RU159413U1 - WIND POWER PLANT - Google Patents

Abstract

A wind power installation containing a wind wheel connected by a shaft with a multiplier, an inertia battery, a control unit, a battery and a DC motor, characterized in that it further comprises an overrunning clutch, an asynchronous generator with a squirrel-cage rotor, a battery of starting capacitors, voltage transformers, a diode a bridge and a voltage converter, while the inertial battery is made with variable energy intensity and consists of a housing, input and output shafts, l for filling, a piston, a tightening handle, latches of a tightening handle, a protective corrugation and a filler, the multiplier being connected via an output shaft to an overrunning clutch, which is connected to an inertial battery with a variable energy capacity, connected to the rotor of an asynchronous generator with a squirrel-cage rotor, which is electrically connected with a battery of starting capacitors, and voltage transformers are electrically connected to the diode bridge, the rotor of an asynchronous generator with a squirrel-cage rotor on one side s through an inertial battery with variable energy intensity is connected to an overrunning clutch, and on the other hand, to a DC motor, which is electrically connected to the battery through a voltage converter, the output shaft of the multiplier, overrunning clutch, inertial battery with variable energy consumption, asynchronous generator with squirrel-cage the rotor and the DC motor are mounted on the same horizontal axis.

Description

The area to which the utility model belongs.

The utility model relates to the field of wind energy and electrical engineering, in particular to autonomous power supply systems with three-phase alternating current using wind energy.

The level of technology.

The well-known "Autonomous uninterrupted power supply system using a renewable energy source", containing a variable speed wind turbine rigidly connected to an alternator, an auxiliary electric consumer, made in the form of a battery, connected to an alternator by a power control device, a diesel engine, mechanically connected to synchronous generator, forming a diesel generator set, with the formation of two independent sources of electric power of the interconnected switching unit, the function of one of them is performed by a diesel generator set equipped with an automatic active power control system, the function of the other is a synchronous compensator with an acceleration device and an automatic speed control system, a rechargeable battery connected to a synchronous compensator by means of a two-set reverse thyristor DC-DC converter, which, when the power of the wind turbine exceeds the load power, is controlled in automatic stabilization system speed synchronous compensator, and in a mode where the wind turbine power is less than the load power, and the battery is low, in the active power stabilization system of the diesel generator set; the function of the alternator is performed by a multi-speed asynchronous machine controlled by a mode selection unit that sets its operating speed as an active power function, characterized in that a consumer unloading device is introduced into the system, the input of which is connected to the output of the switching unit, and the output to the input of the electricity consumer node (patent RU No. 113615 H02J 3/00 of 09/22/2011).

Its disadvantage is the complexity and high cost of the design, requiring a complex technical solution associated with the use of a reversible thyristor converter, a diesel generator set equipped with an automatic power control system, low reliability due to the use of a large number of elements, high cost due to the need to use a diesel generator fossil fuel plant.

Known "Wind power installation" containing a differential gear, a wind wheel, a wind speed sensor, a direct current machine, a voltage inverter, a battery, an excitation regulator, an excitation shutdown unit and an electric load (patent RU No. 2287718 F03D 9/02 of 20.11. 2006).

Its disadvantage is the complexity and high cost of the design, requiring a complex technical solution associated with the use of gear differential transmission, a direct current machine as a generator, an excitation regulator, an excitation shutdown unit, relative reliability due to the use of a direct current machine as a generator, low quality of the generated electric energy through the use of a voltage inverter.

The closest in technical essence and the achieved effect adopted by the authors for the prototype is a "wind power installation" containing a tower, a wind wheel, a multiplier, an inertial battery, a generator. The wind wheel shaft is connected via a multiplier and an inertial battery to the stator housing of a DC machine. The armature shaft of the DC machine is connected to the shaft of the synchronous generator. The DC machine and the synchronous generator are electrically connected to the electric energy accumulators through the control unit. The anchor winding of a DC machine has the ability to reverse the poles. A synchronous machine is used as a generator (patent RU No. 2313693 F03D 9/02 of 12/27/2007).

The disadvantage of this device is the low reliability and high cost of the design associated with the use of a synchronous generator, the vertical arrangement of the elements of the wind power installation, which complicates maintenance and repair.

Disclosure of a utility model.

The technical result of the proposed utility model is to reduce the cost of construction and increase reliability by using an asynchronous generator with a squirrel-cage rotor, introducing an inertial battery with a variable power consumption and a DC motor into the circuit to stabilize the output parameters of the asynchronous generator and the possibility of autonomous use of the entire wind power installation, simplifying maintenance and repair system elements due to their horizontal arrangement, increasing the coefficient Use coagulant wind flow at different wind speeds.

