RU2455746C2 - Two-stroke bridge converter - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: additionally included in the two-stroke converter are a diode bridge circuit, the magnetic storage second winding and the transformer second primary winding that, as well as the transformer primary winding, is magnetically connected to the secondary winding connected to a load. The connection of the diode bridge circuit, the magnetic storage second winding and the transformer second winding to the two-stroke converter elements is designed as specified in the application materials. Multiple versions of the converter circuit design are provided.

EFFECT: converter operation reliability enhancement and energy performance improvement.

11 cl, 7 dwg

Description

The proposed device relates to power converting equipment and is intended for converting and regulating the energy consumed from a direct current source, and transmitting the converted energy to its receiver using transformer coupling between the source and receiver energy circuits.

A push-pull converter is known that contains power controlled keys connected by a bridge circuit, as well as a circuit formed in series by a first winding of a magnetic energy storage device, a capacitor and a primary winding. The primary winding is magnetically connected to the secondary winding connected through rectifier diodes to a DC load shunted by the filter capacitor (V.I. Meleshin. Transistor converter technology. - M.: Technosphere. 2005, Fig. 13.7-a, p. 295).

In the known device for regulating the energy transmitted to the consumer, resonance phenomena occurring in an LC circuit formed by a winding of a magnetic energy storage device and a capacitor are used, which are connected to each other in series.

A disadvantage of the known device is the existence of a fundamental possibility of increasing energy accumulated in the elements of the LC circuit, which occurs from one clock cycle of the device to another. This increase is characterized by an increase from step to step of the amplitude of the voltage across the capacitor of the LC circuit and the amplitude of the current flowing through the elements of the LC circuit, switched by power transistors. In the process of such an increase, both the voltage amplitude at the capacitor and the current amplitude can reach indefinitely large values. In particular, the amplitude of the voltage across the capacitor can many times exceed the voltage of the power source. As a result, the reliability of the device decreases and its energy efficiency deteriorates.

The accumulation of energy in the elements of the LC circuit, accompanied by an increase in the amplitudes of the voltages on them and the current of the LC circuit, is confirmed by the results of simulation of pulsed processes in a known scheme.

The aim of the proposed technical solutions is to increase the reliability of the voltage converter and improve its energy performance.

This goal is achieved by the fact that in a push-pull converter containing power controlled keys connected by a bridge circuit, the input circuit of which is connected to the power buses, and the circuit formed in series by the first winding of the magnetic energy storage device, the capacitor and the first primary winding, which is magnetically connected to secondary winding connected to the load, introduced an additional diode bridge circuit, a second winding of the magnetic storage and a second primary winding, which is magnetically connected to toric winding connected to the load. In the proposed device:

the first and second terminals of the input circuit of the diode bridge circuit are connected respectively to the first and second terminals of the capacitor, and the outputs of the output circuit of the diode bridge circuit are connected to the power buses of the device;

the first output of the output circuit of the bridge circuit formed by the power controlled keys is connected to the first output of the capacitor through the first two-terminal network, which contains the first winding of the magnetic storage device and the primary winding magnetically connected to the secondary winding connected to the load in series;

the second terminal of the capacitor is connected to the second terminal of the output circuit of the bridge circuit formed by the power controlled keys through a second two-terminal device, which comprises a second winding of the magnetic storage device connected in series and another primary winding magnetically connected to the secondary winding connected to the load;

in the series circuit formed by the first two-terminal, capacitor and second two-terminal, the first and second primary windings are connected according to.

The proposed device in the embodiment where the first winding of the magnetic storage device and the second winding of the magnetic storage device do not have magnetic coupling, is presented in figure 2. The absence of magnetic coupling between the windings means that each of them is represented by the winding of a separate inductor. It is advisable to have an approximate equality of the inductances of the windings of these chokes. The condition of strict equality is not mandatory. However, to simplify the description of physical processes, it is believed that the inductances are the same.

It is advisable that the ratio of the instantaneous voltage values on the first primary winding and on the secondary winding magnetically connected to it be close to the ratio of the instantaneous voltage values on the second primary winding and the secondary winding magnetically connected to it. Strict equality of these relations is not mandatory. However, to simplify the description of physical processes in the circuit, it is believed that these relations for the first and second primary windings are the same.

