RU2006665C1 - Rotor-type windmill - Google Patents

Abstract

FIELD: wind-electric power engineering. SUBSTANCE: windmill has vertical hollow shaft that mounts horizontal turning shafts with blades, wind-vane mechanism, vertical posts, frame built up radial cross-arms joined together by bows and secured to vertical posts, U-section links mounted on posts, carrier with pin, bearing, and holes one of which is splined. Horizontal shafts are joined with posts on one side by means of threaded joint and on other, y splined joint; they are also couple with carrier which is connected through pin and bearing to link. Wind-vane mechanism is mounted on posts. EFFECT: improved design.

Description

 The invention relates to wind turbines operating at any wind speed, including hurricane.

 The aim of the invention is to increase efficiency and reliability in operation at any wind speed, including hurricane.

 In FIG. 1 shows the proposed wind turbine, a vertical section; in FIG. 2 is a section AA in FIG. 1; in FIG. 3a - a horizontal shaft with blades and other details; in FIG. 3c - drove; in FIG. 4 - backstage; in FIG. 5 is a section BB in FIG. 1.

The rotary wind turbine contains a hollow vertical rotating shaft 1 with a diameter d ending in a spike 2, with a total height of H + H ₁ with mutually perpendicular step holes 3 made on two levels with a height h (Figs. 1 and 3) and interacting with mutually perpendicular horizontal shafts 4. One end of the latter ends with a spike 5 and a thread, and the other end with the same spike 5, then with splines and thread. On the opposite side of the holes 3, windows 6 are made (Figs. 1 and 3), which are closed through shims by covers 7 fixed by bolts (center lines). On the covers 7, holes are made that interact with the shafts 4. To prevent axial movement of the shaft 4, a sleeve 8 is mounted on it, fixed to the shaft 4 by a bolt (center line). The ends of the sleeve 8 interact with the inner wall of the shaft 1 and the inner wall of the cover 7. If the diameter of the shaft 1 allows a person to pass, then the window 6 on the shaft 1 is not satisfied, since the sleeve 8 is mounted on the shaft 4 by a person inside the shaft 1. The shafts 4 are executed with two mutually perpendicular slots 9, in which the blades 10 are mounted, fastened with bolts (axial lines). The spikes 5 of the shafts 4 are inserted into the holes made on the uprights 11 and their left ends are fastened with nuts using the washers (Figs. 1-3). On the splines (the right ends of the shafts 4), the carrier 12 is mounted through the washers (Figs. 1-3) and are fastened with nuts through the washers. A finger 13 is mounted on the smooth hole of the carrier 12 and mounted through a washer with a nut (not shown), and a bearing 14 is mounted on the other end of the finger 13, interacting with the wings 15 of the U-shaped section, mounted on the wind racks 16. In order for the bearing 14, mounted on a finger 13, it was precisely moving along a curved track (Fig. 4), that is, along the wings 15, its section is necessarily made U-shaped. Vertical posts 11 are attached (center line) to the ends of the radial beams 17, the inner ends of which are mounted on a ring 18, welded (bolted) to the shaft 1. The upper ends of the vertical posts 11 are attached to the outer ends of the upper radial beams 19 (center line), and their inner ends are mounted on a ring 20 (center lines), worn on a spike 2 and bolted (center lines). In order to increase rigidity, the outer ends of the radial beams 17 are connected by arcs 21 forming a ring. The lower ends of the vertical wind racks 16 are attached (axial lines) to the ends of the radial beams 22, the inner ends of which are attached (axial lines) to the ring 23 (Fig. 1), interacting through rollers (not shown) with the shaft 1 and ring 18. Radial beams 22 are connected by the same arcs as arcs 21, forming a ring interacting via rollers with a continuous ring 24, mounted on the cover. The upper ends of the wind guide risers 16 are mounted on the ends of the radial beams 25, mounted on a ring 26, interacting through a bearing (not shown) with a spike 2 and through rollers with a ring 20. The radial beams 19 and 25 are connected by arcs as arcs 21 (Fig. 5).

 The guide tail 27 (Fig. 2) is mounted on the wind-guide rack 16 and for the horizontal direction of the wind on the radial beams 25 the roof 28 is attached.

