RU2118701C1 - Wind-electric generating plant (design versions) - Google Patents

Abstract

FIELD: electric power generation by using wind energy. SUBSTANCE: tower 1 having outlet hole in bottom part accommodates air duct 3. Wicket-gate mechanism 4 is mounted at its inlet. Windwheel 5 is loosely mounted on shaft of mechanism 4 outside air duct 3, its diameter being greater than that of the latter. Shaft of generator 2 mounts windwheel for aerodynamic interaction with windwheel 5. Two design versions are described. In second version, windwheel 5 of a diameter greater than that of air duct 3 is loosely mounted outside on shaft of mechanism 4. Installed on shaft of mechanism 4 at inlet of other side of air duct 3 is vent windwheel 10 ; second wicket-gate mechanism 11 is provided upstream of it. Drive windwheel is installed on same shaft as loosely mounted windwheel 5. EFFECT: improved specific energy of stream due to installation of several windwheels for their aerodynamic interaction and improved efficiency of plant. 6 cl, 9 dwg

Description

 The invention relates to the field of wind energy, namely to power plants.

 Known wind power plants (wind turbines) (see, for example, RF patent N 2018028, class F 03 D 1/00, ed. St. USSR N 1682621, 1560781, 1471709, 1242636, class F 03 D 1/00, patent Germany N 2932293, class F 03 D 1/02), containing a tower (mast), one or more self-mounted wind wheels, a generator installed directly on the wind wheel on the same axis with it and transmitting connection when using a generator installed at the base of the tower.

 The disadvantage of the wind turbines considered is the relatively low efficiency.

 Known wind power installation (see German patent N 3604448, class F 03 D 1/02 - prototype), containing a bearing support (tower) mounted movably on the base, the duct, the upper and lower ends of which are bent in opposite directions in horizontal direction; a turbine installed in the middle of the duct cavity on the generator shaft, including one or more wind wheels and guide vanes. The generator is installed inside the base.

 The disadvantage of the considered wind power installation is also a relatively low efficiency due to large energy losses at the inlet and outlet of the duct and, accordingly, a small pressure drop, as well as due to significant dynamic loads on the generator.

 The objective of the proposed technical solutions is to increase the efficiency of the wind power installation by increasing the specific energy of the flow and significantly reducing the dynamic loads on the generator.

 Option 1. The task is achieved in that in a wind power installation containing a hollow tower with an outlet in the lower part and a generator mounted on the base, an air duct, the lower part located in the cavity of the tower, two wind wheels, one of which is installed on the generator shaft with the possibility of aerodynamic interaction with another wind wheel, the guide apparatus, it is proposed that another wind wheel be made with a diameter greater than the diameter of the duct and installed freely, outside it, on the shaft of the guide arata, fixed at the inlet of the duct.

 Option 2. The task is also achieved by the fact that in a wind power installation containing a hollow tower with an outlet in the lower part and a generator installed on the base, an air duct, the lower part located in the cavity of the tower, three wind wheels, one of which is installed on the generator shaft and a guide apparatus, it is proposed that the air duct be T-shaped, and at one end of its upper part, on the outside, on an axis fixed in the support, a drive wind wheel with a diameter greater than the diameter of the air be installed An ode, at the other end of the upper part of the duct, in its cavity, on the same axis, fix a guide apparatus and a fan wind wheel with the possibility of its aerodynamic interaction with the wind wheel mounted on the generator shaft.

 Option 3. The task is also achieved by the fact that in a wind power installation containing a hollow tower with an outlet in the lower part and a generator installed on the base, an air duct, the lower part located in the cavity of the tower, three wind wheels, one of which is installed on the generator shaft with the possibility of aerodynamic interaction with other windwheels and two guide vanes, it is proposed that the air duct be T-shaped, with the upper part being provided with an additional internal air duct conical shape and at one end to fix together with the first guide vane at one of its entrance. On the axis of the first guide vane, from the outside, freely, with a diameter greater than the diameter of the duct, install a second wind wheel. On the same axis with the second guide vane, mounted in the cavity of the other end of the additional internal duct, freely, inside the cavity from the side of the other inlet of the duct, install a third wind wheel.

 In addition, in a wind turbine, a hollow tower can be mounted on the base movably, and the duct can be fixed in the cavity of the tower (option 1) or installed in it with the possibility of rotation (in any version), the wind turbines can be equipped with an additional curved outlet duct installed concentrically , for example, relative to the surface of the cavity of the tower and duct.

