RU85444U1 - BLADE SYSTEM OF DELAS OF WIND-HYDRO-POWER PLANTS, AIR / COMBIN OR LOAD-SCREWS - Google Patents

Abstract

1. The blade system of wind-hydroelectric power plants, propellers / propellers or rotors, which contains one, two, three or more base blades placed in the same plane at an angle to the longitudinal axis of each of the blades and in the plane of rotation of these base blades, while the blades are installed either motionless or with the possibility of changing the pitch of the screw, and the blades are made of any geometric shape in plan and with different geometric and aerodynamic twist, the blades are made either metal or wooden, or of plastic or composite materials, and a system with one blade contains a counterweight, which is mounted axisymmetrically to the longitudinal axis of the specified blade, characterized in that it additionally contains one, two or more sets of blades, while the number of blades in each of the additional sets coincides in number with a set of base blades, the blades of each of the additional sets are made with decreasing blade length relative to the length of the blades of the base set and each of the sets will include flax, the blades of additional sets are placed in the plane of rotation of the base blades in the sector between the base blades with an angular shift in the same direction as the linear dimensions of the blades decrease, the blades of additional sets are placed in the plane of rotation of the base blades with a shift of their longitudinal axis by an angle of at least 1/1000 size of the sector between the base blades and the shorter length of the additional blade relative to the adjacent additional blade with a large linear size, the blades are additional

Description

The utility model relates to the field of technology, in particular to a rotor-motor group, namely, to one or multi-blade propeller systems, which are made in the form of pushing / pulling propellers that are installed on any type of aircraft and other type of aircraft such as rotary wing aircraft and airships, on air-cushion vehicles, self-propelled vehicles, or to one or multi-blade rotor systems of helicopters, or to one or multi-blade wind / hydra drive systems power plants, as well as to one or multi-blade systems of vehicles that float on or under water, the power plant of which is equipped with a propeller.

Known blade system of wind-hydroelectric power plants, propellers / propellers or rotors, which contains one, two, three or more base blades placed in one plane at an angle to the longitudinal axis of each of the blades and in the plane of rotation of these base blades, while the blades installed either motionless or with the possibility of changing the pitch of the screw, and the blades are made of any geometric shape in plan and with constant or with different geometric and aerodynamic twist along the feather blade / 1 /.

The disadvantages of the known blade system of wind / hydroelectric power plants, propellers / propellers or rotors include the fact that with the known structural design of one or multi-blade propeller systems at high speeds (the latter applies only to propellers and propellers). reduced screw efficiency. For the blades of wind-hydroelectric power plants, the disadvantage is that there is no increase in the pulling component of the force and the screw stops pulling at high speeds of rotation of the blades of the specified screw.

Known blade system of wind-hydroelectric installations, air / propellers or rotors, which contains one, two, three or more base blades placed in one plane at an angle to the longitudinal axis of each of the blades and in the plane of rotation of these base blades, while the blades installed either motionless or with the ability to change the pitch of the screw, and the blades are made of any geometric shape in plan and with constant or with different geometric and aerodynamic twist along the feather blade / 2 /.

The disadvantages of the known blade system of wind / hydroelectric power plants, propellers / propellers or rotors include the fact that with the known structural design of one or multi-blade propeller systems at high speeds (the latter applies only to propellers and propellers). reduced screw efficiency. For the blades of wind-hydroelectric installations, the disadvantage is that there is no increase in the traction component of the force and the screw stops pulling at high speeds of rotation of the specified screw (blades).

The closest technical solution, both in essence and in terms of tasks to be solved, which is selected as the closest analogue (prototype). is a Delas blade system of hydro-power plants, air / propellers or rotors, which contains one, two, three or more base blades placed in one plane at an angle to the longitudinal axis of each of the blades and in the plane of rotation of these base blades, while the shovels are installed either motionless or with the possibility of changing the pitch of the screw, the blades being made of any geometric shape in plan and with different geometric and aerodynamic twists, the blades are made of either metal or indented, or from plastic or composite materials, and the system with one blade contains a counterweight, which is mounted axisymmetrically to the longitudinal axis of the specified blade / 3 /.

The disadvantages of the well-known blade system of Delas wind-hydro power plants, air / propellers or rotors, which is selected as the closest analogue (prototype). refers to the fact that with the known design of one or multi-blade system of screws, at high speeds, the efficiency of the screw is reduced (the latter applies only to propellers and propellers). For the blades of wind-hydro power plants, the disadvantage is that there is no increase in the thrust component of the force and the screw stops pulling at high speeds of rotation of the blades of the specified screw.

