavelike riblets are arranged at constant intervals.

4. An object, comprising a wavelike riblet pattern including wavelike ridge lines, a height of the wavelike riblet pattern in a first direction changing cyclically with respect to a surface of the object, wherein a fluid flow direction is parallel to the surface of the object, wherein the first direction is perpendicular to the fluid flow direction, wherein the wavelike ridge lines have a sinusoidal shape of a first wavelength, and the height of the wavelike riblet pattern increases/decreases in a sinusoidal shape of a second wavelength as a half wavelength of the first wavelength in the fluid flow direction.

Description

BRIEF DESCRIPTION OF DRAWINGS

(1) FIG. 1 is a perspective view of an object according to an embodiment of the present invention.

(2) FIGS. 2(a) and 2(b) are diagrams for explaining a change of a height of wavelike riblets shown in FIG. 1 in a fluid flow direction (x direction).

(3) FIG. 3 is a cross-sectional diagram of the wavelike riblets having a reference height, the diagram being perpendicular to the flow direction (x direction).

(4) FIG. 4 is a graph showing curves of drag increase rates of various riblets obtained by a wind tunnel test.

MODES FOR CARRYING OUT THE INVENTION

(5) Hereinafter, an embodiment of the present invention will be described with reference to the drawings.

(6) FIG. 1 is a perspective view of an object according to an embodiment of the present invention.

(7) As shown in FIG. 1, an object 1 includes a wavelike riblet pattern 3 on a surface 2 thereof.

(8) The object 1 is an object that includes a surface on which fluid flows, such as an aircraft, a plant, and a pipeline, for example.

(9) The surface 2 is an outer surface in terms of an aircraft. Alternatively, the object 1 may take a form of a sheet and may be attached to a desired position of the aircraft. Regarding the pipeline, the surface 2 refers to an inner wall portion through which liquid flows.

(10) The wavelike riblet pattern 3 is constituted of a large number of wavelike riblets 30 that have wavelike ridge lines 31 and whose height h changes cyclically with respect to a fluid flow direction D.

(11) Here, the ridge lines 31 are typically lines formed by apexes of triangular cross sections that each have an apex angle of about 30, but even if the apexes are not constituted of corners and the apexes are, for example, a plane or a curved surface, these cases are also included, and a long surface formed by these surfaces is regarded substantially as the ridge line, for example. Of course, the cross-sectional shape may be other than a triangular shape, such as a square shape, for example. Further, although the wavelike shape is typically a sinusoidal shape, it is meant to include any curved surface excluding the sinusoidal shape as long as it is formed continuously to some extent. In the present invention, the entire riblet pattern of the surface 2 may be the wavelike riblet pattern 3, or a part of the riblet pattern of the surface 2 may be the wavelike riblet pattern 3.

(12) FIGS. 2(a) and 2(b) are diagrams for explaining a change of a height of the wavelike riblets 30 shown in FIG. 1 in the fluid flow direction (x direction). FIG. 2(a) is a diagram showing the surface 2 of the object 1 from an upper surface (y direction), and FIG. 2(b) is a diagram showing the surface 2 of the object 1 from a lateral direction (z direction). In FIG. 2(a) and FIG. 2(b), phases in the x direction are made to coincide. FIG. 3 is a cross-sectional diagram of the wavelike riblets 30 having a reference height, the diagram being perpendicular to the flow direction (x direction).

(13) As shown in FIGS. 2(a), 2(b), and 3, a height h.sub.x of the wavelike riblets 30 becomes smaller as an angle formed by the ridge line 31 and the fluid flow direction D becomes larger.

(14) As shown in FIGS. 2 and 3, a height h.sub.x of the wavelike riblets 30 becomes smaller as an angle formed by the ridge line 31 and the fluid flow direction D becomes larger.

(15) The ridge line 31 of the wavelike riblet 30 according to this embodiment has a sinusoidal shape of a wavelength (see FIG. 2(a)). Therefore, the height h.sub.x of the wavelike riblets 30 increases/decreases (changes) in a sinusoidal shape of a wavelength /2 as a half wavelength of the sinusoidal wave in the fluid flow direction D (see FIG. 2(b)). For example, since the angle formed between the ridge line 31 and the fluid flow direction D is 0 at a point x.sub.1 of the ridge line 31 in FIG. 2(a), a height h.sub.x1 of the wavelike riblet 30 corresponding to this position becomes maximum (see point x.sub.1 in FIG. 2(b)). On the other hand, since the angle formed between the ridge line 31 and the fluid flow direction D is maximum at a point x.sub.2 of the ridge line 31 in FIG. 2(a), the height h.sub.x2 of the wavelike riblet 30 corresponding to this position becomes minimum (see point x.sub.2 in FIG. 2(b)).

