阅读说明：本技术 一种采摘无人机的带切割翼型旋翼造型 (Unmanned aerial vehicle's area cutting wing section rotor molding is picked ) 是由 孙中涛 单杭英 王华明 于 2020-07-14 设计创作，主要内容包括：本发明涉及一种采摘无人机的带切割翼型旋翼造型,包括桨叶造型和切割翼型；桨叶造型依次包括切割段、过渡段、主升力段和根部加强段,切割段为桨叶展向的100%-80%,切割段的桨叶扭转角为0°,切割段沿展向的100%-80%方向的桨叶迎风面为渐扩结构,切割段的翼型为切割翼型；过渡段为桨叶展向的80%-70%,过渡段的桨叶扭转角由0°向5°过渡,过渡段的翼型由切割翼型向标准翼型平滑过渡；主升力段为桨叶展向的70%-40%,主升力段的翼型为标准翼型,主升力段的造型为16%标准翼型；根部加强段为4展向的40%-10%,主升力段的造型为16%标准翼型过渡到24%标准翼型,根部加强段沿展向的40%-10%方向的迎风面为渐缩结构；桨叶与桨毂对接区域为展向的10%-0%；切割翼型的翼型前缘设置有切割刃。(The invention relates to a rotor wing model with a cutting wing section for a picking unmanned aerial vehicle, which comprises a blade model and a cutting wing section; the blade modeling sequentially comprises a cutting section, a transition section, a main lifting section and a root reinforcing section, wherein the cutting section is 100% -80% of the spanwise direction of the blade, the blade torsion angle of the cutting section is 0 degree, the windward side of the blade of the cutting section along 100% -80% of the spanwise direction is of a gradually expanding structure, and the airfoil shape of the cutting section is a cutting airfoil shape; the transition section is 80-70% of the span direction of the blade, the blade torsion angle of the transition section is transited from 0 degree to 5 degrees, and the airfoil profile of the transition section is transited smoothly from a cutting airfoil profile to a standard airfoil profile; the main lifting section is 70% -40% of the span direction of the blade, the wing profile of the main lifting section is a standard wing profile, and the shape of the main lifting section is a 16% standard wing profile; the root reinforcing section is 40% -10% of the 4 spanwise direction, the shape of the main lifting section is that 16% of standard airfoil profile is transited to 24% of standard airfoil profile, and the windward side of the root reinforcing section along the 40% -10% of the spanwise direction is of a reducing structure; the butt joint area of the blades and the propeller hub is 10% -0% of the span direction; the airfoil leading edge of the cutting airfoil is provided with a cutting edge.)

1. The utility model provides a pick unmanned aerial vehicle's area cutting wing section rotor molding, characterized by: the method comprises the steps of blade modeling and airfoil cutting; the blade modeling comprises a cutting section, a transition section, a main lifting section and a root reinforcing section from the blade end part to the blade root part in sequence, wherein the cutting section is 100% -80% of the blade span direction, the blade torsion angle of the cutting section is 0 degree, the windward side of the blade of the cutting section along 100% -80% of the span direction is of a gradually expanding structure, the gradually expanding tail end is as wide as the transition section, and the airfoil shape of the cutting section is a cutting airfoil shape; the transition section is 80-70% of the span direction of the blade, the blade torsion angle of the transition section is transited from 0 degree to 5 degrees, and the airfoil profile of the transition section is transited smoothly from a cutting airfoil profile to a standard airfoil profile; the main lifting section is 70% -40% of the span direction of the blade, the wing profile of the main lifting section is a standard wing profile, and the shape of the main lifting section is a 16% standard wing profile; the root reinforcing section is 40% -10% of the 4 spanwise direction, the shape of the main lifting section is that 16% of standard airfoil profile is transited to 24% of standard airfoil profile, and the windward side of the root reinforcing section along the 40% -10% of the spanwise direction is of a reducing structure; the butt joint area of the blades and the propeller hub is 10% -0% of the span direction; wherein the front edge of the airfoil of the cutting airfoil is provided with a cutting edge with an acute-angle triangular cross section.

