UA144419U - ELECTRIC GENERATING INSTALLATION - Google Patents

Abstract

The power plant includes a wind turbine or hydroturbine rotating an asynchronous generator with a short-circuited rotor, and a transformer-key energy converter, which includes the first switch of the stator winding, two or more main power frequency converters, an auxiliary power converter. reactive power regulator, step-up transformers, the secondary windings of which are connected in series and connected to a high-voltage power line and a battery of filter capacitors, according to the utility model has an additional power selection channel of the adjacent installation, which contains the stator winding switch, through which the specified additional winding is connected to the generator of the adjacent installation.

Description

The useful model belongs to power engineering, in particular to machine-valve generating complexes, and can find application in distributed generation systems.

A well-known wind installation for the production of electrical energy (1|, which contains a wind turbine, a generator, a powerful main frequency converter (FD), a low-power auxiliary frequency converter that can work both on the internal network of the installation and on the centralized electric network, switches and transformers at the output of each of the converters.

The disadvantages of this scheme include: firstly, the parallel connection of the inverter to the terminals of the phases of the stator winding of the generator, which causes the mutual influence of the inverters and the occurrence of an emergency situation due to their non-synchronous operation, and, secondly, the high cost and complexity of the power converter with significant output power of the installation (from 2...2.5 MW) due to the need to make the generator and IF high-voltage to limit the cross-sectional area of the connecting wires and stator winding, which is a sign of low reliability and complexity of designing the installation.

As the closest analogue, an electric generating plant |Z) was chosen, which contains a wind turbine or a hydro turbine rotating an asynchronous generator with a short-circuited rotor, a commutator of the stator winding, two or more main power inverters for taking power to the network, an auxiliary inverter of lower power for powering the internal network of the installation, multi-winding power transformer, semiconductor reactive power regulator, step-up transformers, the secondary windings of which are connected in series, shunted by a battery of filter capacitors and connected to a high-voltage power transmission line. Together, the stator winding commutator, main power inverter, auxiliary inverter, multi-winding power transformer, semiconductor reactive power regulator (RPR), step-up transformers, and filter capacitor bank (BFC) form a transformer-key energy converter. The disadvantage of the closest analogue is the high total cost of electrical equipment of distributed generation systems designed on the basis of two or more of the specified installations due to the presence of an expensive transformer-key energy converter in each of them.

The basis of the useful model is the task of improving the power generating plant

Zo due to the fact that the additional elements of its transformer-key energy converter compensate for the absence of a similar converter in an adjacent installation, which makes it possible to install transformer-key energy converters in only one of the two installations. This makes it possible to obtain a new technical result: a reduction in the total cost of electrical equipment for distributed generation systems built from two or more power generating units based on a hydro turbine or wind turbine of variable rotation frequency and an asynchronous generator with a short-circuited rotor.

The task is solved by the fact that the power generating unit contains a wind turbine or hydro turbine rotating an asynchronous generator with a short-circuited rotor, and a transformer-key energy converter, which includes the first commutator of the stator winding, two or more main power frequency converters, an auxiliary frequency converter of lower power , a multi-winding power transformer, a semiconductor reactive power regulator, step-up transformers, the secondary windings of which are connected in series and connected to a high-voltage power transmission line and a battery of filter capacitors, according to the proposed utility model, what is new is that the installation has an additional channel for taking the power of the adjacent installation, which contains an additional primary high-voltage winding of a multi-winding power transformer and an additional commutator of the stator winding, through which the specified additional winding is connected to the generator of the adjacent installation.

