By using the interaction between the wind flow and the stabilizer arranged in the wind flow and along the direction of the wind flow, this invention provides the flying object that secures the stability of device or aircraft or stabilizer itself unified with the stabilizer by above effect. The inter
By using the interaction between the wind flow and the stabilizer arranged in the wind flow and along the direction of the wind flow, this invention provides the flying object that secures the stability of device or aircraft or stabilizer itself unified with the stabilizer by above effect. The interaction mentioned above is that when the wind flow hits the stabilizer at a certain angle, the wind flow changes the direction, and the power corresponding its reaction is given to the stabilizer by its reaction.
대표청구항▼
1. A flying object, comprising: a wind flow generating device; andone or more radial stabilizing wings arranged along a center axis of a wind flow in the form of a coaxial line in a wind flow generated by the wind flow generating device,wherein said radial stabilizing wings are arranged such that a
1. A flying object, comprising: a wind flow generating device; andone or more radial stabilizing wings arranged along a center axis of a wind flow in the form of a coaxial line in a wind flow generated by the wind flow generating device,wherein said radial stabilizing wings are arranged such that a relationship between a vertical distance nGC between a center point of total wind flow pressure obtained by synthesizing a center point of wind flow pressure of the respective stabilizing wings and a center of gravity of the flying object, and a vertical distance nGW between a center point of outside wind pressure and the center of gravity of the flying object, is represented by formula (26), wherein: [H]nGC=[W]nGW (26)providing that: [H]=π(HC+Ha)+1πH0(21)[W]=SW[SC](25)[SC]=SC+Sa+1πS0(23)HC=SCr02,Ha=Sar02,H0=S0r02(43)where,r0: a diameter of the wind flow generating device;SC: an area obtained by converting an area of said radial stabilizing wing inside of a spreading wind flow generating device wind into an area of said radial stabilizing wing inside of a shrunk wind flow generating device wind, when the spreading wind flow generating device wind is shrunk such that the wind flow generating device wind flows as a parallel wind flow without changing an air density directly under wind flow generating device, but a calculation of shrinking rate is as follows:a horizontal line on said radial stabilizing wing located at any distance from the wind flow generating device, and a width of spreading of the wind flow generating device wind on its horizontal line be rW, a width of said radial stabilizing wing inside of the wind flow generating device wind be ra, and the width of said radial stabilizing wing on its horizontal line after shrinking be r, and r is represented by formula (3), in which r=ra(r0rw)(3)Sa: the area of said radial stabilizing wing inside of exceeding part of the shrunk wind flow generating device wind when the area of said radial stabilizing wing inside of the exceeding wind flow generating device wind from inside of said spreading wind flow generating device wind is shrunk at a shrinking rate represented by formula (3), and in whichS0: the area (except the area where the wind flow generating device wind is flowing) of said radial stabilizing wing of the wind flow generating device periphery, andSW: a projection area of the flying object. 2. The flying object described in claim 1, wherein a stable hovering condition is π∑iHCinGCi+π∑jHajnGaj+1π∑mH0mnG0m+[W]SW∑kSWknGWk≥nG(28)providing that: [W]=SW[SC](25)[SC]=SC+Sa+1π2S0(23)HCi=SCir02,Haj=Sajro2,Hom=Somr02(44)where,r0: the diameter of the wind flow generating device,SC: the area obtained by converting the area of said radial stabilizing wing inside of the spreading wind flow generating device wind into the area of said radial stabilizing wing inside of the shrunk wind flow generating device wind, when the spreading wind flow generating device wind is shrunk such that the wind flow generating device wind flows as the parallel wind flow without changing the air density directly under the wind flow generating device, but the calculation of shrinking rate is as follows:the horizontal line on said radial stabilizing wing located at any distance from the wind flow generating device, and the width of spreading of the wind flow generating device wind on its horizontal line be rE, the width of said radial stabilizing wing inside of the wind flow generating device wind be ra, and the width of said radial stabilizing wing on its horizontal line after shrinking be r, then r is represented by formula (3), in which r=ra(r0rw)(3)Sa: the area of said radial stabilizing wing inside of exceeding part of the shrunk wind flow generating device wind when the area of said radial stabilizing wing inside of the exceeding wind flow generating device wind from inside of said spreading wind flow generating device wind is shrunk at the shrinking rate represented by formula (3), and in whichS0: the area (except the area where the wind flow generating device wind is flowing) of said radial stabilizing wing of the wind flow generating device periphery,SW: the projection area of the flying object,SCi: an area of each minute part of said SC,Saj: an area of each minute part of said Sa,S0m: an area of each minute part of said S0,SWk: an area of each minute part of said SW,nG: a first multiple coefficient of a vertical distance between a fixed point of a rotational axis of the wind flow generating device and the center of gravity of the flying object for the diameter of the wind flow generating device r0,nGCi: a second multiple coefficient of a vertical distance between each minute part that has the area of said SCi and the center of gravity of the flying object for the diameter of the wind flow generating device r0,nGaj: a third multiple coefficient of a vertical distance between each minute part that has the area of said Saj and the center of gravity of the flying object for the diameter of the wind flow generating device r0,nG0m a fourth multiple coefficient of a vertical distance between each minute part that has the area of said S0m and the center of gravity of the flying object for the diameter of the wind flow generating device r0, andnGWk: a fifth multiple coefficient of a vertical distance between each minute part that has the area of said SWk and the center of gravity of the flying object for the diameter of the wind flow generating device r0. 