The utility model is based on the task of installing in the sector between the base vanes one, two or more additional vanes that are smaller than the basic ones, as well as changing the geometrical dimensions of these additional vanes and installing these vanes relative to the axis of thrust creation, to ensure a reduction in torque blade resistance, to achieve the effect of tightening the "degeneration" of the screw, when the screw stops pulling, towards high speeds, as well as to increase the traction component with silt.

The essence of the utility model in the Delas blade system of wind-hydroelectric power plants, air / propellers or rotors, which contains one, two, three or more base blades placed in one plane at an angle to the longitudinal axis of each of the blades and in the plane of revolution of these base blades while the blades are installed either motionless or with the possibility of changing the pitch of the screw, and the blades are made of any geometric shape in plan and with different geometric and aerodynamic twist, the blades are made or metal steel, or wooden, or plastic or composite materials, and a single-blade system contains a counterweight, which is mounted axisymmetrically to the longitudinal axis of the specified blade, consists in that it additionally contains one, two or more sets of blades. The essence of the utility model consists in the fact that the number of blades in each of the additional sets coincides in number with the set of base blades, the blades of each of the additional sets are made with decreasing blade length relative to the length of the blades of the base set and each of the sets, the blades of additional sets are located in the plane of rotation of the base blades in the sector between the base blades with an angular shift in the same direction as the linear dimensions of the blades decrease, the blades to additional sets are placed in the plane of rotation of the base blades with a shift of its longitudinal axis by an angle of not less than 1/1000 of the sector between the base blades and the shorter length of the additional blade relative to the adjacent additional blade with a large linear size, the blades of additional sets are placed or in the reference plane of the base blades, when the longitudinal axis of the blades of additional sets are located in the plane of rotation of the blades of the base set, or with the placement of one, two or more sets of additional blades in the plane of rotation of the base blades and with the placement of other sets of additional blades with a shift of their rotation planes forward / backward relative to the plane of rotation of the blades of the base set along the axis of the thrust, or with a shift of all planes of rotation of the sets of additional blades forward / back relative to the plane of rotation the blades of the base set along the axis of creating traction, the blades of additional sets are located with their longitudinal axis or at a constant angle m relative to the longitudinal axis of the base blades, or with the possibility of changing the installation angle both between the base blade and the additional blade, which has the greatest length, and between the blades of other additional sets, the base spade and the set / sets of additional blades are installed with the same pitch and with a reduced / increased pitch of the blades of the additional set relative to the pitch of the base blades. The essence of the utility model also lies in the fact that at least 1% of the length of the base blade is made to reduce the length of the blade along the sets from the largest to the smallest length of the additional blade, the blades of additional sets are made either with the same geometric and aerodynamic twist relative to the base blade, or with different in a system of wind / hydropower plants, air / propellers or rotors, which contains one base blade and one base counterweight, the number of blades and counterweights in each of the additional underwear sets coincides in number with a set of base blades and counterweights, the angle of shift of the largest additional blade relative to the base blade and the shortest additional blade relative to the adjacent additional blade with a large linear size, is made either the same or different in size between the said blades, when placing the rotation planes of the blades of the additional sets forward / backward relative to the plane of rotation of the blades of the base set, sets additional blades are placed sequentially to reduce their linear dimensions relative to the base blades in the direction of rotation of the base blade, when placing the plane of rotation of the blades of additional sets forward / back relative to the plane of rotation of the blades of the base set, sets of additional blades are placed sequentially one from the other and the first of the additional sets from the base the blades at the same or at different distances, and the base blades and blades of one of all the additional GOVERNMENTAL kits performed or of the same material or from different materials.