(16) Here, typically, it is favorable for an amplitude A of the ridge line 31 of the wavelike riblet 30 to satisfy
tan.sup.1(2n*/A)=10.

(17) Further, as shown in FIG. 3, when an interval between the wavelike riblets 30, which is a pitch of the wavelike riblets 30 in the wavelike riblet pattern 3, is represented by s, it is favorable for a reference height h of the wavelike riblets 30 to satisfy
h=s/2.

(18) It is favorable for an amplitude a of a wavelength corresponding to a change in the height of the wavelike riblets 30 to take a value that satisfies
0<a0.2 h
with respect to the reference height h.

(19) As a result of a study while fixing at s+=20, it was confirmed that, when the amplitude a is 0.2 h or less, pressure drag decreases, and also friction drag decreases.

(20) Next, a result of a test conducted to confirm the effects of the present invention will be described.

(21) FIG. 4 shows curves of drag increase rates of various riblets obtained by a wind tunnel test.

(22) Here, the drag increase rate is a value with respect to a wall index s+ of an interval of apexes of the riblets (corresponding to interval s described above).

(23) In FIG. 4, the reference numeral 401 indicates a drag increase rate of a linear riblet, the reference numeral 402 indicates a drag increase rate of a wavelike riblet of the past (wavelike riblet having constant height), and the reference numeral 403 indicates a drag increase rate of a wavelike riblet according to the present invention.

(24) Here, a parameter of the linear riblet is height h=s/2 (variable value). Parameters of the wavelike riblet of the past are ridge line wavelength +=1131 (fixed value) of the ridge line, amplitude A=0.03 (fixed value), and height h=s/2 (variable value). Parameters of the wavelike riblet according to the present invention are ridge line wavelength =1131 (fixed value), amplitude A=0.03 (fixed value), reference height h=s/2 (variable value), and amplitude a=0.1 h (variable value). , A, and h described above are considered to be a combination of a wavelength and amplitude of a ridge line having the highest drag reduction effect in the wavelike riblet of the past.

(25) The definition of the drag increase rate (y axis in FIG. 4) is
drag increase rate={(total drag on riblet surface)(total drag on smooth surface)}/(total drag on smooth surface).

(26) The smooth surface is a surface without a riblet.

(27) It can be seen that in s+ of the measured range (x axis in FIG. 4), the drag reduction effect is higher in the wavelike riblet of the past and the wavelike riblet according to the present invention than in the linear riblets. The drag increase rate becomes the smallest at s+=17 to 18, and it is usually the case that a real scale of the riblet apex interval is determined while setting a vicinity of this range as a design point. It can be seen from FIG. 4 that in the vicinity of the design point s+=17 to 18, there is hardly any difference between the wavelike riblet of the past and the wavelike riblet according to the present invention. However, it can be seen that, as s+ becomes larger than the design point, the drag reduction effect of the wavelike riblet according to the present invention is improved as compared to the wavelike riblet of the past.

(28) For example, when mounting the riblets on an aircraft, it is not always possible to fly in the vicinity of the design point, so robustness with respect to the value of s+ other than the design point is important. In other words, according to the present invention, it can be said that the robustness of the drag reduction effect is improved as compared to the wavelike riblet of the past.

(29) As described above, it has been confirmed by the wind tunnel test that the robustness of the drag reduction effect is improved by the present invention.

(30) For example, in an aircraft, improvement of a drag reduction rate by about 1% corresponds to about 3% a fuel consumption reduction amount. Converting to CO.sub.2 emission, 700 tons/year can be reduced per one Airbus A320 (150 to 180 seats), which greatly contributes to global warming countermeasures.

(31) The present invention can be applied to various technical fields.

(32) For example, by applying the present invention to plants and pipelines, it is possible to improve fluid transport efficiency and the like.

(33) Further, by applying the present invention to a field of fluid machinery, friction drag can be reduced.

REFERENCE SIGNS LIST

(34) 1 object 2 surface 3 wavelike riblet pattern 30 wavelike riblet 31 ridge line D fluid flow direction h height