2. A rotor form with cutting wing for picking unmanned aerial vehicle as claimed in claim 1, wherein: the cutting airfoil is sequentially divided into three sections from the front edge to the rear edge along a chord line, namely a cutting edge section, a transition section and a standard airfoil section, wherein the cutting edge section comprises a cutting edge formed by an upper surface and a lower surface, the upper surface and the lower surface are both planes, an upper edge and a lower edge are respectively formed between the upper surface and the lower surface and the chord line, the included angle between the upper edge and the chord line is 10-45 degrees, and the included angle between the lower edge and the chord line is 10-15 degrees; with the leading edge to the trailing edge of a chord line as a direction, dividing the upper airfoil into an origin, characteristic points such as S1, S2, S3, S4, S5, S6, S7, S8 and A, and dividing the lower airfoil into an origin, characteristic points such as P1, P2, P3, P4, P5, P6, P7, P8 and A; the chord length of the cutting airfoil section is B;

wherein the origin to S1 is the upper edge, 20 percent of the chord line, and the origin to P1 is the lower edge, 20 percent of the chord line;

the transition section of the upper airfoil comprises S1 and S2, and the transition section of the lower airfoil comprises P1 and P2; wherein S1 to S2 are 10 percent of chord line, S1 to S2 are convex arc surfaces, and the included angle between the tangent line of the arc surface from S1 to S2 and the chord line is X1, wherein X1= tan^-1{ | S2-S1 |/(0.1B) }; P1-P2 are convex cambered surfaces, and the included angle between the tangent of the cambered surface from P1-P2 and the chord line is Y1, wherein Y1= tan^-1{| P2-P1|/（0.1B）}；

The standard airfoil section of the upper airfoil is S2 to A, and the standard airfoil section of the lower airfoil is P2 to A;

s2 to S3 are 10 percent of chord line, S2 to S3 are convex arc surfaces, and the included angle between the tangent line of the arc surface from S2 to S3 and the chord line is X2, wherein X2= tan^-1{ | S3-S2 |/(0.1B) }; P2-P3 are convex cambered surfaces, and the included angle between the tangent of the cambered surface from P2-P3 and the chord line is Y2, wherein Y2= tan^-1{ | P3-P2 |/(0.1B) }; s3 to S4 are 10 percent of chord line, S3 to S4 are convex arc surfaces, and the included angle between the tangent line of the arc surface from S3 to S4 and the chord line is X3, wherein X3= tan^-1{ | S4-S3 |/(0.1B) }; P3-P4 are convex cambered surfaces, and the included angle between the tangent of the cambered surface from P3-P4 and the chord line is Y3, wherein Y3= tan^-1{ | P4-P3 |/(0.1B) }; s4 to S5 are 10 percent of chord line, S4 to S5 are convex arc surfaces, and the included angle between the tangent line of the arc surface from S4 to S5 and the chord line is X4, wherein X4= tan^-1{ | S5-S4 |/(0.1B) }; P4-P5 are convex cambered surfaces, and the included angle between the tangent of the cambered surface from P4-P5 and the chord line is Y4, wherein Y4= tan^-1{ | P5-P4 |/(0.1B) }; s5 to S6 are 10 percent of chord line, S5 to S6 are convex arc surfaces, and the included angle between the tangent line of the arc surface from S5 to S6 and the chord line is X5, wherein X5= tan^-1{ | S6-S5 |/(0.1B) }; P5-P6 are convex cambered surfaces, and the included angle between the tangent of the cambered surface from P5-P6 and the chord line is Y5, wherein Y5= tan^-1{ | P6-P5 |/(0.1B) }; s6 to S7 are 10 percent of chord line, S6 to S7 are convex arc surfaces, and the included angle between the tangent line of the arc surface from S6 to S7 and the chord line is X6, wherein X6= tan^-1{ | S7-S6 |/(0.1B) }; P5-P6 are convex cambered surfaces, and the included angle between the tangent of the cambered surface from P5-P6 and the chord line is Y5, wherein Y5= tan^-1{ | P6-P5|/（0.1B）}；

S7 to S8 are 10 percent of chord line, S7 to S8 are convex arc surfaces, and the included angle between the tangent line of the arc surface from S7 to S8 and the chord line is X7, wherein X7= tan^-1{ | S8-S7 |/(0.1B) }; P7-P8 are convex cambered surfaces, and the included angle between the tangent of the cambered surface from P7-P8 and the chord line is Y7, wherein Y7= tan^-1{ | P8-P7|/（0.1B）}；

S8 to A are 10 percent of chord line, S8 to P are planes, and the included angle between the planes from S8 to A and the chord line is X8, wherein X8= tan-1{ | S8-0 |/(0.1B) }; p8 to A are planes, and an included angle between a tangent of a cambered surface from P8 to A and a chord line is Y8, wherein Y8= tan-1{ | P8-0 |/(0.1B) };

wherein: origin =0, S1=0.0828, S3=0.1053, S4=0.0974, S5=0.0829, S6=0.0637, S7=0.0431, S8=0.0224, P1=0.0519, P2=0.0538, P3=0.0532, P4=0.0496, P5=0.0424, P6=0.0331, P7=0.0232, P8=0.0132, a =0.