The technical result is achieved using a wind power installation containing a wind wheel, a wind wheel shaft, a multiplier, a multiplier shaft, an overrunning clutch, an input shaft of an inertial battery with a variable energy intensity, an output shaft of an inertial battery with a variable energy capacity, an asynchronous generator with a squirrel-cage rotor, a battery of starting capacitors, voltage transformers , electric energy consumer, diode bridge, control unit, battery, voltage converter, op bearings, a DC motor, while the multiplier is connected to the freewheel via a shaft, and the freewheel, in turn, is connected to an inertial battery with variable energy consumption by means of an input shaft on thrust bearings, which is connected via an output shaft to thrust bearings with a rotor of an asynchronous generator with a squirrel-cage rotor, and an armature of a DC motor. The output shaft of the multiplier, the shafts of the overrunning clutch, an inertial battery with variable energy consumption, the rotor of an asynchronous generator with a squirrel-cage rotor and a DC motor are installed on the same horizontal axis, the stator windings of an asynchronous generator with a squirrel-cage rotor with a battery of starting capacitors, a consumer of electrical energy and voltage transformers are electrically connected voltage transformers are electrically connected to a diode bridge, which is electrically connected to a block control that is electrically connected to the battery, which is connected to the voltage converter is electrically connected to the DC motor, which is electrically connected to the control unit.

A brief description of the drawings.

In FIG. 1 is a structural diagram of a wind power installation.

In FIG. 2 shows an inertial battery with variable energy consumption.

Implementation of a utility model.

The wind power installation includes: a wind wheel 1 connected via a shaft 2 with a multiplier 3, the output shaft 4 of which is connected to an overrunning clutch 5, which is connected to the input shaft 6 of an inertial battery 7 with variable energy consumption, which is connected to the rotor by means of the output shaft 8 (in FIG. 1 (not shown) of an asynchronous generator 9 with a squirrel-cage rotor, to the outputs of the stator windings (not shown in Fig. 1) of an asynchronous generator 9 with a squirrel-cage rotor, a battery of starting capacitors is electrically connected 10, voltage transformers 11, electric energy consumer 12, voltage transformers 11 are electrically connected to a diode bridge 13, which is electrically connected to the control unit 14, the control unit 14 is electrically connected to the battery 15 and the voltage converter 16, which is electrically connected to the field winding ( in Fig. 1 is not shown) and the anchor winding (in Fig. 1 not shown) of the DC motor 17, the anchor winding (in Fig. 1) and the field winding (not shown in FIG.) Of the DC motor 17 is electrically connected to the control unit 14, shafts 4, 6, and 8 are fixed in the thrust bearings 18.

In FIG. 2 schematically depicts an inertial battery with variable energy consumption, consisting of an input shaft 6, which has a thread, a filling hatch 19, a piston 20 connected by a threaded connection to the input shaft 6, the housing 21 connected to the output shaft 8, the tightening arm 22 connected to the input shaft 6, the latches 23 of the long arm 22, the filler 24 and the protective corrugation 25.

As a wind wheel 1, any converter of wind energy into mechanical energy, an asynchronous generator 9 with a squirrel-cage rotor with a through rotor of a standard design can be used. The control unit 14 must provide the charge of the battery 15 to control the voltage converter 16 and the DC motor 17. As a DC motor, a mixed-excitation DC motor can be used. The filler 24 for the inertial battery 7 with variable energy intensity may be sand, gravel or other other bulk material.

Wind power installation works as follows.

