SU729746A1 - Device for flexible connection of power systems - Google Patents

Description

The invention relates to the transmission of electric energy over AC and AC, namely to electromechanical frequency converters for flexible communication of power systems with differing frequencies. Arrangements are known for the communication of electric power systems, made on the basis of two synchronized synchronous machines with rigidly connected shafts, the stator circuits of which are connected separately to power systems. To supply the rotor circuits of asynchronous synchronous machines, a known device uses a collector-mounted or static frequency converter located on a common shaft with a corresponding search for regulator 1. However, the presence of power consumers to supply rotor circuits reduces the transmission capacity and efficiency of the communication device. The closest to the technical essence of the invention is a device for combining power systems, which contains two asynchronized synchronous masks with rigidly connected shafts, the stator circuits of which are connected to the corresponding power system, and static control converters and control unit regulation 2J. With such a communication device, depending on the ratio of frequency {to i in the integrated power systems, the static winding frequency converter winds the rotors of asynchronized synchronous machines only consumed or only increases the active power P, - where S is the slip of the rotor of the asynchronized machine relative to the frequency of the power system, to which the stator circuits of the considered asynchronized machine are connected (during its operation with sliding). The throughput of a known device depends on the active power P, supplied or consumed by the windings of the rotors of asynchronized machines of an electromechanical converter, depending on the frequency fluctuations of the connected power systems. When the frequency of the receiving power system decreases, the power returns to the transmitting power bus (CHCiervibi) and vice versa (when the frequency of the transmitting power system decreases, the power P returns to the receive power system buses). Thus, the throughput of the entire device is reduced by the value of Pj, i.e. through the electromechanical conversion frequency, it is possible to transfer not all the nominal power, but only a part of the power (Р-Р {). At the same time, when reducing the frequency in the receiving power system, due to the nominal active power deficit in this power system, it is extremely necessary to ensure the greatest possible throughput of the device - the more necessary it is, the greater the decrease in frequency, i.e. the larger the P value. To increase the capacity and efficiency of the device for flexible communication of power systems with mutual slip, the obedine – emith subsystems are in a known device containing two asynchronized synchronous machines with rigidly connected shafts, the stator tsegs of which are connected each to the corresponding power system and static frequency converters in the rotor circuits of each machine, to the input of which signals are received from the common for the rotor circuits of asynchronized regulator machines with a forming unit func adjusting tion, introduced Switch ents, closing contacts which are connected to a power system, and opens the contact - to the other grid. In order to carry out p: switches, the switch is equipped with a control unit containing power direction signal sensors connected to the stator and rotor circuits of asynchronized machines, and a comparison element of these signals. The drawing is a diagram of the proposed device. A device for flexible communication of power systems and 2 consists of two asynchronized synchronous machines 3 and 4 with rigidly connected shafts. The rotor circuits of asynchronized machines 3 and 4 through static frequency converters 5 and 6 and switch 7 are connected to the stator circuits of asynchronized machines, i.e. with power systems 1 and 2. The input of static frequency converters 5 and 6 receives a signal from controller 8 with a block of the form-controlling function. The control elements of the switch 7 are connected to the control device of the switch, which is a comparison element 9, to the input of which sensors 10, 11, 12 are connected to the power direction signals in the rotor and stator circuits of asynchronisers 1 and 3 and 4. There are two switch positions 7, in which the power of the asynchronized rotary Mauitm 3 and 4 is powered from the network of the transmitting 1 or receiving 2 power system. When transmitting power P through an electromechanical frequency converter from the power system 1 to 2, the asynchronized machine 3 will operate in the motor, and the asynchronized memory 4 in the generator modes. If the frequencies I n i in these power systems are in the ratio f.tn, the motor P Pf + p should be removed from the rotors of both machines. . in this case, the switch 7 is transferred to a position in which the power of the PJ will be transferred to the power system 2. As a result, the -P-P | power will be transmitted through the stator working as a generator of the asynchronization of the machine 4, and the static-conversion will be transmitted through the static. Frequency telephones 5 and 6 are additional power P. (in the drawing, the direction of the active power flows for this case is shown by solid arrows); thus, the full power P will be transmitted to the power system. At a ratio of frequencies J - {2 and maintaining the direction of power flow P, both asynmonized power machines Pf and P, are introduced into the rotor circuit. In this case, the action of the switch 7 connects the power supply system of both asynchronized machines 3 and 4 to the power system, thereby allowing the transfer to the power system 2 through the strap P of the chronical circuit 4 (in the drawing 1, the power flows in this case are shown by dotted arrows). Switch 7 is controlled in accordance with a simple algorithm using a switch control device, which is an element of comparison 9, to which power signals () are sent to the stator circuits of asynchronized machines 3 and 4 from sensors 11 and 12 and to rotary circuits x asynchronized machines 3 and 4 from sensor 10. If we take the positive power of the direct powers to direct them — ie, to the stator and rotor windings of asynchronized machines 3 and 4, then if the condition is fulfilled: sign P it works ment Comparative 9 and acts on the switch 7 which connects the circuit both rotors 4 asinhronizirovashtyh machines third busbar power system 1. Under the conditions: 9) gn 5

Claims (1)

Claim A device for flexible connection of power systems, containing two asynchronous synchronous machines with rigidly connected shafts, the stator circuits of which are each connected to the corresponding power system, and static frequency converters and a regulator with a block for the formation of regulation functions are connected to the rotor chains of the machine, characterized in that, with In order to increase the throughput and efficiency of the device, it is equipped with a switch, the make contacts of which are connected to one power system, and the make contacts to the other power system, and a switch control unit containing sensors of power direction signals and an element for comparing these signals, the sensors being connected to the stator and rotor circuits of asynchronized machines.