Technical Field

The invention relates to the technical field of rotor blade design, in particular to a rotor wing model with a cutting wing section for a picking unmanned aerial vehicle.

Background

At present, the blades used by the small multi-rotor unmanned aerial vehicle only provide flight aerodynamic force and do not provide other functions.

The cutting body of the cutting tool used in gardens and agriculture and forestry is a cutting tool only having a cutting function, and does not consider other functions.

The high altitude branch cutting of gardens and agriculture and forestry trade at present can only rely on the manual work to climb to the crown eminence, cuts the operation again, and is inefficient, and the risk is big, especially in the inconvenient traffic, the mountain region planting district that large machine is difficult to reach, the casualties that from this produces take place occasionally.

Disclosure of Invention

The technical problem to be solved by the invention is as follows: overcome the technical problem among the prior art, provide a take cutting wing section rotor molding of picking unmanned aerial vehicle.

The technical scheme adopted by the invention for solving the technical problems is as follows:

a rotor wing model with a cutting wing section for a picking unmanned aerial vehicle comprises a blade model and a cutting wing section; the blade modeling comprises a cutting section, a transition section, a main lifting section and a root reinforcing section from the blade end part to the blade root part in sequence, wherein the cutting section is 100% -80% of the blade span direction, the blade torsion angle of the cutting section is 0 degree, the windward side of the blade of the cutting section along 100% -80% of the span direction is of a gradually expanding structure, the gradually expanding tail end is as wide as the transition section, and the airfoil shape of the cutting section is a cutting airfoil shape; the transition section is 80-70% of the span direction of the blade, the blade torsion angle of the transition section is transited from 0 degree to 5 degrees, and the airfoil profile of the transition section is transited smoothly from a cutting airfoil profile to a standard airfoil profile; the main lifting section is 70% -40% of the span direction of the blade, the wing profile of the main lifting section is a standard wing profile, and the shape of the main lifting section is a 16% standard wing profile; the root reinforcing section is 40% -10% of the 4 spanwise direction, the shape of the main lifting section is that 16% of standard airfoil profile is transited to 24% of standard airfoil profile, and the windward side of the root reinforcing section along the 40% -10% of the spanwise direction is of a reducing structure; the butt joint area of the blades and the propeller hub is 10% -0% of the span direction; wherein the front edge of the airfoil of the cutting airfoil is provided with a cutting edge with an acute-angle triangular cross section.

The invention is further improved, wherein the cutting airfoil is sequentially divided into three sections from the front edge to the rear edge along a chord line, namely a cutting edge section, a transition section and a standard airfoil section, wherein the cutting edge section comprises a cutting edge formed by an upper surface and a lower surface, the upper surface and the lower surface are both planes, an upper edge and a lower edge are respectively formed between the upper surface and the lower surface and the chord line, the included angle between the upper edge and the chord line is 10-45 degrees, and the included angle between the lower edge and the chord line is 10-15 degrees; with the leading edge to the trailing edge of a chord line as a direction, dividing the upper airfoil into an origin, characteristic points such as S1, S2, S3, S4, S5, S6, S7, S8 and A, and dividing the lower airfoil into an origin, characteristic points such as P1, P2, P3, P4, P5, P6, P7, P8 and A; the chord length of the cutting airfoil section is B;

wherein the origin to S1 is the upper edge, 20 percent of the chord line, and the origin to P1 is the lower edge, 20 percent of the chord line;

the transition section of the upper airfoil comprises S1 and S2, and the transition section of the lower airfoil comprises P1 and P2; wherein S1 to S2 are 10 percent of chord line, S1 to S2 are convex arc surfaces, and an included angle between a tangent line of the arc surface from S1 to S2 and the chord line is X1, wherein X1= tan-1{ | S2-S1 |/(0.1B) }; P1-P2 are convex cambered surfaces, and an included angle between a tangent line of the cambered surface from P1-P2 and a chord line is Y1, wherein Y1= tan-1{ | P2-P1 |/(0.1B) };

the standard airfoil section of the upper airfoil is S2 to A, and the standard airfoil section of the lower airfoil is P2 to A;