In the proposed device in figure 1, the first power bus 1 is connected to the negative pole of the power source 2, and the second bus 3 is connected to the positive pole. When describing the processes, the potential of the first bus 1 is considered equal to zero. Then the potential of the second tire 3 is positive.

The input circuit of the bridge circuit formed by power controlled keys 4, 5, 6 and 7 is connected to the power buses 3 and 1. In FIG. 2, as well as in the remaining drawings relating to different embodiments of the proposed device, power controlled keys are shown in the form field effect transistors. These semiconductor devices are characterized by controlled conductivity for currents of direct direction and constantly present high conductivity for currents of inverse direction. Direct conductivity control is provided by signals specified in the input circuits of field-effect transistors.

Regardless of the actual form of power controlled keys used in the proposed device, a prerequisite is the similarity of their properties to the above properties of field-effect transistors. Further in the description, for the purpose of abbreviation, the term "power controlled key" is replaced by the term "transistor".

The first terminal 8 of the output circuit of the transistor bridge circuit is formed by the connection point of the transistors 4 and 5. The second terminal 9 of the output circuit of the transistor bridge circuit is formed by the connection point of the transistors 6 and 7.

To the power buses 3 and 1, in addition, the outputs of the output circuit of the rectifier bridge circuit, which is formed by the diodes 10, 11, 12 and 13, are connected. The first terminal 14 of the input circuit of the rectifier bridge circuit is the connection point of the diodes 10 and 11. The second terminal 15 of the input circuit The rectifier bridge circuit is the junction point of the diodes 12 and 13. A capacitor 16 is connected between the terminals 14 and 15.

Between terminal 8 of the transistor bridge circuit and terminal 14 of the rectifier bridge circuit, a first two-terminal network is connected. It is made in the form of a series-connected first winding 17 of a magnetic energy storage device and a first primary winding 18, which is magnetically connected to the secondary winding. The secondary winding contains two sections 19 and 20. They are connected to the load 21, shunted by the filter capacitor 22, through power rectifier diodes 23 and 24.

Between terminal 9 of the transistor bridge circuit and terminal 15 of the rectifier bridge circuit, a second two-terminal network is connected. It is made in the form of a second winding 25 of a magnetic energy storage device connected in series and a second primary winding 26, which is magnetically connected to the secondary winding.

The magnetic connection between the primary winding 18, the primary winding 26 and the secondary winding (19, 20) is ensured by the fact that all these windings together with the magnetic circuit 27, which is common to them, form a single power transformer.

In the series circuit, which is formed by winding 17, winding 18, capacitor 16, winding 25 and winding 26, the primary windings 18 and 26 of the power transformer are included according to.

The principle of regulating the flow of energy transmitted from the power source 2 to the load 21 is based on the use of the oscillatory nature of the electrical processes that occur during operation of the device and due to the presence of LC circuit elements in it in the form of the first winding 17 of the magnetic energy storage device, capacitor 16 and second winding 25 magnetic energy storage. In this LC circuit, said elements are connected in series.

Power transistors 4 and 7 of the first pair of opposite shoulders of the bridge circuit by the action of signals generated by the control device, are transferred to a state of high conductivity during odd clock cycles (1st, 3rd, 5th, ...).

Power transistors 6 and 5 of the second pair of opposite shoulders of the bridge circuit by the action of signals generated by the control device, are transferred to a state of high conductivity during even work cycles (2nd, 4th, 6th, ...).

The durations of the signals controlling the power transistors almost coincide with the duration of the corresponding clock cycles. By varying the signal repetition rate, the power consumed from the power supply 2 and transmitted by the power transformer to the load 21 is regulated. The lower limit of the range of the variable operating frequency is higher than the resonant frequency of the LC circuit.

The control device provides a "technological" delay in the appearance of signals generated in each given clock cycle, in relation to the completion of the control signals generated in the previous clock cycle.

The end of the signals provides the locking of power transistors, which in the previous cycle were in a state of high conductivity. Due to the “technological” delay in the appearance of signals generated in the next new clock cycle, an interval is formed during which all the power transistors of the bridge circuit are locked. Accordingly, at the beginning of this interval, the connection of each of the outputs of the output circuit of the bridge transistor circuit with power buses 1 and 3 is broken.

The current of the LC circuit, thanks to the energy stored at the end of the previous cycle in the magnetic storage devices of the LC circuit, continues to flow for some time in the same direction as it was when the power transistors were locked that were in the state of direct conduction at the moment immediately before the end of the signals controls in the previous measure. The capacitors of transistors are recharged with this current.