A comparative analysis of the technical solution with the prototype shows that the Delas blade system of wind turbines, air / propellers or rotors, which is claimed, is characterized in that it additionally contains one, two or more sets of blades, with the number of blades in each of the additional sets coincides in number with a set of base blades, the blades of each of the additional sets are made with a decrease in the length of the blade relative to the length of the blades of the base set and each of one of the sets inclusive, the blades of additional sets are placed in the plane of rotation of the base blades in the sector between the base blades with an angular shift in the same direction as the linear dimensions of the blades decrease, the blades of additional sets are placed in the plane of revolution of the base blades with a shift of their longitudinal axis by the angle is not less than 1/1000 of the size of the sector between the base blades and the shorter length of the additional blade relative to the adjacent additional blade with a large linear measure, the blades of additional sets are placed either in the plane of rotation of the base blades, when the longitudinal axis of the blades of the additional sets are located in the plane of rotation of the blades of the base set, or with the placement of one, two or more sets of additional blades in the plane of rotation of the base blades and with the placement of other sets of additional blades with a shift of the planes of its rotation forward / backward relative to the plane of rotation of the blades of the base set along the axis of traction, or with a shift of sun x planes of rotation of the sets of additional blades forward / backward relative to the plane of rotation of the blades of the base set along the axis of traction, the blades of additional sets are located with their longitudinal axis or at a constant angle relative to the longitudinal axis of the base blades, or with the possibility of changing the installation angle both between the base blade and the additional blade that has the greatest length, and between the blades of other additional sets, the base blades and the set / sets of additional blades are installed both with the same pitch and with a reduced / increased pitch of the blades of the additional set relative to the pitch of the base blades, and at least 1% of the length of the base blade is made to reduce the length of the blade in sets from the largest along the length of the additional blade to the smallest, the blades of additional sets are made or the same geometric and aerodynamic twist relative to the base blade, or with different ones in the system of wind-hydroelectric power plants, air / propellers or rotors, which holds one base blade and one base counterweight, the number of blades and counterweights in each of the additional sets coincides in number with the set of base blades and counterweights, the angle of shift of the largest additional blade relative to the base blade and the shortest additional blade relative to the adjacent additional blade with a large linear size, made either the same or different in size between the said blades, when placing the planes of rotation of the blades additionally set of forward / backward sets relative to the plane of rotation of the blades of the base set, sets of additional blades are arranged sequentially to reduce their linear dimensions relative to the base blades in the direction of rotation of the base blade, when placing the planes of rotation of the blades of additional sets forward / back relative to the plane of rotation of the blades of the base set, additional sets the blades are placed sequentially one from the other and the first of the additional sets from the base output blades at the same or at different distances, and the base blades and blades of one or all additional sets are made either of the same material or of different materials.

Thus, the Delas blade system of wind-hydro power plants, propellers / propellers or rotors, which is claimed, meets the criterion of the utility model “novelty”.