If the height of the wind turbine (H + H ₁ ) is more than 50 m, a crosspiece 29 is installed, interacting through the rollers with a ring 26, and a cap 30 is attached to it. The crosspiece is stretched by cables 31.

To increase the power turbine 16 to the wind guide studs mounted vertical shield 32 of length B and an angle β = ^{15 °} and a vertical shield 33 at an angle β = ⁴⁵ ° and the length C. The distance between the ends of boards 32 and 32 is e. The continuation of the shield 32 is an arc shield 34, mounted on a wind guide rack 16, occupying a sector with a coverage angle α = 90 ^about , an arc shield 35 with a coverage angle α ₁ = 50 ^about . Between the vertical shields 32 and 33, a diffuser 36 is formed (e = 2R).

 To transmit torque to the shaft 1, a pulley 37, a gear 38 are attached to which energy consumers are connected: an electric generator 39, a compressor 40 installed in a room containing a foundation 41 with walls and a closing ceiling 42, where a ring 24 is installed. A hole in the ceiling 42 is installed bearing 43, and on the foundation - bearing 44, interacting with the shaft 1.

 To rotate the cylindrical wind-guiding frame, consisting of vertical struts 16, on which arc shields 34 and 35 and vertical shields 32 and 33 are mounted, directed against (along) the wind, tail 27 is used. To eliminate the massive metal-consuming tail 27, a weather vane is made that accurately determines the direction the wind. Automatically acts as a tail 27 electric motor 45, made with a worm 46, interacting with a worm wheel 47, mounted on the lower ribs of the radial beams 22.

 The upper ends of the vertical wind racks 16 are fixed on the radial beams 25, the inner ends of which are fixed on the ring 26, interacting through the rollers with the ring 20. The lower ends of the wind racks 16 are fixed on the outer ends of the radial beams 22, and the inner ends are fixed on the ring 23, interacting with the shaft 1 and through the rollers with the ring 18. The ring formed by arcs fixed to the radial beams 22 interacts through the rollers with the ring 24 mounted on the ceiling 42, which prevents the shaft 1 from swinging in the vertical ikalnom direction. Thanks to the tail 27, the wind turbine is always in working condition, i.e., the diffuser 36 is always directed against the wind.

 If a weather vane is installed, connected by an automatic machine, then the direction of the diffuser 36 against the wind is carried out by an electric motor 45 made with a worm 45 interacting with the worm wheel 47 fixed to the radial beams 22.

= = 320 т. При скорости (8˙ 2 = 16 м/с) энергия ветра составит Е =

= 1280 т. По мере вращения правой лопасти 10 масса ветра оказывается между двумя лопастями и дуговым щитом 34, создающим крутящий момент на валу 1, до тех пор, пока лопасть 10 не пройдет нижнего торца дугового щита 32. Kогда лопаcть 10 пройдет ветровую тень, создаваемую валом 1 (линия Оe, образующая угол α₃), вал 4, на торце которого закреплено шлицами водило 12, а на другом конце крепится палец 13 с подшипником 14, взаимодействующим с кулисой 15, проходя по ее наклонной части, начнет поворачивать лопасть 10 (пунктиры в наклонной части кулисы, фиг. 4) в горизонтальное положение (левая часть от вала 1), до тех пор пока она не станет в горизонтальное положение (параллельно к листу) к движению ветра. Благодаря взаимодействию торцов втулки 8 с внутренней поверхностью вала 1 и крышки 7, закрывающей окно 6, вал 4, взаимодействующий с отверстием 3, не может перемещаться осевом направлении.The wind flow (arrows), moving below the roof 28, entering the diffuser 36 with a width e (e = 2R), falls on the right blade 10, mounted on the slots 9 of the shaft 4, the spikes 5 of which interact with the holes made on the posts 11, fixed on the radial beams 17, fixed by arcs 21 on the ring 18, mounted on the shaft 1, rotating clockwise ω. The wind, striking the shield 33, located at an angle β ₁ , ricochets against the blade 10, which is parallel to the wind, rotates the shaft 1 clockwise, part of the wind moves between the arc shield 35 and the upper blade 10. Due to the fact that the shield 32 - at a smaller angle β (β <β ₁ ), the wind, striking with a slight rebound, increases the speed (Bernoulli law) and moves to the right blade 10, the length of the blade 10 is R = e: 2. Therefore, the wind speed v will increase 2 times . At a wind speed of v = 8 m / s, with a mass passing in 1 s 10 t, the wind energy will be E =

