PL234358B1 - Electric generator excited by permanent magnets - Google Patents

Abstract

The generator (1) excited by magnets is three-phase and has a winding divided into two sections (1) and (2) or into three sections that are connected in series or parallel, and the connection is made by a block of W switches. When the winding is divided into two sections (1) and (2) the ends of the first section (1) of the winding are shorted, and the beginnings of the winding of section (1) are connected to the fixed contacts of the three-pole switch (4) and to the two-pole switch (5), and the ends are connected to the movable contacts of the three-pole switch (4). the second winding section (2) and the third fixed contacts of the switch (4) are closed, the second contacts of the bipolar switch (5) are connected to the beginnings of the winding section (2). When dividing the winding into three sections, the ends of the first section (1) of the winding are shorted, and the beginnings of the section winding (1) are connected to the fixed contacts of the first three-pole switch (4) and to the first two-pole switch (5), to the movable contacts of the three-pole switch (4). ) the ends of the second winding section (2) are connected and the third fixed contacts of the switch (4) are closed, the second contacts of the bipolar switch (5) are connected to the beginnings of the third winding section and the beginnings of the winding section (2) are also connected to the fixed contacts the second three-pole switch (6) and with the second two-pole switch (7), the ends of the section winding are connected to the moving contacts of the three-pole switch (6), and the third fixed contacts of the switch (6) are closed, the second contacts of the two-pole switch (7) are connected to the beginnings of the section winding. The three-pole (4) and two-pole (5) switches are interlocked, and the three-pole (6) and two-pole (7) switches are interlocked. It is advantageous when the microprocessor controller S measures the operating parameters of the generator P: voltage U, current I, frequency f and controls the switching on and off of the switches W.

Description

Description of the invention

The subject of the invention is a three-phase synchronous generator excited by permanent magnets dedicated to wind power plants and hydroelectric plants operating at variable rotational speed.

Permanent magnet generators have a constant excitation flux. The rotation voltage and frequency of the generators are a linear function of the rotational speed. In wind farms it is advantageous for the wind turbine to operate at a variable rotational speed depending on the wind speed. A wind turbine obtains maximum power from the wind stream only when its rotational speed is matched to the wind speed. At low wind speeds, e.g. 5 m / sec, the turbine speed should be low, and at high wind speeds, greater than 10 m / sec, the turbine speed should be correspondingly higher. Likewise, the water turbine speed should be adapted to the water pressure. In order to convert the mechanical power of a wind turbine or a water turbine into electricity, the generator should be adapted to work at a variable rotational speed of the turbine. At low rotational speed, the winding should have many turns for the generator voltage to be as high as possible, while the winding cross-section may be smaller because the power and current are not high. At high rotational speed, the number of winding turns may be correspondingly smaller and the winding cross-section correspondingly larger. Standard winding generators have a winding with the number of turns and cross-section adjusted to one rotational speed, most often corresponding to the wind speed of 12 m / sec.

From the patents: WO 2017/180850 A1, US 2016/0036308 A1 and US 2006/0220486 A1, generators are known in which each phase has several windings (sections). The winding sections are connected: in series, in parallel, and in series-parallel using electronic switches. Electronic systems are much more expensive than electromechanical switches, and they cannot be used in high-voltage windings. Therefore, there is a need to design generators that are as cheap as possible and adapted to work with wind and water turbines operating at variable rotational speed. The purpose of the solution is a generator that can efficiently generate energy at low and high rotational speeds.

According to the invention, a three-phase generator excited by permanent magnets with an armature winding divided into two sections, the sections being connected in series or in parallel. The sections are connected by W circuit-breakers. The ends of the winding of the first section are short-circuited, and the beginnings of the winding of this section are connected to the fixed contacts of the three-pole switch and to the bipolar switch, the ends of the winding of the second section are connected to the movable contacts of the three-pole switch, and the third fixed contacts of the three-pole switch are shorted , the second contacts of the bipolar switch are connected to the beginnings of the second winding section.

The three-pole and two-pole circuit breakers are interlocked with each other.

In a generator with an armature winding divided into three sections, the ends of the first winding section are short-circuited, and the beginnings of the winding of this section are connected to the fixed contacts of the first three-pole circuit breaker and to the first two-pole circuit breaker, the ends of the second winding section are connected to the moving contacts of the first three-pole circuit breaker, and the third the fixed contacts of this switch are closed, the second contacts of the first bipolar switch are connected to the beginnings of the third winding section, and the beginnings of the second winding section are connected to the fixed contacts of the second three-pole switch and to the second bipolar switch, the ends of the third are connected to the movable contacts of the second three-pole switch section of the winding, and the third fixed contacts of the second three-pole circuit breaker are closed, the second contacts of the two-pole circuit breaker are connected to the beginnings of the third winding section. The first three-pole and two-pole circuit breakers are interlocked with each other, and the second three-pole and two-pole circuit breakers are interlocked with each other.

The subject of the invention is illustrated in an example of a solution in the drawings, in which: Fig. 1 shows a block diagram of the system, Fig. 2 a diagram of the system when the generator winding is divided into two sections, Fig. 3, a diagram of the system when the generator winding is divided into three sections and diagram of a three-pole circuit breaker.