The essence of the utility model is illustrated using illustrations, in which Figs. 1-6 show diagrams of the structural arrangement of base blades that serve as the basis for the Delas blade system of wind-hydroelectric power plants, propellers / propellers or rotors, which is claimed, Fig. 7 shows an arrangement motionless of the base blades, Fig. 8 shows an arrangement of the base blades with the possibility of changing the pitch A of the screw, Figs. 9-15 show embodiments of the feather of the base blades, Fig. 16 shows a design diagram pen of the base blade with different geometric and aerodynamic twist, Fig.17-25 shows a General view of the blade system of the Delas wind-hydroelectric, air / propeller or rotors, which is claimed with one base blade and with one or more sets / sets of additional blades , which are placed in the plane of rotation of the base blades, FIGS. 26-34 show a General view of the Delas blade system of wind-hydropower, air / propellers or rotors, which is claimed, with two base blades and with one and earlier a set / sets of additional blades that are located in the plane of rotation of the base blades, Figs. 35-40 shows a General view of the Delas blade system of wind-hydroelectric, air / propellers or rotors, which is claimed, with three base blades and with one or more a set / sets of additional blades, which are placed in the plane of rotation of the base blades, Figs. 41-46 show a General view of the Delas blade system of wind-gyro-energy, air / propellers or rotors, which is claimed with with four base blades and with one or more sets / sets of additional blades that are located in the plane of rotation of the base blades, Figs. 47-52 show a General view of the Delas blade system of wind-hydropower, air / propellers or rotors, which is claimed, with five base blades and with one or more sets / sets of additional blades, which are placed in the plane of rotation of the base blades, Figs. 53-58 show a General view of the Delas blade system of wind, hydropower, air / rowing or rotors, which is claimed, with six base blades and with one or more sets / sets of additional blades, which are placed in the plane of rotation of the base blades, Figs. 59-60 show schemes for performing additional sets of blades with decreasing blade length L relative to the length L bl Fig. 61 shows the layout of additional sets of blades in the plane Q of rotation of the base blades with a shift of its longitudinal axis by an angle α relates the size of the sector (at an angle Ψ). between the base blades and the shorter length of the additional blade relative to the adjacent additional blade with a large linear size, Fig.62-63 shows the arrangement of base and additional blades in the plane Q of rotation of the base blades, Fig.64-67 shows the layout of one, two or more sets of additional blades in the plane Q of rotation of the base blades and with the placement of other sets of additional blades with a shift Δ of the planes Q1 of its rotation forward / backward relative to the plane Q rotation of the blades of the base set along the axis of creating the thrust vector P, Figs. 68-71 show the layout of one, two or more sets of additional blades with a shift Δ of all planes Q1 of rotation of the sets of additional blades forward / backward relative to the plane Q of rotation of the blades of the base set along the axis the creation of the thrust vector P, Fig. 72 shows the installation diagram of the additional blade relative to the base blades with the possibility of changing the installation angle α as between the base blade and the additional blade, which the second one has the longest length L, and between the blades of other additional sets, Fig. 73 shows a diagram of an installation of a base blade and a set of additional blades with the same pitch λ relative to a pitch λ of base blades, Fig. 74 shows a diagram of an installation of a base blade and a set of additional blades with a reduced / increased pitch λ of the blades of the additional set relative to the pitch λbl of the base blades, Fig. 75 shows a diagram for reducing the length of the additional blade in sets from the largest Lmax in length indicated additional blades to the smallest Lmin relative to the length λbl of the base blade, Figs 76-83 show the layout of the base and additional blades with the angle α (namely, α1, α2, α3). shear of the longest maximum blade length Lmax relative to the base blade and the smaller Lmin along the length of the additional blade relative to the adjacent additional blade with a large linear size Lj, Figs 84-89 show diagrams of options for constructive implementation of the Delas blade system of wind-hydroelectric power plants, air / rowing or rotors, which is claimed, on Fig-96 shows a diagram of the options for the structural placement of the blade system of the Delas wind-hydropower plants, air / propellers or rotors, which is claimed, on airplanes of different schemes, Figs. 97-99 show diagrams of options for constructive placement of a Delas blade system of wind-hydro power plants, air / propellers or rotors, which is claimed, on helicopters of different schemes, in Figs. .100 shows a diagram of a variant of the structural placement of the Delas blade system of wind-hydroelectric power plants, air / propellers or rotors, which is claimed to be a wind power installation, Fig. 101 shows a comp lecture of additional blades on the blade system of a wind power installation, FIGS. 102-104 are diagrams of options for constructive placement of a Delas blade system of wind-hydro power plants, air / propellers or rotors, which is claimed on helicopters of different schemes, FIGS. 105-106 are shown general view of the Delas blade system of wind-hydroelectric power plants, propellers / propellers or rotors, which is claimed with one base blade, Figs. 107-109 show general views of the Delas blade system 110-111 shows variants of the general view of the Delas blade system of wind-hydroelectric installations, air / propellers or rotors, with three base vanes, with three base blades, in Fig.112 shows a diagram of the creation of a vortex by additional blades, in Fig.113-114 shows a diagram of increasing the pulling component of the force on the part of the base blade, which is located on a larger radius R than the core of the vortices, which converge yat with short (extra) endings. blades of the Delas blade system of wind-hydroelectric installations, air / propellers or rotors, which is claimed, respectively, for one and two additional blades.