= = 320 t. At a speed (8˙ 2 = 16 m / s), wind energy will be E =

= 1280 t. As the right blade 10 rotates, the mass of wind is between the two blades and the arc shield 34, which creates a torque on the shaft 1, until the blade 10 passes the lower end of the arc shield 32. When the blade 10 passes the wind shadow, created by the shaft 1 (line Oe, forming an angle α ₃ ), the shaft 4, on the end of which is secured with slots carrier 12, and on the other end is attached a finger 13 with a bearing 14 interacting with the link 15, passing along its inclined part, will begin to turn the blade 10 (dashed lines in the inclined part of the wings, Fig. 4) to the horizontal position (left side of shaft 1), until it becomes in a horizontal position (parallel to the sheet) to the movement of the wind. Due to the interaction of the ends of the sleeve 8 with the inner surface of the shaft 1 and the cover 7, covering the window 6, the shaft 4, interacting with the hole 3, cannot move axially.

On the left side (Fig. 1 and 2) from the shaft 1, the blade 10 moves parallel to the movement of the wind until the shaft 4 reaches (about 10 ^about ) the line of the OS, the blade 10 takes a vertical position to the sheet and the wind from the shield 33 the blade starts to ricochet in a clockwise direction. The cycle repeats. Thus, the working stroke of the blade 10 lasts about α ₂ = 220 ^about (Fig. 2).

In order to prevent the shaft 1 from rolling over, when H ₁ + H = 50 m or more, the wind turbine is made with a cross 29 closed by a flange 30, tensioned by cables 31, interacting through a bearing with a spike 2 and through rollers with a ring 26.

 From shaft 1, the torque is transmitted to the pulley 37, gear 38, electric generator 39, compressor 40 and other energy consumers installed in the room containing the foundation 41, walls, ceiling 42, in the hole of which the bearing 43 and the bearing 44 installed in the foundation 41 are installed. Bearings interact with shaft 1.

 It is convenient, safe to remove power through a pulley and gear and connect any consumer. Power can be removed from known vane windmills.

The efficiency of using wind energy of known rotary and drum wind turbines made with screens is about 10%. The blades of the wind turbine of the Savonius system, made of convex and concave surfaces, are perpendicular to the movement of the wind, so the wind glides along the convex surface and acts on the curved surface. The working stroke is 180 ^{about the} rotation of the shaft. But despite this, the efficiency is 0.23.

The efficiency of using wind energy by modern high-speed impellers (screw) wind turbines is about 40% (0.4), and they start moving at a wind speed of 4-6 m / s. In the proposed wind turbine, one half of the blade (from the axis of the shaft 1) is perpendicular to the direction of the wind, and the other half of the blade is horizontal. Thanks to the diffuser, the wind speed increases by 2 times, and the working stroke is 220 ^{about the} rotation of the shaft, which can dramatically increase the efficiency of using wind, it will be more than 0.9. To calculate the efficiency we take η _isp.v. = 0.5.

 The rated power of all types of wind turbines is calculated at a wind speed of about 8 m / s.

The wind turbulence coefficient is 0.95, the mechanical efficiency (shaft 1 rotates on rolling bearings) η _m = 0.92-0.98. Total efficiency η _total = 0.95 (0.92 + 0.98): 2 = 0.9. Wind speed 8 m / s, height H = 100 m, shaft diameter 1 d = 4 m taking into account diameter d radius R = 10 m.

