RU64831U1 - DEVICE FOR STARTING HIGH POWER SYNCHRONOUS MOTORS - Google Patents

Abstract

The utility model relates to the field of electrical engineering and can be used as a device for starting high-power synchronous motors. The device comprises a network, first, second auxiliary and main switches, a reactor, a motor stator winding and a control unit for switches, comprising a power device and a control device, said switches being connected to the network, a capacitor bank connected to the first additional switch, and the reactor connected to the second additional to the circuit breaker, the motor stator winding is connected to the reactor and the main circuit breaker, the circuit breaker control unit is connected to the network, and the control unit control unit is connected EHO with the control device. The use of a capacitor bank, additional switches and a control unit for circuit breakers allows you to ensure the specified quality of the mains voltage when starting motors commensurate with the mains power.

Description

The utility model relates to the field of electrical engineering and can be used as a device for starting engines of electric drives of water supply systems.

A device for starting high-power engines is known, containing a network, an oil switch, a conventional switch, a reactor and a high-power synchronous motor, the stator winding of which is connected to the network during acceleration using an oil switch and a reactor, and during synchronization, using a conventional switch (see Electric Machines. Edited by G.N. Petrov. M., L., SEI, 1940, p. 537, Fig. 692 M). This device is simple and reliable, but it does not solve the formation of a starting winding circuit, which delays the start time.

The closest in technical essence to the claimed utility model is a device for starting high-power synchronous motors, containing a network, a three-pole switch, a motor stator winding, an excitation winding, used as a starting, starting rheostat, connected in series to the field winding and quenching reactor, closing the excitation winding of the motor during start-up using a two-pole switch (see Tokarev B.F. Electric machines. M., Energoatomizdat, 1990, p. 434, Fig. 37.9). This device uses a rational way to turn on the windings of synchronous

engine at start, however, there are no means to ensure a smooth increase in inrush currents, which leads to a failure of the mains voltage at the time of starting and delaying the start time.

The technical result of the utility model is to provide a given quality of voltage at the terminals of all consumers connected to the network when starting a synchronous motor, the power of which is comparable with the power of the network.

The required technical result is achieved in that a device for starting a high-power synchronous motor containing a main switch, a reactor and a motor stator winding, the motor stator winding being connected to the network through a main switch, the first and second additional switches, a capacitor bank and a switch control unit are introduced while the capacitor bank is connected to the network through the first additional switch, the stator winding of the motor is connected to the network through a series connection nye reactor and a second additional switch control unit provides the engine starts in step sequential switching at predetermined intervals the first switch, the second switch circuit breaker switch and the main switch after turning off the main switch of the first and second additional switches.

In figure 1. presents a structural diagram of a device for starting a synchronous motor of high power. In figure 2. shows a graph of changes in reactive power. Figure 3 shows a diagram of a control unit switches.

The device comprises (Fig. 1.) a network 1, a first additional switch 2, a second additional switch 3, a main switch 4, a capacitor bank 5, a reactor 6, a stator winding of the motor 7, a control unit for switches 8, containing a power device 9 and a control device 10 and the first additional 2, the second additional 3 and the main 4 switches connected to the network 1,

a capacitor bank 5 is connected to the first additional switch 2, the reactor 6 is connected to the second additional switch 3, the stator winding of the motor 7 is connected to the reactor 6 and the main switch 4, the control unit of the switches 8 is connected to the network 1, and the control device 10 of the block 8 is connected to the device power supply 9 of the same unit. The change curve (Fig. 2.) of reactive power when starting the engine consists of sections: in the interval 0 - t ₁ reactive power has a value of Q _D ; on the plot t ₁ -t ₂ to the network 1 is connected a capacitor bank 5, so the power has become greater than the nominal value Q _n ; on the plot t ₂ -t ₃ reactive power decreases almost to the limit value About _cr due to engine starting; plot t ₃ -t _{4 is} characterized by acceleration of the engine, in which the engine gains speed corresponding to the synchronous speed and reactive power, increasing reaches its initial value. The introduction of a capacitor bank 5 into the starting device provides a reactive power balance in the network 1, which provides a voltage level at the load. The control unit of the switches 8 contains a power device 9, constructed according to the usual scheme, the output buses (Fig. 3) of which (plus and minus) provide voltage to the control device 10, containing in parallel connected coils 2-1, 3-1 and 4-1 of the corresponding switches and the first 10-1 and second 10-3 timers. The first inputs (not shown) of the coils 2-1, 3-1, 4-1 and the time relay 10-1 and 10-3 are connected directly to the positive bus of the power device 9. The second input (not shown) of the coil 2-1 of the first auxiliary switch 2 is connected to the negative bus of the device 9 through a series-connected closed contact 4-2 of the coil 4-1 of the main switch 4 and the open contact of the start 11. The second input (not shown) of the first time relay 10-1 is connected to the negative bus via the open contact 2-2 of the coil 2-1 of the first additional switch 2; the second input (not shown) of the coil 3-1 of the second additional switch 3