In the interval of recharging the capacitance of the transistors for a short period of time, the potential of that output of the output circuit of the transistor bridge circuit, which during the previous cycle was “tied” to the high potential of bus 3, gradually decreases. This binding was made through a transistor connected to this bus, which was in a state of high conductivity in the previous cycle. For example, if the previous clock cycle was even, then a high potential value at the beginning of the recharge interval takes place at pin 9. When the lowering potential of this pin reaches a small negative value, a transistor will enter the inverse conduction state, the output circuit of which is between the specified pin and bus 1. If the previous clock cycle was even, then transistor 7 will be one.

Simultaneously with the process under consideration, in the interval of transistor capacitance overcharge for a short period of time, the potential of that output of the output circuit of the transistor bridge circuit, which during the previous cycle was “tied” to the zero potential of bus 1, is gradually connected. This binding was made through a transistor connected to this bus, which was in a state of high conductivity in the previous cycle. For example, if the previous clock cycle was even, then a low potential value at the beginning of the recharge interval takes place at pin 8. When the increasing potential of this pin slightly exceeds the potential of bus 3, a transistor will switch to the inverse conduction state, the output circuit of which is located between the specified pin and bus 3 If the previous clock cycle was even, then transistor 4 will be.

The process of recharging the capacitances of transistors takes such an insignificant time in comparison with the period of operation that the duration of this process can be neglected. Therefore, without a significant error, we can assume that almost immediately after the locking of one pair of transistors, another pair goes into the state of inverse conductivity.

If the previous clock cycle was even, a pair of transistors 4 and 7 goes into the conduction (inverse) state. The current state of these transistors at time t ₀ starts an odd cycle of the next cycle (period) of the circuit, which is discussed later. Throughout this cycle, terminal 8 is “tied” to the high potential of bus 3, and terminal 9 to zero potential of bus 1. If we neglect the voltage drop across the power transistors, then in a new odd cycle, the potential of terminal 8 is equal to the supply voltage, and the potential of terminal 9 - zero.

Due to the short duration of the process of recharging the capacities of transistors, we can assume that at time t ₀ there is no significant change in the state of the elements of the LC circuit with respect to their state at the time of the end of the previous cycle (even).

The initial state of the LC circuit elements for a new cycle is characterized by the fact that the current of the capacitor 16 flowing through the windings 17 and 25, which is determined by the energy level stored in the first and second magnetic drives by the time the previous (even) cycle ends, is directed from terminal 15 to conclusion 14. By the current that flowed in the same direction in the previous cycle (even), the capacitor 16 was charged so that the potential of the output 15 is higher than the potential of the output 14.

The magnitude and direction of the current flowing through the primary windings of the transformer 27 at the beginning of a new cycle (odd) practically do not undergo changes with respect to the moment the previous cycle (even) is completed. This means that on the secondary side of the transformer 27, the current continues to flow through the secondary winding 20. It is connected through the power rectifier diode 24 in parallel with the output filter capacitor 22. Therefore, the voltage polarity at winding 20: “plus” - at the end of the winding, “minus” - at its beginning. Due to the magnetic coupling between the windings of the transformer 27, the voltage polarity is the same across all its windings.

For any time, including the initial moment, the instantaneous voltage values on the primary windings 18 and 26 are the same if the proportionality coefficients between the voltages on the primary windings 18 and 26 and the voltages on the secondary windings 19, 20 are the same (this assumption was made earlier )

For any time, including the initial moment, the instantaneous voltage values on the windings 17 and 25 of the first and second magnetic drives are the same if the inductances of these windings are the same (this assumption was made earlier). This is due to the fact that the same current flows through the windings, since the diodes 10-13 connected by a bridge circuit are in a locked state. As for the voltages on the windings of magnetic drives, they are equal to the product of two factors: the first is the inductance of the winding, the second is the time derivative of the change in current flowing through the winding.

The equality of the sum of the instantaneous voltage values on the windings 17.18 and the sum of the instantaneous voltage values on the windings 25, 26 allows us to draw the following conclusion. For any time, including the initial moment, the potential difference between the power bus 3 and the output of the capacitor, on which the instantaneous value of the potential is higher than on its second output, is equal to the potential of this second output relative to the zero potential of the bus 1. This means that the time-dependent potentials of the capacitor terminals are represented by the same alternating functions, which change out of phase with respect to a level equal to half the supply voltage.