 In FIG. 1 and 3 presents a General view of a wind turbine (option 1); in FIG. 2 is a section AA of FIG. one; in FIG. 4 is a section AA of FIG. 3; in FIG. 5 is a cross-section BB in FIG. 3; in FIG. 6 - general view of a wind turbine (option 2); in FIG. 7 is a section AA in FIG. 6; in FIG. 8 is an embodiment of the arrangement of a free and driving wind turbine of a wind turbine in FIG. 6; in FIG. 9 - a general view of a wind turbine (option 3).

 The wind turbine (option 1, Fig. 1-5) contains a hollow tower 1 with an outlet in the lower part and a generator 2 mounted on the base. An air duct 2 is placed in the cavity of the tower 1. A guide apparatus 4 is fixed at its entrance (section of Figs. 2, 4). On the shaft of the apparatus 4, outside the duct 3, a wind wheel 5 is freely fixed, the diameter of which is larger than the diameter of the duct 3. A wind wheel 6 is mounted on the shaft of the generator 2 with the possibility of aerodynamic interaction with the wind wheel 5. The following structural differences in this embodiment may be provided. The hollow tower 1 can be mounted movably in the supports 7 on the base, the duct 3 can be installed in the cavity of the tower 1 with the possibility of rotation in the supports 8. The hollow tower 1 can have one outlet or several made along its perimeter. The wind wheel 6 can be placed directly in the outlet of the duct 3 (Fig. 3) or inside the duct 3, at the end of its rectilinear part (Fig. 1).

 Wind power installation (option 2, Fig. 6-7) contains a hollow tower 1 with an outlet in the lower part and a generator 2 mounted on the base. The air duct 3 is made in a T-shape, the lower part is placed in the cavity of the tower 1 and fixed with the possibility of rotation. A support 4 is fixed on one side of the upper part of the air duct 3. On its axis from the outside, a second wind wheel 5 is freely fixed with a diameter greater than the diameter of the upper part of the air duct 3. A first wind wheel 6 is mounted on the shaft of the generator 2.

 The wind turbine is equipped with an additional curved outlet duct 9 installed concentrically, for example, relative to the surface of the cavity of the tower 1 and duct 3. The exit of the hollow tower 1 can be made in the form of one hole or several made around its perimeter (see Fig. 5). On the axis of the support 4 and the wind wheel 5 in the inlet cavity of the other side of the upper part of the duct 3, a fan wind wheel 10 is installed, and a second guide apparatus 11 is fixed in front of it (section of FIG. 7). On the same axis with a free wind wheel 5 (either in front of it or after it), a driving wind wheel 12 is installed (see Fig. 6, 7).

 Wind power installation (option 3, Fig. 9) contains a hollow tower 1 with outlet holes in the lower part and a generator 2 mounted on the base. The air duct 3 is made in a T-shape and the lower part is placed in the cavity of the tower 1 with the possibility of rotation. In the cavity of one end of the upper part of the duct 3, a first guide vane 4 is fixed. On the axis of the guide vane 4, a free wind wheel 5 is installed outside, with a diameter larger than the diameter of the upper part of the air duct 3. A wind wheel 6 is installed on the shaft of the generator 2. Inside the cavity of the other entrance of the upper part of the air duct 3, a fan wheel 10 and a second guide apparatus 11 are mounted, mounted in an additional air duct 13 located in the upper part of the air duct 3 and having a conical shape. Moreover, the large diameter of the additional duct 13 is fixed together with the first guide apparatus 4 at the entrance to the duct 3.

 Wind power installation (option 1, Fig. 1-5) works as follows.

 Under wind pressure, for example, using an aerodynamic plane, the air duct 3 is deployed parallel to the flow if it is rotatably mounted in the tower 1 (Fig. 3) or it is deployed together with the tower 1 (Fig. 1) if it is rotatably mounted. The wind flow spins the wind wheel 5, which, for example, ventilates (sucks) the air flow through the guide unit 4. Forced ventilation creates a superior pressure drop compared to the dynamic pressure of the wind on the wind wheel 6, which also flows from below from the air flow entering the lower end of the duct directly or through openings in the tower 1 (Fig. 5), communicating its cavity and the limb of the duct 3 with the external environment. The wind wheel 6 spins the drive shaft of the generator 2, which converts the rotation into electricity for the consumer.

