SU978293A1 - Dc voltage to dc voltage converter - Google Patents

Description

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The invention relates to electrical engineering and can be used in. secondary sources of power supply of electronic equipment.

Voltage converters are known that convert the voltage of one level to the voltage of another desired level tn and 2.

Such converters are widely used in power supplies with a transformerless input (with an intermediate frequency increase) fed from an industrial network, but these converters are large and not reliable enough.

The closest to the invention to the technical essence is a device containing two single-ended converters, dual to a common output diode-capacitor filter, each of which consists of a switching transistor, a power transformer with a demagnetizing driver, and a regenerative diode, let us take the converter inputs connected parallel to the power source 3.

The disadvantage of this converter is the presence of a high voltage equal to the double voltage of the power source (2Un) on closed transistors at the moment of transformer energy recovery through the degaussing circuit. This leads to an increase in the instantaneous dissipated power at the collectors of the transistors, to losses in the demagnetization winding, reduces reliability; and

15 Efficiency converter. .

Claims (2)

In this case, the voltage on the collectors of closed transistors is limited by the level of 2Un only in 20 cases when the inductive coupling coefficient between the primary and demagnetizing windings of the power transformers is close to unity. For this, a bifillary method of winding these windings is necessary. Transformers in this case have significant dimensions and are non-technological. The refusal of the bifillary winding method results in a surge voltage occurring when the transistors are closed (due to the inductance of the dissipation of the transformer primary winding The voltage across the closed transistors is equal to the sum of the source double voltage power supply (21),) the amplitude of the above-mentioned emission, this increases the instantaneous power dissipation at the collectors of the transistors, reduces the reliability of the converter and its K D. In order to reduce emissions, special limiters are introduced into the known converter, which complicates the scheme, reduces the efficiency of the converter, its weight and dimensions, and reliability. The purpose of the invention is to improve the weight and dimensions of the device, increasing its reliability and efficiency. The goal is achieved by the fact that the DC / DC converter contains two inverter cells connected in series to the input terminals, each of which contains a key element connected to the primary winding of the output transformer, the secondary winding of which is connected to a common LCD via a matching rectifier - a filter whose output is connected to the output terminals, and the attachment point of each key element with one of the primary terminals of the corresponding winding Khodnev transformer connected to the corresponding first mu electrode regenerative diode parallel input terminals of the introduced capacitive voltage divider, the midpoint of which is connected to other ends of your primary GOVERNMENTAL windings of output transformers, and each of the extreme points of this voltage divider is connected to respective second electrodes rekuperatsionnyk diodes. FIG. 1 is a diagram of the device; FIG. 2 is a timing diagram of its operation. In this converter, for example, one of the series-connected single-ended voltage converters is connected to the power source. The first converter consists of a switching transistor 1, an input capacitor 2, a power transformer 3, a recovery diode 4, and a single-ended rectifier 5 that operates on a common inductive-capacitance diode filter 6-7-8, the second one - from switching commutator 9, input capacitor 1 (1, power transformer 11, recovery diode 12 and single-ended rectifier 13o Transistors 1 and 9 operate alternately and controlled by voltage pulses shifted by half of the switching period of the device. Suppose that transistor 1 is open, and transistor 9 is closed. In this case, a voltage of Un is applied to the primary winding of transformer 3. Reverse voltage U is applied to the closed diode k , The flow path of the current of the primary winding of the transformer 3 at this point in time is closed along the circuit 2-1-3- 2. When the transistor 1 is closed on the primary winding of the transformer 3, a self-induction EMF occurs, under the influence of which the diode is opened and the energy stored in the transformer during the open state of transistor 1 recovers to capacitor 10 ". The voltage up to / on the capacitor 2 2, and the self-induction EMF of the transformer primary, paBHoe.-Up / i, is added, and a voltage equal to the power supply voltage is applied to the closed transistor 1, the process of opening and closing the transistor 9 proceeds similarly, 8m ment opening 9 of the transistor circuit current flow in the primary winding of the transformer 11 is closed by 10-11-9-10 circuit, circuit current flow in the secondary winding of the transformer circuit is closed by 11-137-8-11. When the transistor 9 is closed on the primary winding of the transformer 11, a self-induction EMF occurs, under the influence of which diode 12 is opened, and the energy accumulated in the transformer 11 is recovered during the open state of transistor 9 through a circuit 11-12-2-11. The voltage on the closed switching transistor 9 and the recovery 5 diode 1.2 is equal to the voltage of the power source. During the time when both switching transistors 1 and 9 are closed, a part of the energy accumulated by the inductance of the filter is transmitted through the shunt diode 6 to the load. Thus, a voltage equal to V is applied to the closed switching transistors and regenerative diodes of the device being described. In the known device {3, the demagnetization of the transformer is sensed through the additional demagnetization winding, with parasitic voltage surges on the closed switching transistors of the converter, o Conditioned inductance of the transformer. In the proposed device, the demagnetizing winding of the transformer in each of the single-ended converters is eliminated. When switching the inductance of the transformer from the magnetizing to demagnetizing state, no parasitic voltage surge occurs, since both processes occur in the same winding of the transformer. The exception of the demagnetizing winding in transformers makes it possible, by simplifying the design of the transformer, not only to reduce its size and weight, but also to increase the efficiency of the transformer, since demagnetizing the winding in a known device is performed with a thinner wire one way than the primary winding, has great resistance and makes great losses. The absence of parasitic surge | voltage across closed switching transistors increases the reliability of the device and reduces the instantaneous power dissipated by the switching transistors. 3 The proposed technical solution provides improved weight and size indicators, improved reliability and efficiency in comparison with the known solution. Claims of a DC / DC converter containing two consecutive, single-phase inverter cells connected to the input terminals, each of which contains a key element connected to the primary winding of the output transformer, the secondary winding of which is connected to a common LCD through a rectifier filter whose output is connected to the output pins, and the point of attachment of each key is. An element with one of the primary windings of the corresponding output transformer is connected to the corresponding first recovery diode electrode, which is due to the fact that, in order to improve the weight and size parameters, efficiency and reliability, the input capacitor voltage divider is connected in parallel to the input terminals, the midpoint which is connected to the other leads of the primary windings of the output transformers, and each of the extreme points of this voltage divider is connected to the corresponding second electrodes p kuperatsionnyh diodovo Sources of information received into account in the examination 1, USSR Author's Certificate 576647. cells. H 02 M 7/537,. 2, Electronic equipment in automatic collection. Ed. Yu.P.Koneva, M., -Sovo Radio, 1977. Vol. 9, p. 95 rice 10o 3, Electronics, 1978, t, 51,. 3, s. 50-56. 7 / Wyx. 6 - Ik, / y Ur. a. iif. .XV X .X yx X V % x v fug. .xXX x v