At the beginning of a new odd cycle, the current flows through the power transistors 4 and 7 in the inverse direction. This current closes along the circuit, the elements of which are further listed in accordance with the direction of the current. Namely: bus 1 of power supply 2; power transistor 7; winding 25 of the magnetic drive; the primary winding 26 of the power transformer 27; capacitor 16; the primary winding 18 of the power transformer 27; winding 17 of the magnetic drive; power transistor 4; bus 3 power supply 2; bus 1 power supply 2.

In the circuit where the inverse current of the power transistors 4 and 7 is closed, the voltages on all its elements, except the windings 17 and 25, are directed towards the flowing current. Therefore, all circuit elements, except windings 17 and 25, are energy receivers, and windings 17 and 25, on the contrary, act as its sources. The energy that is transmitted from the windings 17 and 25 to the remaining elements of the circuit, where the inverse current of the power transistors 4 and 7 is closed, is provided by the energy consumption stored in the magnetic storage devices by the time the previous cycle of the device ends. The inverse current drops quickly, which is caused by the high value of the total voltage on the windings 17 and 25. It is equal to the sum of the voltage of the power supply 2, the voltage on the primary windings 18 and 26 of the power transformer 27, the voltage on the capacitor 16, the voltage drops on the power transistors 4 and 7 .

The “technological” delay of unlocking one pair of transistors with respect to locking the other is set so that the unlock signal arrives before the end of the inverse current flow interval. Therefore, in reality, the voltage drop across the power transistors in the inverse direction is negligible in comparison with the other terms listed above.

Among the listed components of the total voltage on the windings 17 and 25, all of them, except the voltage on the capacitor 16, are unchanged. As for the voltage across the capacitor 16, it continues to increase, since energy is transferred to the capacitor by the current of the circuit. The loss resistance in the circuit is negligible (the converter circuit is usually characterized by a high efficiency value). Therefore, the current drop in the circuit is described by a sinusoidal function. Its frequency is equal to the resonant frequency of the LC circuit.

When the modulus of the inverse current of the power transistors decreasing according to the sinusoidal law decreases to a value equal to the amplitude value of the magnetizing current of the power transformer (negative in sign), the direction of the current of the secondary windings will change. Now, on the secondary side, current will begin to flow through winding 19. In this case, a positive polarity voltage will appear on the transformer windings.

Always in real conditions, the total voltage on the primary windings 18 and 26 of the power transformer is less than the voltage of the power source. Therefore, a change in the polarity of the voltages on the transformer windings, although it will lead to a decrease in the total voltage on the windings 17 and 25 of the magnetic energy storage devices, but these voltages will continue to be directed towards the current in the inverted current circuit of the power transistors mentioned above. In this circuit, therefore, magnetic storage devices continue to function as energy sources, i.e. the process of returning the energy previously stored in them continues, although at a reduced speed. The decreasing inverse current, as before, is described by a sinusoidal function. Its frequency is still equal to the resonant frequency of the LC circuit, but the amplitude is lower than in the previous interval, when the polarity on the transformer windings was negative.

When the inverse current of the transistors decreases in absolute value, it decreases to zero, the two processes that occurred before this end will end. Firstly, the return of energy to the power source by the inverse current of the power transistors will stop. Secondly, the energy storage in the capacitor 16 will stop, and, accordingly, the potential difference between its terminals will reach the amplitude value.

At the time t _{1 of the} decay to zero of the current of the power transistors, a new stage of the processes in the circuit begins. It is characterized by the fact that the current of power transistors begins to flow through them in the forward direction. This current closes along the circuit, the elements of which are further listed in accordance with the direction of the current. Namely: bus 3 of power supply 2; power transistor 4; winding 17 of the magnetic drive; the primary winding 18 of the power transformer 27; capacitor 16; primary winding 26 of the power transformer; winding 25 of the magnetic drive; power transistor 7; bus 1 power supply 2; bus 3 power supply 2.