The Delas blade system of wind-hydroelectric power plants, propellers / propellers or rotors contains (see Fig.1-111 - as an embodiment of the design). one (see figure 1). two (see figure 2). three (see figure 3). or more base blades 1, for example, four (see figure 4). five (see figure 5). six (see Fig.6). placed in one plane Q at an angle ψ to the longitudinal axis 2 of each of the blades 1 and in the plane Q of rotation of these base blades 1. Structurally and technologically, the blades 1 are installed or stationary (see Fig.7). or with the ability to change the pitch λ of the screw (see Fig. 8). Structurally, the blades 1 are made of any geometric shape in plan (see Fig.9-15). and with different geometric and aerodynamic twist (see Fig.16). Structurally and technologically, the blades 1 are made either metal, or wooden, or from plastic or composite materials. Structurally and technologically, the system with one blade 1 contains a counterweight 3, which is mounted axisymmetrically to the longitudinal axis 2 of the specified blade 1 (relative to the axis of rotation 4). (see figure 1). The blade system of wind / hydropower plants, propellers / propellers or rotors additionally contains one, two or more sets of blades 5, while the number of blades 5 in each of the additional sets coincides in number with the set of base blades 1 (see Fig. 17-58 ) Structurally and technologically, the blades 5 of each of the additional sets are made with a decrease in the length L of the blade 5 (L1, L2, ... Li, see Figs. 59-60). relative to the length L bl blades 1 of the base set and each of the sets inclusive (see Fig.17-58 and Fig.59-60). The blades of 5 additional sets are placed in the Q plane of rotation of the base blades 1 in the sector (at an angle Ψ). between the base blades 1 with an angular shift in the same direction as the linear dimensions of the blades decrease (Lbl> L, L> L1, L1> Li, Lbl >> Li). (see Fig. 59-60). Structurally and technologically, the blades of 5 additional sets are placed in the Q plane of rotation of the base blades 1 with a shift of its longitudinal axis 6 by an angle α of at least 1/1000 of the sector between the base blades 1 and the shorter length of the additional blade 5 relative to the adjacent additional shovel 5 with a large linear size (see Fig. 61 and Figs. 17-20, 26-30, 35-36, 38-39, 41-44, 47, 49, 53, 55, 57). Structurally and technologically, the blades of 5 additional sets are placed either in the Q plane of rotation of the base blades 1, when the longitudinal axis 6 of the blades 5 of additional sets are located in the Q plane of rotation of the blades 1 of the base set (see Figs. 62-63). or with the placement of one, two or more sets of additional blades 5 in the plane Q of rotation of the base blades 1 and with the placement of other sets of additional blades 5 with a shift Δ of the planes Q1 of their rotation forward / backward relative to the plane Q of rotation of the blades 1 of the base set along the axis 7 of the vector thrust P (see Fig.64-67). or with a shift Δ of all rotation planes Q1 of the sets of additional blades 5 forward / backward relative to the plane Q of rotation of the blades 1 of the base set along the axis 4 of rotation of the blade system, which coincides with the thrust vector P (see Fig. 68-71). and the incoming air flow V. The shovel 5 additional sets are located with their longitudinal axis 6 or at a constant angle α relative to the longitudinal axis 2 of the base blades 1 (see Fig.17-61). or with the possibility of changing the installation angle α both between the base blade 1 and the additional blade 5, which has the largest length L, and between the blades 5 of other additional sets (see Fig. 72). The base blades 1 and the set / sets of additional blades 5 are installed as with the same pitch λ (div. Fig. 73). and with a reduced / increased pitch λ of the blades 5 of the additional set relative to the pitch λbl of the base blades (see Fig. 74). Structurally and technologically, the reduction in the length L of the additional blade 5 in sets is from the largest Lmax along the length of the additional blade 5 to the smallest Lmin (with intermediate blades 5 of length Lj). not less than 1% of the length Lbl of the base blade 1 is made (see Fig. 75). Structurally, the blades 5 additional sets are made either with the same geometric and aerodynamic twist relative to the base blade 1, or with different ones.

Structurally, in the Delas blade system of wind-hydroelectric power plants, air / propellers or rotors, which contains one base blade 1 and one base counterweight 3, the number of blades 5 and additional counterweights 7 in each of the additional sets coincides in number with the set of base blades 1 and counterweights 3 (see Fig. 1, Figs. 17-25 and Figs. 105-106). Angle α (namely, α1, α2, α3). the shift of the largest length Lmax of the additional blade 5 relative to the base blade 1 and smaller Lmin along the length of the additional blade 5 relative to the adjacent additional blade 5 with a large linear size Lj, is made or the same (see diagrams in Figs. 76, 79). or different in size between the said blades (see Fig.77-78, 80-83). When placing the Q1 rotation plane of the blades 5 additional sets forward / backward relative to the Q plane of rotation of the blades 1 of the base set, sets of additional blades 5 are placed sequentially to reduce their linear dimensions (Lmax, Lj, Lmin). relative to the base blades 1 in the direction of rotation of the base blade 1 (see Fig.64-71). When placing the Q1 rotation plane of the blades 5 additional sets forward / backward relative to the Q plane of rotation of the blades 1 of the base set, sets of additional blades 5 are placed sequentially from each other and the first of the additional sets from the base blades 1 at the same distance Δ (see Fig. 64- 67). or at different distances Δ (see Fig.68-71). Technologically, the basic blades 1 and blades 5 of one or all additional sets are made of either the same material or different materials, for example, metal-metal, metal-wood, metal-plastic, wood-metal, wood-plastic, metal-wood-plastic etc..