The torque from the wind wheel 1 through the shaft 2 enters the multiplier 3, in which, in accordance with the gear ratio, the angular speed of the wind wheel 1 is converted to the speed of the asynchronous generator 9 with a squirrel-cage rotor. The output shaft 4 of the multiplier 3 is connected by an overrunning clutch 5, which is connected to an inertial battery 7 with a variable energy consumption, the input shaft 6 of an inertial battery 7 with a variable energy consumption, which is connected through an output shaft 8 to a rotor (not shown in Fig. 1) of an asynchronous generator 9 s squirrel-cage rotor, while the energy is transmitted through an inertial battery 7 with a variable energy intensity, thereby acquiring an additional inertial moment and smoothing out the pulse changes in the moment on the rotor of the asynchronous squirrel cage generators of changing wind and electrical load. If the torque of the output shaft 4 of the multiplier 3 is not enough for the operation of the asynchronous generator 9 with a squirrel-cage rotor, then an inertial battery 7 with a variable energy capacity which supplies inertial energy gives it in the form of torque to an asynchronous generator 9 with a squirrel-cage rotor, and the DC motor 17 operates in motor mode, thereby adding the missing speed and moment for the operation of the asynchronous generator 9 with a squirrel-cage rotor, and the moment from the DC motor 17 n and the multiplier 3 is not transmitted due to the overrunning clutch 5. Thus, regardless of the power on the shaft 2 of the windwheel 1 and, accordingly, the output shaft 4 of the multiplier 3, the rotation speed and the output parameters of the asynchronous are stabilized by a DC motor 17 and an inertial battery 7 with a variable energy intensity generator 9 with a squirrel-cage rotor. A battery of starting capacitors 10 is used to excite an asynchronous generator 9 with a squirrel-cage rotor, voltage transformers 11 take information about the voltage level at the consumer 12 of electric energy and through the diode bridge 13 is transmitted to the control unit 14. According to the results of processing the received information about the voltage level at the consumer of electric energy 12, the control unit 14 generates control signals for the battery 15 and the voltage converter 16, thereby forming voltage levels for the winding excitation (in Fig. 1 is not shown) of the DC motor 17 and the anchor winding (in Fig. 1 is not shown) of the DC motor 17, the resulting torque allows you to stabilize the rotational speed of the rotor shaft (not shown in Fig. 1) of the asynchronous generator 9 with a squirrel-cage rotor and accordingly its output parameters both when the power on the shaft of the wind wheel 1 changes, and when the power of the consumer 12 of electric energy changes.

The inertial battery 7 with variable energy intensity works as follows: filler 24 is poured into the housing 21 of the inertial battery 7 with variable energy intensity through the hatch 19 for filling, then removing the latches 23 of the tightening handle 22 by rotating the input shaft 6 by the tightening handle 22, the piston 20 is screwed input shaft 6 and seals the filler 24, at the end of the filling, the tightening handle 22 is fixed by the latches of the tightening handle 23.

The novelty of the technical solution is due to the fact that an inertial battery with a variable energy intensity is used, and the torque from a wind wheel through a multiplier and an overrunning clutch is transmitted to an inertial battery with a variable energy intensity, and then to the rotor of an asynchronous generator with a short-circuited rotor and at the same time to the anchor of a DC motor. An inertial battery with variable energy intensity in a power plant smooths out pulsed changes in the moment on the rotor of an asynchronous generator with a squirrel-cage rotor when the wind and electric loads change, and also has an inertial moment, and the energy consumption of an inertial battery can be changed depending on the specified load parameters, thereby optimizing the operation of the units and units of a wind power installation. An inertial battery with variable energy intensity consists of a housing, input and output shafts, a filler hatch, a piston, a pull handle, clamps for a pull handle, a protective corrugation and a filler. A DC motor connected to an asynchronous generator with a squirrel-cage rotor performs the functions of an additional device that stabilizes the rotational speed of the rotor of an asynchronous generator with a squirrel-cage rotor, which leads to stabilization of its output parameters, and in the absence of torque on the wind wheel can create torque on the shaft of the asynchronous generator with squirrel-cage rotor due to the use of battery energy.

Based on the foregoing, a reduction in the cost of a wind power installation, stabilization of the output parameters of an asynchronous generator with a squirrel-cage rotor, increased reliability, simplified operation, maintenance and repair of system elements, increased utilization of the wind flow are achieved.

Claims (1)

A wind power installation containing a wind wheel connected by a shaft with a multiplier, an inertia battery, a control unit, a battery and a DC motor, characterized in that it further comprises an overrunning clutch, an asynchronous generator with a squirrel-cage rotor, a battery of starting capacitors, voltage transformers, a diode a bridge and a voltage converter, while the inertial battery is made with variable energy intensity and consists of a housing, input and output shafts, l for filling, a piston, a tightening handle, latches of a tightening handle, a protective corrugation and a filler, the multiplier being connected via an output shaft to an overrunning clutch, which is connected to an inertial battery with a variable energy capacity, connected to the rotor of an asynchronous generator with a squirrel-cage rotor, which is electrically connected with a battery of starting capacitors, and voltage transformers are electrically connected to the diode bridge, the rotor of an asynchronous generator with a squirrel-cage rotor on one side s through an inertial battery with variable energy intensity is connected to an overrunning clutch, and on the other hand, to a DC motor, which is electrically connected to the battery through a voltage converter, the output shaft of the multiplier, overrunning clutch, inertial battery with variable energy consumption, asynchronous generator with squirrel-cage the rotor and the DC motor are mounted on the same horizontal axis.

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