For modes of transmission to the load of power not exceeding the nominal value, the current loop of power transistors 4 and 7 is unbranched. This is due to the fact that at any moment of time, the potentials of the terminals 14 and 15 of the LC capacitor satisfy the inequalities 0 <φ ₁₄ <E, 0 <φ ₁₅ <E, where E is the voltage of the power supply 2. Fulfillment of the indicated inequalities means that the diodes 10 -13 are in the locked state, and there is no branching of the current from the circuit. Thus, the current of power transistors 4 and 7 is equal to the current flowing through the elements of the LC circuit.

For a closed current loop of an LC circuit, the following combinations are characteristic between the direction of the current and the polarity of the voltages on the circuit elements.

The current direction of the LC circuit flowing through power supply 2 and the voltage polarity of this source are the same. This means that the power source 2 operates in the mode of the energy source, and not its receiver, as it was previously in the interval between time instants t ₀ , t ₁ .

из вторичной обмотки 19. Положительная полярность напряжений на первичных обмотках 18 и 26 означает, что эти напряжения направлены навстречу току LC-цепи, протекающему по обмоткам. Поэтому первичные обмотки трансформатора выступают в роли приемников энергии.After the moment t _{1, the} voltage of positive polarity is transformed into the primary windings 18 and 26

from the secondary winding 19. The positive polarity of the voltages on the primary windings 18 and 26 means that these voltages are directed towards the current of the LC circuit flowing through the windings. Therefore, the primary windings of the transformer act as energy receivers.

The voltage on the secondary winding 19, which transmits current through the rectifier diode 23 to the load 21, shunted by the output filter capacitor 22, is equal to the sum (V _out + ΔV _rect ) where V _out is the voltage across the output filter capacitor, ΔV _rect is the voltage drop across the rectifier diode connected in series with the secondary winding.

, трансформируемое в первичную обмотку, практически неизменны во времени.Usually negligible voltage ripple on the capacitor of the output filter, and, in addition, the inequality ΔV _rect << V _out . Therefore, the voltage on the secondary winding, as well as the voltage

, transformed into the primary winding, are practically unchanged in time.

At time t ₁ , when the current of the LC circuit has become equal to zero, the capacitor 16 of this circuit has accumulated a maximum charge. The voltage on it is equal to the amplitude value V _{C, max} . The polarity of this voltage coincides with the current direction of the LC circuit. This means that at time t ₁ , as well as for a certain period of time after this moment, the capacitor 16 acts as an energy source. This capacitor is discharged by the current of the LC circuit, and the discharge process is oscillatory in nature.

. Поскольку всегда выполняется неравенство

, напряжение, приложенное к обмоткам 17 и 25, положительно, т.е. оно направлено навстречу току LC-цепи. Это означает, что в момент времени t₁, а также на протяжении некоторого промежутка времени после этого момента, обмотки выступают в роли приемников энергии. Она запасается в магнитном поле, создаваемым током LC-цепи, протекающим по обмоткам.At time t ₁ , when the current of the LC circuit became equal to zero, a voltage equal to the voltage applied to the windings 17 and 25 of the magnetic drives of this circuit

. Since the inequality always holds

, the voltage applied to the windings 17 and 25 is positive, i.e. it is directed towards the current of the LC circuit. This means that at time t ₁ , as well as for a certain period of time after this moment, the windings act as energy receivers. It is stored in a magnetic field created by the current of the LC circuit flowing through the windings.

The change in the current of the LC circuit in the interval that begins at time t ₁ when the current of the LC circuit is zero is described by well-known expressions

Where

In the expressions (1) and (2): L is the sum of the inductances of the windings 17 and 25 of the magnetic drives of the LC circuit; C is the capacitance of the capacitor 16 of this circuit.

The power consumed from the power source and transmitted by the transformer to the load is controlled by changing the switching frequency of the power transistors. The lower limit of the range of variable frequencies is higher than the resonant frequency of the LC circuit, equal to

When lowering the switching frequency of the power transistors, which is accompanied by an increase in the interval between the moments t ₁ and t ₂ , the charge increases, which is transmitted to the primary windings of the power transformer in the interval when the current of the LC circuit maintains this direction (positive or negative). The duration of this interval is half the period of operation of the device. Accordingly, the energy transmitted by the transformer to the load increases, i.e. by changing the operating frequency, the flow of energy into the load is regulated.