s2 to S3 are 10 percent of chord line, S2 to S3 are convex arc surfaces, and an included angle between a tangent line of the arc surface from S2 to S3 and the chord line is X2, wherein X2= tan-1{ | S3-S2 |/(0.1B) }; P2-P3 are convex cambered surfaces, and an included angle between a tangent line of the cambered surface from P2-P3 and a chord line is Y2, wherein Y2= tan-1{ | P3-P2 |/(0.1B) }; s3 to S4 are 10 percent of chord line, S3 to S4 are convex arc surfaces, and an included angle between a tangent line of the arc surface from S3 to S4 and the chord line is X3, wherein X3= tan-1{ | S4-S3 |/(0.1B) }; P3-P4 are convex cambered surfaces, and an included angle between a tangent line of the cambered surface from P3-P4 and a chord line is Y3, wherein Y3= tan-1{ | P4-P3 |/(0.1B) }; s4 to S5 are 10 percent of chord line, S4 to S5 are convex arc surfaces, and an included angle between a tangent line of the arc surface from S4 to S5 and the chord line is X4, wherein X4= tan-1{ | S5-S4 |/(0.1B) }; P4-P5 are convex cambered surfaces, and an included angle between a tangent line of the cambered surface from P4-P5 and a chord line is Y4, wherein Y4= tan-1{ | P5-P4 |/(0.1B) }; s5 to S6 are 10 percent of chord line, S5 to S6 are convex arc surfaces, and an included angle between a tangent line of the arc surface from S5 to S6 and the chord line is X5, wherein X5= tan-1{ | S6-S5 |/(0.1B) }; P5-P6 are convex cambered surfaces, and an included angle between a tangent line of the cambered surface from P5-P6 and a chord line is Y5, wherein Y5= tan-1{ | P6-P5 |/(0.1B) }; s6 to S7 are 10 percent of chord line, S6 to S7 are convex arc surfaces, and an included angle between a tangent line of the arc surface from S6 to S7 and the chord line is X6, wherein X6= tan-1{ | S7-S6 |/(0.1B) }; P5-P6 are convex cambered surfaces, and an included angle between a tangent line of the cambered surface from P5-P6 and a chord line is Y5, wherein Y5= tan-1{ | P6-P5 |/(0.1B) };

s7 to S8 are 10 percent of chord line, S7 to S8 are convex arc surfaces, and an included angle between a tangent line of the arc surface from S7 to S8 and the chord line is X7, wherein X7= tan-1{ | S8-S7 |/(0.1B) }; P7-P8 are convex cambered surfaces, and an included angle between a tangent line of the cambered surface from P7-P8 and a chord line is Y7, wherein Y7= tan-1{ | P8-P7 |/(0.1B) };

s8 to A are 10 percent of chord line, S8 to P are planes, and the included angle between the planes from S8 to A and the chord line is X8, wherein X8= tan-1{ | S8-0 |/(0.1B) }; p8 to A are planes, and an included angle between a tangent of a cambered surface from P8 to A and a chord line is Y8, wherein Y8= tan-1{ | P8-0 |/(0.1B) };

wherein: origin =0, S1=0.0828, S3=0.1053, S4=0.0974, S5=0.0829, S6=0.0637, S7=0.0431, S8=0.0224, P1=0.0519, P2=0.0538, P3=0.0532, P4=0.0496, P5=0.0424, P6=0.0331, P7=0.0232, P8=0.0132, a =0.

The invention has the beneficial effects that:

1. the blade is divided into three sections from the front edge to the rear edge along a chord line, namely a cutting blade section, a transition section and a standard airfoil section.

2. The cutting edge section has flat upper and lower surfaces forming a cutting edge specific functional region.

3. The transition section is connected with the cutting edge section and the standard airfoil section, the curvature of the curve is continuous with the curvatures of the front section and the rear section, and the integral convex hull of the upper airfoil section curve and the lower airfoil section curve is ensured.

4. The standard airfoil section has standard upper and lower airfoil profile curve, satisfies the aerodynamic requirement, guarantees small-size many rotor unmanned aerial vehicle's flight quality.

5. The blade torsion angle of the cutting section is 0 degree, and a patent cutting airfoil is adopted. When unmanned aerial vehicle flies, the blade of high-speed rotation can realize the cutting function to preceding branch.

6. The transition section blade torsion angle is transited from 5 degrees to 0 degree, and the airfoil profile is transited from a standard airfoil profile to a patent cutting airfoil profile.