The Delas blade system of wind-hydro power plants, propellers / propellers or rotors, which is claimed, works as follows.

Pre-form the blade system of wind / hydropower plants, propellers / propellers or rotors, which is created with one (see figure 1 and Fig.17-25). two (see Fig.2 and Fig.26-34). three (see Fig. 3, Figs. 35-40 and Figs. 76-83). or more base blades 1, for example, four (see figure 4 and figures 41-46). five (see FIG. 5 and FIGS. 47-52). six (see Fig.6 and Fig.53-58). the blades, which are placed in the same plane Q at an angle Ψ to the longitudinal axis 2 of each of the blades 1 and in the plane Q of rotation of these base blades 1. Structurally and technologically, the blades 1 are installed or motionless (see Fig.7 and Fig.1-5). or with the ability to change the pitch λ of the screw (see Fig. 8). Structurally, the blades 1 perform any geometric shape in plan (see Fig.9-15). and with different geometric and aerodynamic twist (see Fig.16). Structurally and technologically, the blades 1 are made either metal, or wooden, or from plastic or composite materials. Structurally and technologically, a system with one base blade 1 is performed with a base counterweight 3, which is mounted axisymmetrically to the longitudinal axis 2 of the specified blade 1 (relative to the axis of rotation 4). (see Fig.1, Fig.17-25 and Fig.105-106).

Further, wind-hydroelectric installations, propellers / propellers or rotors are added to the Delas basic blade system (namely, technologically rigidly (or with a change in the installation angle). a set / sets of additional blades 5. Moreover, the number of blades 5 in each of the additional sets that are installed in the sector between the base blades 1 must coincide in number with the set of base blades 1 (see diagrams in Figs. 17-58, Fig. 76 -83 and Figs. 84-108). Structurally and technologically, the blades 5 of each of the additional sets are performed with decreasing the length L of the blade 5 (L1, L2, ... Li, see Figs. 59-60). relative to the length L bl blades 1 of the base set and each of the sets inclusive (see Fig.17-58, Fig.59-60, Fig.61-83 and Fig.84-108). The blades 5 additional sets are placed in the plane Q of rotation of the base blades 1 in the sector (at an angle Ψ). between the base blades 1 with an angular shift in the same direction as the linear dimensions of the blades decrease (Lbl> L, L> L1, L1> Li, Lbl >> Li). (see Figs. 59-60). Structurally and technologically, the blades of 5 additional sets are placed in the Q plane of rotation of the base blades 1 with a shift of their longitudinal axis 6 by an angle α of at least 1/1000 of the sector between the base blades 1 and the shorter length of the additional blade 5 relative to the adjacent additional blade 5 with a large linear size (see diagrams in Fig. 61 and in Figs. 17-20, 26-30, 35-36, 38-39, 41-44, 49, 53, 55, 57). Structurally and technologically, the blades 5 of the additional sets are placed either in the Q plane of rotation of the base blades 1, when the longitudinal axis 6 of the blades 5 of the additional sets are located in the Q plane of rotation of the blades 1 of the base set (see Figs. 62-63). or with the placement of one, two or more sets of additional blades 5 in the plane Q of rotation of the base blades 1 and with the placement of other sets of additional blades 5 with a shift Δ of the planes Q1 of its rotation forward / backward relative to the plane Q of rotation of the blades 1 of the base set along the axis of the thrust vector P (see diagrams on Fig.64-67). or with a shift Δ of all planes Q1 of rotation of the sets of additional blades 5 forward / backward relative to the plane Q of rotation of the blades 1 of the base set along the axis of creation of the thrust vector P (see diagrams in Figs. 68-71). The blades 5 of the additional sets have their longitudinal axis 6 or at a constant angle α relative to the longitudinal axis 2 of the base blades 1 (see Fig.17-61). or with the possibility of changing the installation angle α both between the base blade 1 and the additional blade 5, which has the largest length L, and between the blades 5 of other additional sets (see Fig. 72). The base blades 1 and the set / sets of additional blades 5 are installed either with the same pitch λ, or with a reduced / increased pitch λ of the blades 5 of the additional set relative to the pitch λbl of the base blades (see Fig. 74). Structurally and technologically, reducing the length L of the blade 5 in sets from the largest Lmax along the length of the additional blade 5 to the smallest Lmin performs at least 1% of the length Lbl of the base blade 1 (see Fig. 75). Structurally, the blades 5 additional sets are performed either with the same geometric and aerodynamic twist relative to the base blade 1, or with different ones.