The generator of the proposed installation is high-voltage, as a result of which it is connected to the transformer-key energy converter by wires or cables with a lower cross-sectional area and, accordingly, a lower cost than in the case of a low-voltage generator. The low cost of the connecting wires or cable, in turn, allows the specified converter to be placed remotely from the generator, which, in the case of using a utility model in wind turbines of the megawatt class (2-3 MW and more), makes it possible to reduce the mass of the equipment in the nacelle of the wind turbine, which simplifies design of the mechanical part of the wind turbine and its installation. But due to the fact that, unlike its closest analogue, the installation has an additional power take-off channel of an adjacent installation, which contains an additional primary high-voltage winding of a multi-winding power transformer and an additional stator winding commutator (KSO), through which this additional winding is connected to the generator 60 of an adjacent installation, an adjacent installation does not need its own transformer-key energy converter, and its generator can be connected to the terminals of an additional commutator of the stator winding with a high-voltage cable, which will reduce (due to the use of half the number of transformer-key energy converters than installations) the total cost of electrical equipment of the distributed system generation In addition, due to the fact that, in comparison with the nearest analogue, the installation takes electricity from its own generator and the generator of an adjacent installation and generates active power to the network, in the distributed generation system only one of the two installations will be connected to the centralized network, which simplifies the connection of the distributed generation system to the transformer substation by laying half the number of high-voltage cable lines.

According to the scientific and technical and patent literature, the authors do not know the declared set of features aimed at solving the given problem.

Thus, all the declared features of the technical solution of the power generating plant are essential and in their totality are necessary and sufficient to achieve a new technical result, which is provided by a useful model, namely, a reduction in the total cost of electrical equipment of distributed generation systems built from two or more power generating plants, which made on the basis of a hydro turbine or a variable frequency wind turbine and an asynchronous generator with a short-circuited rotor.

The essence of the useful model is explained by the drawings, which depict the functional scheme of the installation.

The installation consists of a drive turbine 1, an asynchronous generator (AG) containing a short-circuited rotor 2 and one winding in the slots of the stator 3, and a transformer-key energy converter 4 containing a multi-winding power transformer 5, on the core of which windings 6-11 are wound, the winding b is connected to the winding of the stator C through the first commutator of the stator winding 16, the second winding 7 of the transformer 5 is connected to the semiconductor regulator of reactive power 17, the third winding 8 is connected to the battery of capacitors for compensation of reactive power (BKKRP) 18 of the generator, the fourth winding 9 supplies through the frequency converter 19 the devices connected to the internal network of the installation, the windings 10 through individual frequency converters 20 are connected to the primary windings of the step-up transformers 14, the winding 11 of the transformer 5 through the second (additional) commutator of the stator winding 12 is connected to the generator of the adjacent

From the installation (adjacent installation not shown), the indicated winding 11 and the commutator 12 form the power take-off channel of the adjacent installation 13, the secondary windings of the transformers 14 are connected in series and connected to the battery of filter capacitors 15 and the high-voltage transmission line.

The installation works as follows.

If the distributed generation system, which includes the installation, has not been started, or after start-up the rotation frequency of the rotor 2 AG has not yet exceeded the minimum permissible, then the AG is not excited, the keys KSOI1 16 and KSO2 12 are open, RRP 17 is turned off, the internal network the installation is fed from the centralized network through step-up power transformers 14, frequency converters 20, multi-winding power transformer 5, frequency converter 19. If the current rotation frequency of the rotor 2 AH exceeds the level of the minimum permissible rotation frequency, the keys KСО1 16 and KСО2 12 are closed, the RRP 17 is turned on in work and excites the AG, the active power from the stator winding Z AG and from the generator of the adjacent installation is taken by the transformer-key energy converter 4 through KСО1 16 and KСО2 12 and is given through the multi-winding power transformer 5, IF 20, transformers 14 to the high-voltage transmission line. In addition, the active power coming from the AG and through the power take-off channel of the adjacent installation 13 is partially consumed by the internal network through KSO 16, KSO2 12, multi-winding power transformer 5, IF 19. IF 19 and 20 are frequency converters with an intermediate DC link current and are implemented on the basis of a bridge rectifier (AC/OS) and an inverter (OS/AC) connected in a direct current circuit, which allows independent regulation of the input and output currents of the IF and limiting the voltage on the IF keys to the level of the DC circuit.