7. The main lift section paddle has excellent lift performance, flight quality is guaranteed, and the aerodynamic force requirement of the small unmanned aerial vehicle is met.

8. The chord length of the root reinforcing section is contracted, the relative thickness of the wing profile is increased, and the integral rigidity and strength of the structure are improved.

Drawings

The invention is further illustrated with reference to the following figures and examples.

FIG. 1 is a schematic view of an airfoil curve;

FIG. 2 is a graph of airfoil parameters;

FIG. 3 is a schematic view of a cutting segment edge angle;

FIG. 4 is a table of characteristic section parameters for blade control theory;

fig. 5 is a theoretical view of a blade.

In the figure: D-E is a cutting segment; D-C is a transition section; C-B is a main lifting section; B-A is a root reinforcing section; bmax is the maximum chord length.

Detailed Description

The present invention will now be described in further detail with reference to the accompanying drawings. These drawings are simplified schematic views illustrating only the basic structure of the present invention in a schematic manner, and thus show only the constitution related to the present invention.

As shown in fig. 4 and 5, the invention relates to a rotor wing with cutting wing profile of a picking unmanned aerial vehicle, which comprises a blade profile and a cutting wing profile, and is mainly formed by improving the standard wing profile of the existing agricultural unmanned aerial vehicle; the cutting of branches and the falling of fruits are realized mainly through cutting wing profiles at the end parts of the blade models, and meanwhile, the stable lift force brought by the blades is ensured; the blade modeling comprises a cutting section, a transition section, a main lift section and a root reinforcing section in sequence from the blade end to the blade root, as shown in E-D of figure 4, wherein the cutting section is 100% -80% of the spanwise direction of the blade, the blade torsion angle of the cutting section is 0 degree, the windward side of the blade in the 100% -80% of the spanwise direction of the cutting section is of a gradually expanding structure, the gradually expanding tail end is as wide as the transition section, and the airfoil shape of the cutting section is a cutting airfoil shape; as shown in D-C of FIG. 4, the transition section is 80% -70% of the span direction of the blade, the blade torsion angle of the transition section is transited from 0 degree to 5 degrees, and the airfoil profile of the transition section is transited smoothly from the cutting airfoil profile to the standard airfoil profile; as shown in C-B of fig. 4, the main lift section is 70% -40% of the span direction of the blade, the airfoil profile of the main lift section is a standard airfoil profile, and the shape of the main lift section is a 16% standard airfoil profile; the root reinforcing section is 40% -10% of the 4 spanwise direction, the shape of the main lifting section is that 16% of standard airfoil profile is transited to 24% of standard airfoil profile, for example, the windward side of the B-A root reinforcing section along the spanwise direction 40% -10% of the B-A root reinforcing section in figure 4 is a tapered structure; from A to the end point, the butt joint area of the blade and the propeller hub is 10% -0% of the span direction; wherein the front edge of the airfoil of the cutting airfoil is provided with a cutting edge with an acute-angle triangular cross section; as in fig. 4, where the chord length of the E-E section is 20% bmax, the blade twist angle here is 0 °; the chord length of section D-D is 71% bmax, where the blade twist angle is 0 °; the chord length of the C-C section is 82% bmax, where the blade twist angle is 5 °; the chord length of B-B is 100% bmax, where the blade twist angle is 15 °; the chord length of A-A is 73% bmax, where the blade twist angle is 25 °; the chord length of the blade root butt area is 52% bmax, where the blade twist angle is 28.5 °.

In order to ensure a good cutting effect, as shown in fig. 1, the cutting airfoil is sequentially divided into three sections from the front edge to the rear edge along a chord line, namely a cutting edge section, a transition section and a standard airfoil section, as shown in fig. 3, wherein the cutting edge section comprises a cutting edge formed by an upper surface and a lower surface, the upper surface and the lower surface are both planes, an upper edge and a lower edge are respectively formed between the upper surface and the lower surface and the chord line, an included angle between the upper edge and the chord line is 22.5 degrees, and an included angle between the lower edge and the chord line is 15 degrees; with the leading edge to the trailing edge of a chord line as a direction, dividing the upper airfoil into an origin, characteristic points such as S1, S2, S3, S4, S5, S6, S7, S8 and A, and dividing the lower airfoil into an origin, characteristic points such as P1, P2, P3, P4, P5, P6, P7, P8 and A; the chord length of the cutting airfoil section is B;

the overall modeling parameters are as shown in FIG. 2 and FIG. 1;