3. The flying object of claim 2, wherein the flying object has a cross shape stabilizing wing and a cylindrical stabilizing wing and the wings share one wind flow generating device. 4. The flying object of claim 3, further comprising two or more flying objects which are arranged at intervals with center axes thereof being parallel to each other and each has a upwardly directed intake and a downwardly direct exhaust; and a connecting member connecting said two or more flying objects to each other. 5. The flying object of claim 2, further comprising two or more flying objects which are arranged at intervals with center axes thereof being parallel to each other and each has a upwardly directed intake and a downwardly direct exhaust; and a connecting member connecting said two or more flying objects to each other. 6. The flying object of claim 1, wherein the flying object has a cross shape stabilizing wing and a cylindrical stabilizing wing and the wings share one wind flow generating device. 7. The flying object of claim 6, further comprising two or more flying objects which are arranged at intervals with center axes thereof being parallel to each other and each has a upwardly directed intake and a downwardly direct exhaust; and a connecting member connecting said two or more flying objects to each other. 8. The flying object of claim 1, further comprising two or more flying objects which are arranged at intervals with center axes thereof being parallel to each other and each has a upwardly directed intake and a downwardly direct exhaust; and a connecting member connecting said two or more flying objects to each other. 9. A flying object, comprising: a wind flow generating device; andone or more cylindrical stabilizing wings arranged along a center line of a wind flow in the shape of coaxial line in a wind flow generated by concerned wind flow generating device,wherein said cylindrical stabilizing wings are arranged such that a relationship between a vertical distance nGC between a center point of total wind flow pressure obtained by synthesizing a center point of wind flow pressure of the respective stabilizing wings and a center of gravity of concerned flying object, and a vertical distance nGW from a center point of outside wind pressure and a center of gravity of the flying object, is represented by formula (26), wherein [H]nGC=[W]nGW (26)providing that: [H]=π22HD(32)[W]=SW[SC](25)[SC]=π2SD(33)HD=SDr02(37)where;r0: a diameter of the wind flow generating device,SD: a projection area of inside wall when inside diameter of cylindrical stabilizing wing is shrunk into the diameter of the wind flow generating device,SW: a projection area of the flying object. 10. The flying object described in claim 9, wherein a stable hovering condition is π22∑qHDqnGDq+[W]SW∑kSWknGWk≥nG(34)providing that: [W]=SW[SC](25)[SC]=π2SD(33)HDq=SDqro2(39)where;r0: the diameter of the wind flow generating device,SW: the projection area of the flying object,SD: the projection area of inside wall when inside diameter of cylindrical stabilizing wing is shrunk into the diameter of the wind flow generating device,SWk: an area of each minute part of said SW,SDq: the arc an area of each minute part of said SD,nG: a first multiple coefficient of a vertical distance between a fixed point of a rotational axis of the wind flow generating device and the center of gravity of the flying object for the diameter of the wind flow generating device r0,nGWk: a second multiple coefficient of a vertical distance between each minute part that has the area of said SWk and the center of gravity of the flying object for the diameter of the wind flow generating device r0,nGDq: a third multiple coefficient of a vertical distance between each minute part that has the area of said SDq and the center of gravity of the flying object for the diameter of the wind flow generating device r0. 11. The flying object of claim 10, wherein the flying object has a cross shape stabilizing wing and a cylindrical stabilizing wing and the wings share one wind flow generating device. 12. The flying object of claim 11, further comprising two or more flying objects which are arranged at intervals with center axes thereof being parallel to each other and each has a upwardly directed intake and a downwardly direct exhaust; and a connecting member connecting said two or more flying objects to each other. 13. The flying object of claim 10, further comprising two or more flying objects which are arranged at intervals with center axes thereof being parallel to each other and each has a upwardly directed intake and a downwardly direct exhaust; and a connecting member connecting said two or more flying objects to each other. 14. The flying object of claim 9, wherein the flying object has a cross shape stabilizing wing and a cylindrical stabilizing wing and the wings share one wind flow generating device. 15. The flying object of claim 14, further comprising two or more flying objects which are arranged at intervals with center axes thereof being parallel to each other and each has a upwardly directed intake and a downwardly direct exhaust; and a connecting member connecting said two or more flying objects to each other. 16. The flying object of claim 9, further comprising two or more flying objects which are arranged at intervals with center axes thereof being parallel to each other and each has a upwardly directed intake and a downwardly direct exhaust; and a connecting member connecting said two or more flying objects to each other.
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