If the Delas blade system of wind-hydroelectric power plants, air / propellers or rotors is made such that it contains one base blade 1 and one base counterweight 3, then the number of additional blades 5 and additional counterweights 7 in each of the additional sets must match the number of the set base blades 1 and counterweights 3 (see Fig. 1, Figs. 17-25 and Figs. 105-106). for example, two or three additional blades 5 are installed, while two or three counterweights 7 should be installed, respectively, which are placed axisymmetrically corresponding to the corresponding additional blades 5 (when placing one base blade 1 and base counterweight 3).

In the formation of the Delas blade system of wind-hydro power plants, propellers / propellers or rotors, which is claimed, the following design solutions are applied:

- angle α of shift (namely, α1, α2, α3). the largest in length Lmax of the additional blade 5 relative to the base blade 1 and the smaller Lmin in the length of the additional blade 5 relative to the adjacent additional blade 5 with a large linear size Lj, are either the same (see the diagrams in Figs. 76, 79). or different in size between the said blades (see diagrams in Figs. 77-78 and in Figs. 80-83) .;

- when placing the planes Q1 of rotation of the blades 5 additional sets forward / backward relative to the plane Q of rotation of the blades 1 of the base set, sets of additional blades 5 are placed sequentially to reduce their linear dimensions relative to the base blades 1 in the direction of rotation of the base blade 1 (see Fig. 64- 71) .;

- when placing the planes Q1 of rotation of the blades 5 additional sets forward / backward relative to the plane Q of rotation of the blades 1 of the base set, sets of additional blades 5 are placed sequentially from each other and the first of the additional sets from the base blades 1 at the same distance Δ (see Fig. 64 -67). or at different distances Δ (see diagrams on Fig.68-71 and Fig.108-109).

Technologically, the basic blades 1 and blades 5 of one of all the additional sets are made either of the same material or of different materials, for example, metal-metal, metal-wood, metal-plastic, wood-metal, wood-plastic, metal-wood-plastic etc..

The manufactured Delasian blade system of wind-hydroelectric power plants, propellers / propellers or rotors, which is claimed, is used as follows, taking into account the physical effect of the positive influence of the vortices 9, which descend from the end of 8 short blades 5 of the additional set, on the flow around the base blades 1.

For air (that are installed on the aircraft 10). propeller and rotor (which are installed on the helicopter 11). This effect has the following mechanism.

When the screw rotates, on which the base 1 and additional blades 5 are installed, from the tip 8 of each of the blades (positions 1 and 5). the final vortices descend 9. The vortices 9, which descend from the tips 8 of the short blades 5, generate “ascending” inductive velocities into parts of the long (base) ones. blades 1, which are located on a radius R greater than the length L of the short blades 5 (see Fig. 112). This allows you to reduce the moment from the inductive resistance of the base blade 1, in addition, the effect of tightening the "degeneration" of the screw is achieved (when the screw of the aircraft 10 or 11 stops pulling). towards high speeds (the latter applies only to propellers and propellers).

For the blades of wind-hydroelectric power plants (see Fig.100-101). the effect of the presence of vortices 9, which descend from the short blades 5, consists in the fact that the inductive velocities generated by them lead to an increase in the pulling force component (see Fig. 113). on the part of the base blade 1, which is located on a larger radius R (see Fig.112-113). than the cores 12 of the indicated vortices 9, which come off the tips 8 of the short blades 5 (see the diagrams in Figs. 112-113, and in Fig. 114 - where the number of additional blades 5 is selected more than one - for example, two).

Improving the efficiency of the application of the Delas blade system of wind-hydroelectric power plants, air / propellers or rotors, which is claimed, compared with the prototype, is achieved by establishing between the base blades of the set / sets of additional blades that are placed in the sector between the base blades with a decrease in size (if whether two more sets of additional blades are installed). these additional blades in the direction of rotation of the screw. Improving the efficiency of the use of the Delas blade system of wind-hydroelectric installations, air / propellers or rotors, which is claimed, compared with the prototype, is achieved by the fact that the installation of additional blades, when the length of the largest additional blades is less than the length of the base blade, allows to reduce the moment from the inductive resistance of the base blade, in addition, the effect of tightening the "degeneration" of the screw is achieved (when the screw stops pulling). towards high speeds. Improving the efficiency of the use of the Delas blade system of wind-hydroelectric power plants, propellers / propellers or rotors, which is claimed, compared with the prototype, is also achieved by the fact that this effect is achieved on additional blades (if two more sets of additional blades are installed in sector between the base blades).