The inverters in the IF 20 work synchronously and in such a way that a constant voltage is maintained at their DC inputs. The capacity of the BKKRP 18 capacitors is selected so that the RRP 17 at the nominal rotation frequency of the rotor 2 operates in a mode close to idling, i.e. does not consume or generate reactive power. The filtering of higher harmonics of the output voltage of the installation is carried out by BFC 15. If in the distributed generation system all installations have similar turbines and generators, which is characteristic of distributed generation systems, then with the same mechanical power on the turbine shafts, the current values of the currents of the phases of windings 6 and 11 of transformer 5 will be the same And therefore, the parameters of windings 6 and 11 in this case must also be set the same. In order to reduce the cross-sectional area of 60 connecting wires or cable lines connected to KSO1 16 and KSO12, the stator winding Z AG and windings b and 11 of transformer 5 must be high-voltage (line voltage 3000-4000 V). Windings 7, 8, 9, 10 of transformer 5 are low-voltage with a nominal line voltage of up to 690 V, which makes it possible to use existing industrial models of frequency converters.

Thus, in comparison with the closest analogue, the power-generating unit has an additional channel for taking the power of an adjacent installation, which contains an additional primary high-voltage winding of a multi-winding power transformer and an additional commutator of the stator winding, through which the specified additional winding is connected to the generator of an adjacent installation, due to which the installation has greater than the nearest analogue functional capabilities and will produce twice the amount of high-voltage electrical energy compared to the nearest analogue, which can be transported with low losses by a high-voltage transmission line to a transformer substation, and the adjacent installation will be lower in cost than the nearest analogue due to the absence of a transformer-key converter in it of energy (TCPE), which allows to apply the proposed useful model in distributed generation systems and, due to the absence of every second TKPE installation, to reduce the total cost of electrical equipment of these systems.

Sources of information: 1. Opied iagez Raiepi 8188610 B2, ROZO 9/00, 09/08/2008. 2. Utility model patent OA 105830, НО2М 5/00, РОЗО 9/00, 09/04/2015.

Claims (1)

UTILITY MODEL FORMULA An electrical generating plant comprising a wind turbine or hydro turbine rotating a short-circuited rotor asynchronous generator and a transformer-key energy converter comprising a first stator winding commutator, two or more main power frequency converters, a lower power auxiliary frequency converter, multi-winding power transformer, semiconductor reactive power regulator, step-up transformers, the secondary windings of which are connected in series and connected to a high-voltage power transmission line and a battery of filter capacitors, which is distinguished by the fact that it has an additional power take-off channel of an adjacent installation, which contains an additional primary high-voltage winding of a multi-winding power transformer and an additional commutator of the stator winding, through which the specified additional winding is connected to the generator of the adjacent installation. Her go More where and/ І Where of the adjacent installation pn pa ana y, V a za a AYU BEK TT, I chi spy U i : zav 4 | | Not t; NE I e I alone: iy nyk she p EE M SHY V NN I Por ev Kt rr p SCHI 33313 330 ш Id ele Sean zh I 14 what; and " i iE Ti Z ; ! 1. ion i pla z plak Shu y feth y i stump y ni bonih be boi pornn on Pn SHI viv: "sh yi I i asan ! 1 | al ! "SOS | Y z i Scale vaash as at MA rani M ryn V ven V pnya V Gro ii I ikuyaYe osyaye | ! Hor retro pai un zn z, i ' t cho se chi: E pit v i Da vnutryshchynyoi | i SHE. same; | I i zrenni I 5 ; ; i E i i Znnishmnnh TIM with not a hall TZ. lanya 11 ! writes sha Voshi and from 173 ! and and I Ko; TE Yaku and and I re shen ! He - ! with "fia GO I ) I Shen ro; Ve, volany glin ke Zk MYH UKH Sh S er Du mesta nyat, is peneyu pev peven nta ves dent taya pogvo zhetyu eeth ny: Do lamia viunniach Z Zk EK