 Wind power installation (option 2, Fig. 6 - 8) works as follows.

 The wind flow turns the air duct 3, mounted in the tower 1 with the possibility of rotation, parallel to the wind flow. U-turn can occur both with the help of the aerodynamic plane, and due to the asymmetry of the upper part of the T-shaped duct 3. The air flow spins the free-wheel wind wheel 5, which creates a pressure back-up in front of the drive wind wheel 12 by uncoiling it. The wind wheel 12 drives the fan wheel 10 mounted on one axis with it, which is also affected by the incoming air flow, which, through the guide apparatus 11, acts on the wind wheel 6. Thus, a stream having high pressure enters the lower part of the duct. The resulting air flow rotates the wind wheel 6 with an increased frequency and power (with relatively small sizes) and drives the generator 2. The rearrangement of the wind wheels 5 and 12 (Fig. 8) creates excessive vacuum, which also leads to improved aerodynamic interaction with other wind wheels of the installation .

 Wind power installation (option 3, Fig. 9) works as follows.

 The wind flow turns the air duct 3, mounted in the tower 1 with the possibility of rotation, parallel to the wind flow. The wind flow spins freely installed wind wheels 5 and 10. The wind wheel 5 with its inlet part (for example) ventilates (sucks) the air flow from the cavity of the additional duct 13. Forced ventilation of the wind wheel 5 creates a negative pressure behind the shuttle part 10. Due to this vacuum and the dynamic pressure of the wind, the wind wheel 10 untwists. At the same time, its peripheral part vents the air flow with excess pressure into a structurally formed diametrical gap (between the surface of the upper part of the air duct 3 and the surface of the additional air duct 13), which forms a unit part with the air duct 3. The high-energy flow generated in the air duct 3 of the tower 1 thus unwinds the wind wheel 6 on the drive shaft of the generator 2, and then comes out from the lower end of the duct and the openings in the tower 1.

 Wind power plants of the proposed design can be represented in a series in terms of power and size depending on energy requirements and climatic operating conditions, i.e. they are not iced up and work even from light winds, due to the design of the installation as a whole and the incorporation of wind wheels in the air intake, in particular.

Claims (6)

 1. Wind power installation comprising a hollow tower with an outlet in the lower part and a generator mounted on the base, an air duct located in the cavity of the tower, two wind wheels, one of which is mounted on the generator shaft with the possibility of aerodynamic interaction with another wind wheel, a guiding device, characterized the fact that another wind wheel with a diameter larger than the diameter of the duct is installed freely outside it, on the shaft of the guide apparatus fixed to the inlet of the duct.  2. A wind power installation comprising a hollow tower with an outlet in the lower part and a generator installed on the base, an air duct placed in the cavity of the tower with the lower part, three wind wheels, one of which is mounted on the generator shaft, and a guiding device, characterized in that the air duct T-shaped, with a drive wind wheel and a free wind wheel, the diameter of which is larger than the diameter of the duct, is installed on the other end of the air duct at one end of its upper part, outside the axis fixed in the support It duct part, in its cavity on the same axis fixed guide vanes and the fan wind wheel with the possibility its aerodynamic interaction with the wind wheel mounted on the generator shaft.  3. Wind power installation comprising a hollow tower with an outlet in the lower part and a generator mounted on the base, an air duct placed in the cavity of the tower with the lower part, three wind wheels, one of which is mounted on the generator shaft, and two guide vanes, characterized in that the duct is made in a T-shape, while its upper part is equipped with an additional internal conical duct, one end fixed together with the first guide apparatus at one of its inlets, on the axis of the first a second wind wheel is installed outside, freely, with a diameter greater than the diameter of the duct, on the axis with a second guide apparatus fixed in the cavity of the other end of the additional internal duct, a third wind wheel is installed inside the cavity from the side of the other duct inlet with the possibility of aerodynamic interaction with the wind wheel mounted on the generator shaft.  4. Installation according to claim 1, characterized in that the hollow tower is mounted on the base movably, and the duct is fixed in the cavity of the tower.  5. Installation according to claims 1 to 3, characterized in that the duct is installed in the cavity of the tower with the possibility of rotation.  6. Installation according to claims 2 to 3, characterized in that it is equipped with an additional curved outlet duct installed concentrically, for example, relative to the surface of the cavity of the tower and duct.

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