wherein the origin to S1 is the upper edge, 20 percent of the chord line, and the origin to P1 is the lower edge, 20 percent of the chord line;

the transition section of the upper airfoil comprises S1 and S2, and the transition section of the lower airfoil comprises P1 and P2; wherein S1 to S2 are 10 percent of chord line, S1 to S2 are convex arc surfaces, and an included angle between a tangent line of the arc surface from S1 to S2 and the chord line is X1, wherein X1= tan-1{ | S2-S1 |/(0.1B) }; P1-P2 are convex cambered surfaces, and an included angle between a tangent line of the cambered surface from P1-P2 and a chord line is Y1, wherein Y1= tan-1{ | P2-P1 |/(0.1B) };

the standard airfoil section of the upper airfoil is S2 to A, and the standard airfoil section of the lower airfoil is P2 to A;

s2 to S3 are 10 percent of chord line, S2 to S3 are convex arc surfaces, and an included angle between a tangent line of the arc surface from S2 to S3 and the chord line is X2, wherein X2= tan-1{ | S3-S2 |/(0.1B) }; P2-P3 are convex cambered surfaces, and an included angle between a tangent line of the cambered surface from P2-P3 and a chord line is Y2, wherein Y2= tan-1{ | P3-P2 |/(0.1B) }; s3 to S4 are 10 percent of chord line, S3 to S4 are convex arc surfaces, and an included angle between a tangent line of the arc surface from S3 to S4 and the chord line is X3, wherein X3= tan-1{ | S4-S3 |/(0.1B) }; P3-P4 are convex cambered surfaces, and an included angle between a tangent line of the cambered surface from P3-P4 and a chord line is Y3, wherein Y3= tan-1{ | P4-P3 |/(0.1B) }; s4 to S5 are 10 percent of chord line, S4 to S5 are convex arc surfaces, and an included angle between a tangent line of the arc surface from S4 to S5 and the chord line is X4, wherein X4= tan-1{ | S5-S4 |/(0.1B) }; P4-P5 are convex cambered surfaces, and an included angle between a tangent line of the cambered surface from P4-P5 and a chord line is Y4, wherein Y4= tan-1{ | P5-P4 |/(0.1B) }; s5 to S6 are 10 percent of chord line, S5 to S6 are convex arc surfaces, and an included angle between a tangent line of the arc surface from S5 to S6 and the chord line is X5, wherein X5= tan-1{ | S6-S5 |/(0.1B) }; P5-P6 are convex cambered surfaces, and an included angle between a tangent line of the cambered surface from P5-P6 and a chord line is Y5, wherein Y5= tan-1{ | P6-P5 |/(0.1B) }; s6 to S7 are 10 percent of chord line, S6 to S7 are convex arc surfaces, and an included angle between a tangent line of the arc surface from S6 to S7 and the chord line is X6, wherein X6= tan-1{ | S7-S6 |/(0.1B) }; P5-P6 are convex cambered surfaces, and an included angle between a tangent line of the cambered surface from P5-P6 and a chord line is Y5, wherein Y5= tan-1{ | P6-P5 |/(0.1B) };

s7 to S8 are 10 percent of chord line, S7 to S8 are convex arc surfaces, and an included angle between a tangent line of the arc surface from S7 to S8 and the chord line is X7, wherein X7= tan-1{ | S8-S7 |/(0.1B) }; P7-P8 are convex cambered surfaces, and an included angle between a tangent line of the cambered surface from P7-P8 and a chord line is Y7, wherein Y7= tan-1{ | P8-P7 |/(0.1B) };

s8 to A are 10 percent of chord line, S8 to P are planes, and the included angle between the planes from S8 to A and the chord line is X8, wherein X8= tan-1{ | S8-0 |/(0.1B) }; p8 to A are planes, and an included angle between a tangent of a cambered surface from P8 to A and a chord line is Y8, wherein Y8= tan-1{ | P8-0 |/(0.1B) };

wherein: origin =0, S1=0.0828, S3=0.1053, S4=0.0974, S5=0.0829, S6=0.0637, S7=0.0431, S8=0.0224, P1=0.0519, P2=0.0538, P3=0.0532, P4=0.0496, P5=0.0424, P6=0.0331, P7=0.0232, P8=0.0132, a =0.

In light of the foregoing description of the preferred embodiment of the present invention, many modifications and variations will be apparent to those skilled in the art without departing from the spirit and scope of the invention. The technical scope of the present invention is not limited to the content of the specification, and must be determined according to the scope of the claims.