When lowering the switching frequency of the power transistors, which is accompanied by an increase in the interval between the moments t ₁ and t ₂ , the charge increases, which is transmitted to the capacitor of the LC circuit in the interval when the current of this circuit maintains this direction (positive or negative). Accordingly, the change in voltage across the capacitor between its extreme values (minimum and maximum) increases. Thus, an increase in the power transmitted to the load is accompanied by an increase in the amplitude of the alternating voltage on the capacitor of the LC circuit.

There are two positive properties inherent in the proposed device.

Firstly, during the operation of the circuit, the potentials of the terminals of the capacitor of the LC circuit change in time symmetrically and out of phase with respect to a level equal to half the supply voltage. This means that the maximum possible range of energy-efficient regulation is implemented, in which the diodes 10-13 are locked. The locked state of the diodes corresponds to the conservation of the oscillatory nature of the processes in the circuit, due to which the switching losses in power transistors and losses associated with the inertia of the power rectifier diodes are reduced.

Secondly, the increase in the amplitude of the voltage across the capacitor of the LC circuit, which occurs with increasing current of this circuit and, accordingly, the current of the primary and secondary windings of the power transformer, is limited by the inequality

.

.

The inequality is ensured by a combination of the marked symmetry of the time variation of the potentials at the terminals of the capacitor and the presence in the proposed device of a bridge circuit formed by diodes 10-13. Their unlocking implements a voltage limitation on the capacitor.

The limitation of the amplitude of the voltage across the capacitor 16 has the effect of limiting the amplitude of the current of the LC circuit, which flows through the output circuits of the power transistors, which follows from (1) and (2). At the same time, the current transmitted by the secondary windings to the load is limited. All this as a whole ensures the fulfillment of the goal, which is to increase the reliability of the device.

The symmetry of the time variation of the potentials at the terminals of the LC circuit capacitor and the antiphase nature of this change are due to the equality of the instantaneous values of the potential difference between the terminals of the first and second two-terminal devices. The difference from equality may be due to the fact that the proportionality coefficient between the voltages of the first and second primary windings of the transformer is different from unity, or because the inductance of the first winding of the magnetic storage device is not equal to the inductance of the second winding of the magnetic storage device.

Modeling of processes in the converter shows that the difference in the instantaneous values of the potential difference between the terminals of the first and second two-terminal devices (asymmetry of two-terminal devices) is manifested in the appearance of spasmodic changes in the potentials of the capacitor terminals relative to the potentials of the power supply buses. These jumps are the smaller, the smaller the asymmetry. The presence of jumps somewhat reduces the regulation range in which the diodes 10-13 remain in a locked state, but the positive properties of the proposed device as a whole are preserved.

The positive qualities of the proposed device are preserved, and the device itself is simplified if the first winding of the magnetic storage device and the second winding of the magnetic storage device are combined by a common magnetic circuit 28, i.e. magnetically connected, and, in addition, in the serial circuit formed by the first two-terminal, capacitor and second two-terminal, these windings are connected according to what is implemented in the second variant of the circuit.

The scheme of the device according to option 2 is presented in figure 2.

The principle of operation of the second variant of the circuit fully coincides with the principle of operation of the circuit depicted in figure 1. The positive quality of the second variant of the circuit with respect to the first, in addition to simplification, is the simplicity of ensuring the symmetry of the first and second two-terminal devices. For this it is enough that the proportionality coefficients between the voltages on the primary windings 18 and 26 are equal to unity, and the proportionality coefficients between the voltages on the windings 17 and 25 are equal to unity. Bearing in mind that these windings are united by a common magnetic circuit 28, equality to unity proportionality coefficients between the voltages on the windings 17 and 25 is achieved by the equality of the numbers of their turns.

The positive qualities of the proposed device are preserved, and the device itself can be performed with the best overall dimensions or energy performance if each of the two primary windings and the associated secondary winding connected to the load are combined by a separate magnetic circuit, forming a separate transformer. In this case, energy is transferred to the load by two transformers in parallel.

The transfer of energy by two transformers, firstly, allows them to be performed in smaller dimensions, since each transmits half the power. This is often a prerequisite for a possible reduction in the dimensions of the unit where the transformers are located (for example, by reducing the height of the unit).

Secondly, when half the power is transmitted by each transformer, heat losses in the windings can be reduced.

Heat losses are proportional to the square of the winding current. Therefore, in the secondary winding of each of the transformers, losses are reduced four times, and the total heat loss in the secondary windings of the two transformers is halved.