The generator P excited by permanent magnets is three-phase and has the armature winding divided into two sections 1 and 2, which sections can be connected in series or in parallel. The sections are connected by a block of circuit breakers W. The ends of the first section 1 of the winding are short-circuited, and the beginnings of the section 1 winding are connected to the fixed contacts of the three-pole circuit breaker 4 and to the bipolar switch

PL 234 358 B1

5, the ends of the second winding section 2 are connected to the movable contacts of the three-pole switch 4, and the third fixed contacts of the circuit breaker 4 are short-circuited, the second contacts of the bipolar switch 5 are connected to the beginnings of the winding of section 2. Connection diagram of sections 1 and section 2 of the winding with circuit breakers 4 and 5 is shown in fig. 2. The switches 4 and 5 must be interlocked with each other. When switch 4 connects sections in series, switch 5 must be open. When the switch 4 connects the winding sections in a star configuration, the switch 5 is closed and connects the winding sections in parallel.

In a generator with an armature winding divided into three sections 1, 2, 3, the ends of the first winding section 1 are short-circuited, and the beginnings of section 1 are connected to the fixed contacts of the first three-pole circuit breaker 4 and to the first two-pole circuit breaker 5, to the moving contacts of the three-pole circuit breaker 4 are connected the ends of the second winding section 2 and the third fixed contacts of the circuit breaker 4 are closed, the second contacts of the bipolar switch 5 are connected to the beginnings of the third winding section 3, and the beginnings of the winding section 2 are connected to the fixed contacts of the second three-pole switch 6 and to the second two-pole switch 7 , the ends of the winding section 3 are connected to the movable contacts of the three-pole switch 6 and the third fixed contacts of the switch 6 are short-circuited, the second contacts of the bipolar switch 7 are connected to the beginnings of the winding of section 3. Connection diagram of sections 1, 2 and 3 of the winding with switches 4 and 5 and 6 and 7 are shown in Fig. 3. Switches 4 and 5 and 6 and 7 must be interlocked with each other. When switches 4 and 6 connect the sections in series, switches 5 and 7 must be open. When the switches 4 and 6 connect the winding sections in a star configuration, the switches 5 and 7 are closed and connect the winding sections in parallel.

Preferably, the microprocessor controller S measures the operating parameters of the generator P: voltage U, current I, frequency f and controls the switching on and off of the circuit breakers W. The voltage U and the frequency / generator depend on the rotational speed, so the connection of the generator with the power grid is via an inverter 8.

The presented systems enable to obtain two variants of winding connection systems: series and parallel. The winding can be divided into more sections. The division of the winding into four sections makes it possible to obtain three variants of connection of sections: series, mixed and parallel. In series configuration, all sections are connected in series. In a mixed arrangement, the first and second sections and the third and fourth sections are connected in series and the double sections are connected in parallel. In a parallel arrangement, all sections are connected in parallel. Three-pole circuit breakers 4 and 6 can be realized by connecting two interlocked two-pole circuit breakers as shown in fig. 4. Movable contacts of circuit breakers 4 and 6 are marked a1, a2, a3, and fixed contacts b1, b2, b3 and c1, c2, c3.

The P generator with winding divided into sections is adapted to work at variable rotational speed. In order to obtain maximum wind power, a wind turbine should adjust its rotational speed to the wind speed. Likewise, the water turbine speed should be adapted to the water pressure. The combination of a wind turbine or a water turbine with a generator P allows for maximum energy efficiency of the power plant.

A generator P with a sectioned winding operating at a variable speed of a wind farm or hydroelectric power plant can transmit more energy to the power grid. At low rotational speeds, all winding sections are connected in series, the section voltages add up, the inverter 8 has a correspondingly higher input voltage. At higher wind speeds, the winding sections are connected in parallel, then the inverter current 8 is the sum of the currents in the winding sections.

Claims (4)

Patent claims 1. A generator excited by permanent magnets with an armature winding divided into two sections, where these sections are connected in series or in parallel, and the connection is made by a switch block W, characterized in that: the ends of the first section (1) of the winding are short-circuited, and the beginnings of the section winding (1) are connected to the fixed contacts of the three-pole switch (4) and to the two-pole switch (5), the ends of the second winding section (2) are connected to the movable contacts of the three-pole switch (4), and the third fixed contacts of the switch (4) are short-circuited, the other contacts of the bipolar switch (5) are connected to the beginnings of the winding section (2). PL 234 358 B1 2. A generator according to claim The method of claim 1, characterized in that the three-pole (4) and two-pole (5) switches are interlocked. 3. A generator excited by permanent magnets with an armature winding divided into three sections, where these sections are connected in series or in parallel, and the connection is made by a switch block W, characterized in that the ends of the first section (1) of the winding are short-circuited and the beginnings of the section winding ( 1) are connected to the fixed contacts of the first three-pole switch (4) and to the first two-pole switch (5), the ends of the second winding section (2) are connected to the movable contacts of the three-pole switch (4), and the third fixed contacts of the switch (4) are short-circuited, the second contacts of the two-pole switch (5) are connected to the beginnings of the third winding section (3), and the beginnings of the winding section (2) are connected to the fixed contacts of the second three-pole switch (6) and to the second two-pole switch (7), to the movable contacts of the switch of the three-pole switch (6), the ends of the section winding (3) are connected, and the third stationary contacts of the switch (6) are short-circuited, the other contacts of the two-pole switch are o (7) are connected by the beginnings of section winding (3). 4. A generator according to claim The device of claim 3, characterized in that the first three-pole (4) and two-pole (5) breakers are interlocked and the second three-pole (6) and two-pole (7) breakers are interlocked from each other. PL 234 358 Β1 Drawings Fig. 1 Fig. 2 PL 234 358 Β1 b1b2b3 dc2c3 ¹¹ 9 9? ? ^(l a1a2 a 3 Fig 4