SU1262670A1 - Grid-controlled semibridge inverter - Google Patents

Abstract

The invention relates to electrical engineering and can be used in secondary power supply systems. The purpose of the invention is to enhance the functionality by allowing the inverter to control an external signal. With the key closed (K) 7, the positive feedback circuit maintains K 2 in the open state. The voltage on the primary winding of the transformer (Tr) 5 is equal to half the supply voltage, the magnetizing current Tr 5 increases linearly. When K 7 is locked, K 6 is unlocked by an external signal. At the primary winding, an emf of self-induction occurs, and while the process of leaving saturation K 2j occurs, the voltage on the windings is zero. At the end of the K 2 out of saturation, the positive feedback circuit provides a forced locking of K 2 and an unlocking of K 1. As the magnetizing current drops to zero, a voltage equal to the voltage of the power supply is generated on the coil and the magnetizing current flows through (L diode 10 and K 1. Next, the reverse magnetization reversal of the magnetic circuit through the open K 1 and K 6 occurs. After locking K 6 and unlocking K 7, the processes are repeated. 1 Cp f-ly, 2 ill.

Description

The invention relates to electrical engineering and can be used in power systems, electric drives and automation.

The purpose of the invention is the expansion of functionality by providing the ability to control the inverter with an external signal.

Figure 1 shows a schematic diagram of the proposed inverter, Fig, 2 is a diagram of the voltage shape on the transformer windings, the Inverter (Fig. 1) contains keys and 2, capacitors 3 and 4, transformer 5, connected in a half-bridge circuit, and the upper leads are , cha and the capacitor 3 are connected to the positive, and the lower terminals of the key 2 and the capacitor 4 are connected to the negative input terminal of the inverter. The lower output of the key 1, the upper output of the key and the first output of the primary winding of the switching transformer 5 are combined, the lower output of the capacitor is connected to the upper output of the capacitor 4 'and the first ^ outputs of the keys 6 and 7. The second output of the key 6 is connected to the cathode of the diode 8, the second is the output key 7 - to the anode of the diode · 9. The cathodes of the diodes 9 and 10, the anodes of the diodes 8 and 11 and the second terminal of the primary winding of the transformer 5 are combined. The cathode of diode 11 is connected to the positive, the anode of diode 10 is connected to the negative input terminal of the inverter.

The inverter operates as follows.

With the key 7 closed, the positive feedback circuit maintains the on state of the power switch 2. The voltage on the primary winding is equal to half the supply voltage, the magnetization current of the transformer 5 increases linearly. At time Ts, key 7 is locked, and key 6 is unlocked by an external signal. On the primary winding of the transformer, an EMF of self-induction occurs and until time t ₂ , while the process of exit from saturation of switch 2 occurs, the voltage on the windings is zero, the magnetization current flows through switch 2 and the GO diode. After the saturation of key 2 is exited, the voltages on the windings change sign, the positive feedback winding circuit provides forced locking of key 2 and unlocking of key 1. Until time tj, i.e. while the magnetization current drops to zero, a voltage equal to the voltage of the power source is formed on the primary winding, and the magnetization current flows through diode 10 and key 1. In the time interval t ₃ - t ₄ , the magnetic circuit is reversed magnetically through public keys 1 and 6. After locking key 6 and unlock key 7 (time t ₄ ) the processes in the circuit proceed similarly.

Claims (2)

The invention relates to electrical engineering and can be used in power supply systems, electric drive and automation. The purpose of the invention is to enhance the functionality by allowing the inverter to be controlled by an external signal. Fig. 1 is a schematic diagram of the proposed inverter; Fig. 2 is a voltage waveform on the transformer windings. The inverter (FIG. 1) contains keys 1 and 2, capacitors 3 and 4, a transformer 5 connected in a half-bridge circuit, the upper terminals of the key 1 and the capacitor 3 are connected to positive, and the lower terminals of the key 2 and capacitor 4 to negative input. inverter. The bottom pin of key 1, the top pin of key 2 and the first pin of the primary winding of the switching transformer 5 are combined, the bottom pin of capacitor 3 is connected to the top pin of capacitor 4 and the first pin is key 6 and 7. The second pin of key 6 is connected to the cathode of diode 8, the second pin key 7 - to the anode of the diode 9. The cathodes of the diodes 9 and 10, the anodes of the diodes 8 and 11 and the second output of the primary winding of the transformer 5 are combined. The cathode of the diode 11 is connected to the positive anode of the diode 10 to the negative input terminal of the inverter. The inverter works as follows. When the switch 7 is closed, the positive feedback circuit maintains the on state of the power switch 2. The voltage on the primary winding is equal to half the supply voltage, the magnetizing current of the transformer 5 increases linearly. At the time point C, key 7 is locked and key 6 is unlocked by an external signal. At the primary winding of the transformer, an emf of self-induction arises and until the time t, while the process of cell 2 goes out of saturation, the voltage on the windings is zero, the magnetizing current flows through switch 2 and GO diode. After the switch out of voltage saturation 2, windings change sign, the positive feedback winding circuit provides forced locking of key 2 and unlocking of key 1, until time tj, Te while the magnetizing current drops to zero, a voltage equal to the voltage of the power source is formed on the primary winding, and the magnetizing current flows through diode 10 and key 1. In the time interval t, the magnetic circuit reverses through the open keys 1 and 6. After locking the key 6 and unlock the key 7 (point in time t4) the processes in the circuit proceed in a similar way. Claim 1. Adjustable half-bridge inverter containing two main series-connected keys, two series-connected condensates a and a transformer with key management windings, and the first primary output of the transformer is connected to the key connection point, characterized in that, in order to expand its functionality by providing the inverter with the ability to control the external signal, two additional keys and a diode circuit are introduced, with In this case, the first pins of the keys are connected to the connection point of the capacitors, the second output of one of them is connected to the anode of the first one, the second output of the other is connected to the cathode of the second diode, and the cathodes of the first, third, three The second and fourth diodes and anodes are combined and connected to the second output of the transformer primary, the anode of the third diode is connected to the negative, and the cathode of the fourth diode is connected to the positive input terminals of the inverter. 2. Inverter POP.1, characterized in that the transformer is made with a non-magnetic gap in the magnetic circuit. tT, -f figure 1