For a given power transmitted to the load, the current of the primary windings of the transformers through which this power is transmitted does not depend on the number of transformers. However, each of the two primary windings contains half the number of turns relative to their total number in the two primary windings. Therefore, although the total heat loss power in the primary windings of the two transformers does not decrease, the sum of the heat loss power released in the windings of each of them decreases by a factor of more than two. This facilitates the thermal regime of transformers, which increases the reliability of the device.

The scheme of the device according to option 3, which implements the transmission of energy by two transformers in parallel, is presented in figure 3.

The third option differs from the second in that the first primary winding 18 and the magnetically secondary winding associated with it (29, 30) are combined by a common magnetic core 31, forming a separate (first) power transformer. The secondary winding of the first transformer is connected to the load 21, shunted by the capacitor 22, through power rectifier diodes 32, 33.

The second primary winding 26 and the associated magnetically secondary winding (34, 35) are combined by a common magnetic circuit 36, forming another separate power transformer (second). The secondary winding of the second transformer is connected to the load 21, shunted by the capacitor 22, through power rectifier diodes 37, 38.

The principle of operation of the third variant of the circuit fully coincides with the principle of operation of the circuits shown in figures 1, 2.

When current is transferred by the secondary windings of two transformers through rectifier diodes to the common load, the instantaneous voltage values on these windings differ by the difference in voltage drops across the rectifier diodes, i.e. insignificant in comparison with the voltage at the load. Therefore, with a slight error, we can assume that the instantaneous voltage values on the secondary windings of the two transformers are the same. With the same transformation ratios of the first and second transformers, the voltages transformed into the first and second primary windings will be the same. The need for the equality of these stresses to achieve a positive effect from the application of the proposed technical solutions has already been considered.

The positive qualities of the proposed device are preserved if the secondary winding, with which the first and second primary windings are magnetically connected, is directly connected to the load. In this case, energy is transferred to the load by alternating current. An example of a circuit with a direct connection of the secondary winding to the load is presented in figure 4. A positive quality of this embodiment of the device is the simplicity of ensuring the symmetry of the first and second two-terminal devices. For this it is enough that the number of turns of the primary windings 18 and 26, united by a common magnetic core 27, are equal, as well as the same number of turns of the windings 17 and 25, which are combined by a common magnetic circuit 28.

The positive qualities of the proposed device are preserved if the secondary winding (for example, 29), with which the first primary winding 18 is magnetically coupled, connected to it by a common magnetic circuit 31, and also the secondary winding (for example, 34), with which the first primary winding 26 is magnetically connected combined with it a common magnetic circuit 36, are connected to the load directly. In this case, energy is transferred to the load by alternating current by two transformers in parallel. An example of a circuit with direct connection of the secondary windings of two transformers to the load is presented in Fig.5. A positive quality of this variant of the circuit is the simplicity of ensuring the symmetry of the first and second two-terminal devices. For this, it is enough that both power transformers would be identical in design, and also the number of turns of the windings 17 and 25, which are combined by a common magnetic circuit 28, be equal.

A converter whose operation principle is based on the use of resonant processes in an LC circuit when switching the current of this circuit by power transistors of a bridge circuit is characterized by the accumulation of significant energy at the end of each clock cycle in the magnetic field created by the LC circuit current flowing through windings 17 and 25 This circumstance makes it possible and expedient to introduce an additional capacitor circuit, made, for example, in the form of a capacitor, which shunts the output circuit of a bridge transistor circuit. The recharging of the capacitor of this circuit in each cycle is carried out in the same way as the recharging of the capacitance of power transistors (see the text of the description, p. 3-4). The difference is that a large amount of energy is spent for recharging (a sufficient portion of it is stored in the magnetic field, which is created by the current of the windings 17 and 25), and the recharging process is longer.

During the recharge, the power transistors must be in a non-conductive state, which means the need to increase the "technological" delay between the end of the control pulses in the previous cycle and their appearance in this cycle. Unlocking of the transistors by the control signal should not occur until the process of recharging the capacitor shunting the output circuit of the transistor bridge circuit is completed. This means that transistors, which in the next cycle must be in a state of conduction, must have time to switch to the state of inverse conduction before, passing the current of the LC circuit "remaining from the previous cycle" (see the description text, page 3, 4) . “Premature” unlocking of transistors by a control signal will be accompanied by significant surges of their currents and an increase in heat loss power.

