SU570167A1 - Three phase voltage inverter - Google Patents

Description

(54) THREE-PHASE VOLTAGE INVERTER The voltage across the capacitor UQ may be less than Uj. (5) before the beginning of the switching) In the first case, when (, C occurs before the comm switch capacitor from the source of the second jBo to the second case, when j Lcf-accumulation of excess energy, co-ddpafl at certain values of current n euzy with each A new switching cycle will increase. This leads to the fact that the voltage on the switching capacitor will fluctuate depending on the load current. In real circuits, the voltage increase is 2 ~ 50%, therefore, the voltage on the comm wiring co-ordinators on 2О-5О Ь, i.e., to increase their installed capacity.In addition, in such a scheme, high growth rates of direct flow from the source of the opposite group of thyristors of the opposite group occur on the commutation of the thyristors. devices, it increases its mass. In order to reduce the weight and dimensions of the inverter, the commutating chokes are connected in series with each of the pilot valves, and in series with each charge generator n resistor. In addition, the leads for connecting the charge source are formed by the junction points of the commutating chokes and the divider valves. FIG. Figures 1 and 2 show the circuit board of the proposed inverter, the controlled thyristor source 2–7 and the reverse current diode bridge 8–13 are connected to the regulated constant current source 1 1. The source of charge charging 14 is connected to a bridge of commuting thyristors 15–20, each phase of which has switching capacitors 21–2.3 connected, the second terminals of which are connected to the corresponding phases of the main thyristors 2–7. The positive pole of source 1 is connected to the positive pole of the source of a charge source 14 through parallel-connected chains, one of which contains a separating valve 24 and a switching choke 25. and shueug - charge thyristors 26 and a resistor 27. The positive pole of source 1 is connected to a negative popus a source of charging d 14 aHft in a logical way through a separating valve 28 and switching dg1ss "gl 29, tirchsgor podzar DA and a resistor 31, To the inertor clamps is connected si: ghropny daigytel 32.t, The circuit works sgs follows. Let the primary 1hiristor 2,6,7 be turned on and pass the current from the source 1p to the load 2. At the same time, the capacitor 21 has an armature, the polarity of which is shown in FIG. 1. When the switching thyristor 2O is turned on, the discharge in circuit 21-20 begins -29-28-7-21, while the thyristor 7 is locked and the capacitor 21 is recharged along the circuit 21-2a-29u28-13-21, the energy stored in the switching choke 29 is accumulated. The value of this energy will depend on the discharge current of the capacitor 21 and the load current of the lockable thyristor 7, Example 1., where: d4, is the energy accumulated in the switch it throttle 29 during discharge switching capacitor 21 ,. The capacitor's We-energy is before the start of switching. In this case, after the capacitor is recharged, the voltage across it will be less than the voltage before the start of switching, therefore the corresponding thyristor is switched on and the switching capacitor is charged to the specified value. EXAMPLE 2,, T, e. In throttle 29, additional energy has been accumulated (. When the voltage on the switching sensor 21 is reached (when current flows from the drossel 29 but the circuit 29-28-1321-2О-29) the ZOR thyristor is turned on, when the atom is closed along the circuit 29-28-30-31-29, the charge of the switching capacitor stops. The excess energy AW dissipates in the resistor 31 during the time where Rji is the resistance of the resistor 31; 29 the inductance of the chokes is 29 , The resistance value Rgj of the resistor 31 is determined from the relation where, is the maximum output frequency investment Since the resistance value of resistors 31 and 27 is from units of ohms to tenths of ohms (depends on the converter power), it does not affect the charge of the switching capacitors from the charge source. The charge source is connected between the points of the switching Drope-mudflows of separation ventepi (see Fig. 2). Such inclusion of the charge source allows reducing the speed of increase () of direct voltage at the commutation voltage of the tirioters. Thus, when the thyristor 15 is turned on, the speed of the overdraft voltage from the sub-source and 14 on the thyristor 18 will be reduced. Such switching-on of the subcharge source and 14 is especially advisable when the inverter has large power, when the internal resistance of the source is subcharge and small. In the adjoined inverter, the voltage on the switching capacitors is stabilized at a certain predetermined level, which makes it possible to use capacitors without voltage reserves. This makes it possible to reduce the installed power of switching capacitors by 20–5%, which reduces the cost of converting into a circuit. Formup of the invention 1. Three-phase voltage inverter, containing switching capacitors and drain plugs, main type. The power thyristors connected with them are connected to the terminals of the main power supply day connection, characterized in that, with a weight and size reduction circuit, the commutating drosteps are connected continuously with each of the sections. tepnyh ventipey and in series with each thyristor included dnym recharging resistor. 2. The inverter according to claim 1, wherein the terminals for connecting the charge source are formed by the points of connection of the commutating chokes and separate valves. Sources of information / taken into account during the examination: 1. Author's certificate CCCf № 271683, M. Kl.N02M.7 / 52, 1969. 2. Author's certificate of the USSR 406279, M. Cl. HO2M 5/42, 1971,

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FIG. one

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