connected to the negative bus of the power device 9 using an open contact 10-2 time relay 10-1; the second input (not shown) of the second time relay 10-3 is connected to the negative bus of the power device 9 through the open contact 3-2 of the coil 3-1 of the second additional switch 3; the second input (not shown) of the coil 4-1 of the main switch 4 is connected to the negative bus of the power device 9 through the open contact 10-4 of the second time relay 10-3. All elements of the device are serially produced by the domestic industry.

The device for starting works as follows. In static mode, if there is voltage in the network 1, but the open contact of the start-up 11 of the control device 10 of the control unit of the switches 8 switches 2 ... 4 are in the initial state, the capacitor bank 5 is de-energized, the reactor 6, the stator winding 7 are also de-energized and the motor does not rotate . When the start contact 11 is closed in the control device 10 of the control unit of the switches 8, the coil 2-1 (Fig. 3) of the first auxiliary switch 2 (Fig. 1) is turned on and the power circuits (not shown) of this switch are closed, providing the connection of the capacitor bank 5 to network 1, as well as its contacts 2-2 are closed, connecting the voltage to the time relay 10-1. After transients in the specified battery at time t ₂ (Fig.2.), The first time relay 10-1 is activated, since the contacts 2-2 of the coil 2-1 of the first additional switch 2 are closed. After the operation of the time relay 10-1, its open contacts 10-2 are closed and the coil 3-1 of the second auxiliary switch 3 is activated, while its power circuits (not shown) are closed and the network voltage 1 is supplied to the reactor 6, from which the stator winding is supplied 7 engine that starts to spin. In addition, contacts 3-2 are activated, connecting a time relay 10-3 to the supply voltage. After the transient starting processes in the reactor 6 and in the motor winding 7 take place and the engine rotor picks up speed close to the nominal, the second time relay 10-3 is activated, since

contact 3-2 of the coil 3-1 of the second auxiliary switch 3 is closed. After the operation of the second time relay 10-3, the contact 10-4 closes and the voltage is supplied to the coil 4-1 of the main switch 4, when activated, the power circuits (not shown) are closed and the mains voltage 1 is applied directly to the stator winding of the motor 7 and the shaft speed reaches synchronous value. When the coil 4-1 is activated, its contact 4-2 and the coils 2-1 and 3-1 open and the time relays 10-1 and 10-3 are de-energized, as a result of which the additional switches 2 and 3, the capacitor bank 5, and the reactor 6 are de-energized. Coil 4-1 rises to self-locking, the chains of which are not shown.

Thus, the introduction of additional switches, a capacitor bank and a switch control unit allows starting a high-power synchronous motor while maintaining the specified voltage quality at the terminals of all consumers connected to the network.

Literature

1. Electric cars. Ed. G.N. Petrova. M., L., SEI, 1940, p. 537, Fig. 692 M

2. Tokarev B.F. Electric cars. M., Energoatomizdat, 1990, p. 434, Fig. 37.9.

Claims (1)

A device for starting a high-power synchronous motor containing a main switch, a reactor and a motor stator winding, the motor stator winding being connected to the network through a main switch, characterized in that the first and second additional switches, a capacitor bank and a switch control unit, are introduced, the battery being capacitors are connected to the network through the first additional switch, the stator winding of the motor is connected to the network through a series-connected reactor and a second additional first switch control unit provides the engine start at step sequential switching at predetermined intervals the first switch, the second switch circuit breaker operation on the switch and after switching on the main switch off the first and second additional switches.