By introducing an additional capacitor circuit, a decrease in the slew rate of the voltage across the power transistors is achieved during their locking. This allows you to reduce the switching heat loss in the transistors when locking, which increases the reliability of their work. In addition, a decrease in the rate of increase in voltage in the primary circuit of the converter helps to reduce the level of interference arising during switching times.

The use of capacitor circuits is possible in any of the schemes considered.

As an embodiment of the capacitor circuit, there may be shunting by the capacitors of the output circuits of each of the power transistors of the bridge circuit.

An example of the use of a capacitor circuit in the form of a capacitor shunting the output circuit of a bridge circuit formed by power transistors is shown in FIG. 6.

In the circuit of FIG. 6, a capacitor 39 is connected between the terminals 8 and 9 of a bridge circuit formed by power transistors.

An example of the use of a capacitor circuit in the form of capacitors shunting the output circuits of power transistors is presented in Fig.7.

In the circuit of FIG. 7, a capacitor 40, 41, 42, and 43 shunts the output circuits of power transistors 4, 5, 6, and 7, respectively ..

Claims (12)

1. A push-pull converter containing power controlled keys connected in a bridge circuit, the input circuit of which is connected to the power buses, and the circuit formed in series by the first winding of the magnetic energy storage device, a capacitor and the first primary winding, which is magnetically connected to the secondary winding connected to load, characterized in that the diode bridge circuit, the second winding of the magnetic storage device and the second primary winding, which is magnetically connected to the secondary winding connected to the load, the first and second terminals of the input circuit of the diode bridge circuit are connected respectively to the first and second terminals of the capacitor, and the outputs of the output circuit of the diode bridge circuit are connected to the power buses of the device, the first output of the output circuit of the bridge circuit formed by power controlled keys is connected to the first terminal capacitor through the first bipolar, formed in series by the first winding of the magnetic storage device and the primary winding, which is magnetically connected to the secondary winding connected to the load, the second output of the output circuit of the bridge circuit formed by power controlled keys is connected to the second output of the capacitor through a second two-terminal circuit, formed in series by a second winding of the magnetic storage device and another primary winding, which is magnetically connected to the secondary winding connected to the load, and in series circuit formed by the first two-terminal, capacitor and second two-terminal, the first and second primary windings are connected according to. 2. The push-pull converter according to claim 1, characterized in that the first winding of the magnetic storage device and the second winding of the magnetic storage device are not magnetically connected. 3. The push-pull converter according to claim 1, characterized in that the first winding of the magnetic storage device and the second winding of the magnetic storage device are combined by a common magnetic circuit, i.e. magnetically connected, and these windings in a series circuit formed by the first two-terminal, capacitor and second two-terminal, are connected according to. 4. The push-pull converter according to claim 1, or 2, or 3, characterized in that the primary windings magnetically connected to the secondary winding connected to the load are combined by a common magnetic circuit on which this secondary winding is placed, and all of the listed windings together with the magnetic circuit form a single transformer. 5. The push-pull converter according to claim 1, or 2, or 3, characterized in that each primary winding and the secondary winding associated with it magnetically correspond to a separate magnetic circuit, which together with the windings placed on it, forms a separate transformer. 6. The push-pull converter according to claim 4, characterized in that the secondary winding magnetically coupled to the first and second primary windings is connected to a DC load shunted by the filter capacitor through a rectifier. 7. The push-pull converter according to claim 4, characterized in that the secondary winding magnetically coupled to the first and second primary windings is connected directly to the AC load. 8. The push-pull converter according to claim 5, characterized in that each secondary winding magnetically connected to the corresponding primary winding is connected to a DC load shunted by the filter capacitor through a separate rectifier. 9. The push-pull converter according to claim 5, characterized in that the secondary windings belonging to different transformers are connected to the AC load in parallel. 10. The push-pull converter according to claim 1, characterized in that, in order to increase the energy efficiency of energy conversion and increase the reliability of the power controlled keys, the output circuit of the bridge circuit formed by these keys is shunted by an additional capacitor circuit. 11. The push-pull converter according to claim 10, characterized in that the additional capacitor circuit is made in the form of a capacitor. 12. The push-pull converter according to claim 10, characterized in that the additional capacitor circuit contains four capacitors, each of which shunts the output circuit of the corresponding controlled power switch of the bridge circuit.

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