SU82889A1 - DC converter - Google Patents

Description

The subject matter of the invention is a constant current converter. For one voltage in a direct current of another voltage, consisting of an inverter and a controlled rectifier.

In order to obtain the compound characteristic of the converter and to provide wide control limits in the proposed converter, in contrast to the known schemes, the circuits of the rectifier grids are fed from the inverter, which creates the possibility of rejecting one of the rectifiers.

The proposed converter can be used in electric traction for installation directly on electric locomotives when applying high voltage in a contact network.

The converter is shown on the attached drawing.

The inverter includes the following apparatuses: a three-phase two-winding power transformer /, two sets of single-electrode mercury rectifiers. Gey (2, 3, 4, 5, 6, 7) equipped with nets and a set of; three capacitors 8.

The constant voltage to be converted is supplied to the clamps. The plus of the constant voltage source is supplied to the common point of the anodes of the anode group, and the laser is connected to the common point of the cathodes of the cathode group of the inverter. The voltage is supplied to the consumer from the /// - / V terminals.

A choke 9 is applied to the AC and DC voltage equation, and it is connected so as to compensate for the constant component of the magnetic flux. Switching is carried out using capacitors connected by a triangle and connected to the interphase voltage of the primary winding of the transformer (inverter side). The grid control of the Yu rectifier is carried out in the usual way according to one of the known schemes, the grid control of the inverter gates is regulated so as to ensure the priority of their operation.

No. 82889

If you unlock valve 3 of the cathode group and valve 4 of the anode group of the inverter, the current from the source of constant voltage will flow from the minus source of constant voltage through valve 5, then through the primary winding of phase A of the transformer, through the winding of phase B of the transformer, through valve 4 to the plus source of constant voltage.

The resulting electromotive self-induction force charges the capacitors. If, further, the valve 6 is opened, the capacitors connected between the ends of phases B and J5 of the transformer are discharged to the induction-free circuit of 4 l 6 valves, reducing the current of valve 4 to zero. The current of valve 6 acquires the value that the valve has 4 before switching valves. When this happens, capacitor recharging takes place, providing the switching of other gates. Now the current flows through the windings of phases L and B. Next, valve 5 is turned off. It switches to valve 3. The non-inductive circuit of two valves 5 and 5 is again created, to which the capacitors connected between the transformer phase AB are discharged, reducing the current to valve 3 Now the current flows through the windings of phases A and B, etc.

The three-phase voltage created in the inverter is further rectified; Since the bridge circuit was used for the rectifier, the rectified voltage has a six-phase ripple.

A change in the load of a consumer of such a converter causes a significant change in the magnitude of the variable voltage. To prevent voltage fluctuations, valves 2 and 7 are provided with grids. Through the grid control of the inverter voltage rectifier, the necessary balance of reactive powers is created, resulting in the required external response of the converter.

Subject invention

1. A DC converter of one voltage to a DC of another voltage, consisting of an inverter and a rectifier, whose fans are connected in a bridge circuit, characterized in that, in order to obtain a compound characteristic of the converter, the power of the rectifier grid circuits implemented from the inverter voltage through a transformer, magnetised by a current proportional to the difference of the reference voltage and voltage of the inverter.

2. Iop converter, 1, characterized in that, in order to obtain stable operation in the range from idle to full load, the inverter capacitors are made partitioned.