At a wind speed of v = 8 m / s per square meter the meter of the blade wind pressure P will be 110 kgf / m ² . With the indicated parameters, the shaft 1 rotational speed without load will be n = 60 _s / πA (rpm), n = (8 · 60) / (3.14 · 20) = 8 rpm. / min

Given the increase in wind speed in the region of the blade 10 by 2 times, the rotation frequency of the shaft 1 will be 16 vol. / min, but under load, the shaft 1 rotates n = 8 about. / min The total wind pressure for one half of the blade 10 will be P _total = 100x10x101 = 110000 kg. Pressure application force R: 2.

= 110000

= 550000 (кг·м) = 550000 (кг ˙ м). Мощность N =

·η_общ·η_исп.в.=

0,9·0,5 = 2031 кВТ, где 975 - переводной коэффициент на кВт.Define the torque M _cr = P _total

= 110000

= 550000 (kgm) = 550000 (kg ˙ m). Power N =

· Η · η _{total isp.v.} =

0.9 · 0.5 = 2031 kW, where 975 is the conversion factor per kW.

 At a wind speed of 16 m / s, the pressure P per square meter. the meter will be about 140 kg, the speed of rotation of the shaft 1 under load will be 16 vol. / min

M _cr = 140х100х10х5 = 700000 kgm, N = (700000 · 16) / 975 0.95 ˙ 0.5 = 5482 kW.

It should be recalled that wind energy is proportional to the cube of its speed. With a 2-fold increase in wind speed, energy increases (16/8) ³ = 8 times, therefore, power should also increase - 2031x8 = = 16248 kW. Counting with understated figures, we got 5482 kW.

On Novaya Zemlya Island, the wind speed (Novaya Zemlya Bora) reaches 50 m / s. At wind speeds, pressure P per square meter. the meter will be more than P = 400 kgf / m ² , M _cr = 400 × 100 × 10 × 5 = 2,000,000 kg, N = (2,000,000 · 85) / (975 · 0,9 · 0,5) = 78,000 kW.

On Novaya Zemlya, the average wind speed is 10 m / s, then n = 10 vol. / m, pressure P = 120 kgf / m ² . We get М _кр = 120х100х10х5 = 600000 kgm, N = (6000000 · 10) / 975х0.9х0.5 = 2700 kW. During the year (in 360 days) it will generate energy - E = 2700x24x360 = 23328000 kW.

 To generate 2 trillion kW of electricity (about 2 trillion kW is generated in the USSR), it is necessary to build 2,000,000,000,000: 23,328,000 = 86,000 pcs of wind farms. With the cost of one station 100 thousand rubles. with all the equipment, then for the construction of all will require 8.6 billion rubles. - this is the cost of two nuclear power plants.

 The proposed wind turbines produce hydrogen for the entire mode of transport, and oxygen for industry.

 Winds blow everywhere, even in the Krylatskoye area (Moscow, at the Krylatskoye weather station (on the banks of the rowing canal), the average wind speed for 1987 was 7.5 m / s, 1988 - 7 m / s, 1989 - 7.2 m / s.

 At the top of the Khadum Mountains, where the Chirkey Hydroelectric Power Station and the Dagestan Autonomous Soviet Socialist Republic function, the winds blow as well as on Novaya Zemlya.

The volume Q of the proposed wind turbine will be Q = π R ² H = 3.14x10 ² x100 = 30,000 m ³ - this is half the volume of only one railway dead end of a TPP with a capacity of 1.2 million kW, which contains nine large facilities, starting from the main building of a TPP ending in an underground fuel bunker, deeply violating the environment. (56) Fateev E.F. Wind turbines and wind turbines. M.: Selkhozgiz, 1957.

 Application of France N 2288878, cl. F 03 D 3/00, publ. 1976.

Claims (1)

 A CAROUSEL WIND MOTOR containing a vertical hollow shaft, mounted on it horizontal rotary shafts with blades, a wind-guiding device, characterized in that, in order to increase efficiency and reliability, it is equipped with vertical posts, a frame made in the form of interconnected radial beam cross members connected with vertical uprights, mounted on the uprights by wings with a U-shaped cross-section, a carrier with a finger, a bearing and holes, one of which is made spline, horizontal shafts are connected to one kami on the one hand by a threaded connection, and on the other - a splined connection and connected to the planet carrier coupled via a pin and bearing with the scenes as wind guide device is mounted on the racks.

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