INFORMATION SOURCES

USSR copyright certificate No. 1295644 A1 of 06/10/1985. IPC 7 V64C 11/00 - analogue.

Military Parade Magazine. July-august 1995, Publishing House A / O "Military Parade", M., 1995, pp. 73-77 - analogue.

GF Burago, VD Votyakov "Aerodynamics". Part II Aerodynamics of aircraft parts. Edited by professor, doctor of technical sciences G.F. Burago. Edition of VVIA them. prof. N.E. Zhukovsky, M., 1961, Chapter XXI "Basic information on aerodynamics of propellers." p. 415-438, Fig. 21.1, Figs. 21.36-21.37 - prototype.

Claims (6)

1. The blade system of wind-hydroelectric power plants, propellers / propellers or rotors, which contains one, two, three or more base blades placed in the same plane at an angle to the longitudinal axis of each of the blades and in the plane of rotation of these base blades, while the blades are installed either motionless or with the possibility of changing the pitch of the screw, and the blades are made of any geometric shape in plan and with different geometric and aerodynamic twist, the blades are made either metal or wooden, or of plastic or composite materials, and a system with one blade contains a counterweight, which is mounted axisymmetrically to the longitudinal axis of the specified blade, characterized in that it additionally contains one, two or more sets of blades, while the number of blades in each of the additional sets coincides in number with a set of base blades, the blades of each of the additional sets are made with decreasing blade length relative to the length of the blades of the base set and each of the sets will include flax, the blades of additional sets are placed in the plane of rotation of the base blades in the sector between the base blades with an angular shift in the same direction as the linear dimensions of the blades decrease, the blades of additional sets are placed in the plane of rotation of the base blades with a shift of their longitudinal axis by an angle of at least 1/1000 size of the sector between the base blades and the shorter length of the additional blade relative to the adjacent additional blade with a large linear size, the blades are additional sets are placed either in the plane of rotation of the base blades, when the longitudinal axis of the blades of the additional sets are located in the plane of rotation of the blades of the base set, or with the placement of one, two or more sets of additional blades in the plane of rotation of the base blades and with the placement of other sets of additional blades with a shift of the planes its rotation forward / backward relative to the plane of rotation of the blades of the base set along the axis of traction, or with a shift of all planes of rotation of additional blades of the forward / backward blades relative to the plane of rotation of the blades of the base set along the axis of traction, the shovels of additional sets are located with their longitudinal axis or at a constant angle relative to the longitudinal axis of the base blades, or with the possibility of changing the installation angle as between the base blade and the additional blade, which has the greatest length, and between the blades of other additional sets, the base blades and the set / sets of additional blades are installed both from one at the same step, and with a reduced / increased pitch of the blades of the additional set relative to the pitch of the base blades, and at least 1% of the length of the base blade is made to reduce the length of the blade along the sets from the largest along the length of the additional blade to the smallest, the blades of additional sets are made with the same geometric and aerodynamic twist relative to the base of the blade, or with different. 2. The blade system according to claim 1, characterized in that in the system of wind-hydroelectric power plants, air / propellers or rotors, which contains one base blade and one base counterweight, the number of blades and counterweights in each of the additional sets is the same as a set of base blades and counterweights. 3. The blade system according to claim 1, characterized in that the shear angle of the largest along the length of the additional blade relative to the base blade and smaller along the length of the additional blade relative to the adjacent additional blade with a large linear size, is made either the same or different in size between the said blades . 4. The blade system according to claim 1, characterized in that when placing the planes of rotation of the blades of the additional sets forward / backward relative to the plane of rotation of the blades of the base set, sets of additional blades are placed sequentially to reduce their linear dimensions relative to the base blades in the direction of rotation of the base blade. 5. The blade system according to claim 1 or 4, characterized in that when placing the planes of rotation of the blades of the additional sets forward / backward relative to the plane of rotation of the blades of the base set, sets of additional blades are placed sequentially from one another and the first of the additional sets from the base blades on the same or at different distances. 6. The blade system according to claim 1, characterized in that the base blades and blades of one or all additional sets are made of either the same material or different materials.