RU2577535C1 - Phase-shifting inverting converter - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: phase-shifting inverter converter containing drive and driven half-bridge inverters, a transformer comprises throttle saturation, which is connected in series with transformer primary, thus forming a series circuit connected between outputs of the driving and driven half-bridge inverters, the first serial oscillating circuit consisting of first vessel and the first choke coil connected to the output of the driving half-bridge inverter, the throttle saturation can be connected to the output of the driving half-bridge inverter and primary winding of transformer is connected to the output of the driven half-bridge inverter or throttle saturation can be connected to the output of the driven half-bridge inverter and primary winding of transformer is connected to the output of the driving half-bridge inverter.

EFFECT: invention relates to converting equipment and can be used, in particular, to create power sources with high output power, low losses and improved parameters of electromagnetic compatibility.

7 cl, 3 dwg

Description

The present invention relates to a conversion technique and can be used, in particular, to create power sources with increased output power, low losses and improved parameters of electromagnetic compatibility.

The proposed scheme is a type of bridge circuit with a phase shift.

From the existing level of technology, a bridge circuit with a phase shift is known (Patent US 4,864,479, publ. 05.09.1989). The circuit shown in FIG. 1 of US patent 4,864,479, contains an input bridge converter (power inverter), consisting of a master and a slave half-bridge, a transformer, a rectifier and an output filter. The output voltage is controlled by a change in the phase shift between the master and slave half-bridges. To reduce dynamic losses, spurious output capacitances PC1-PC4 of power transistors S1-S4 are used, as well as parasitic diodes PD1-PD4, as well as transformer leakage inductance. During pauses between the conduction intervals of the upper and lower keys, a quasi-resonant process occurs in the oscillatory circuit formed by the output capacitances of the keys and the transformer inductance. Due to this, the inclusion of transistors occurs at voltages close to zero, and a significant reduction in the power of dynamic losses.

In the Application Guide for SLUP101 [Andreycak B. Designing a Phase Shifted, Zero Voltage Transition (ZVT), Texas Instruments Literature No. SLUP101 - Unitrode Power Supply Design Seminar SEM-900 topic 3, 1993] the following features of the phase-shifted bridge circuit are noted:

1. An increase in dynamic losses in the low-load mode, since the energy accumulated by the dissipation inductance of the transformer must ensure that the output capacitances of the keys are recharged during a pause between conduction intervals.

2. Transients leading to switching at zero voltage are different for the master and slave half-bridge.

3. In addition, it follows from the timing diagrams that during the pause interval both rectifier diodes conduct current. Thus, the energy stored by the leakage inductance during the conduction interval is expended in maintaining the load current. The consequence of this is a violation of the switching conditions at zero voltage with a decrease in the phase angle (duty cycle) in the regulation process.

To overcome these shortcomings, a number of solutions are proposed.

The above SLUP101 manual proposes the installation of an additional inductor in series with the primary winding of the transformer and provides recommendations for calculating its rating. However, this solution does not provide switching at zero voltage in the "idle" mode and at very low load. In addition, an increase in the inductance rating limits the possibility of increasing the operating frequency and output power of the converter.

Known solutions based on the use of an electromagnetic unit with two transformers (RF patent No. 2421869, publ. 06/20/2011, RF patent No. 2316884, publ. 02/10/2008, US patent 5,875,103, publ. 23.02.1999).

The proposed solutions ensure the fulfillment of soft switching conditions when the load current changes from 0% to 100%, as well as the phase angle from 0% to 100%. However, the asymmetrical mode of operation of transformers in the electromagnetic unit requires the use of magnetic cores with non-magnetic gaps. Moreover, to achieve the required values of the input inductance, a significant increase in the number of turns in the transformer windings is required, which leads to an increase in losses in the windings, as well as an increase in the area of the winding window. In addition, the proposed circuit does not allow you to adjust the output voltage in the direction of reduction to zero values. The foregoing is due to the fact that the operating current, which serves to ensure a mild operating mode, is transformed into secondary circuits, thereby creating additional voltage on the load.

In the publication, Mecke N., Fischer W., Werter F. Soft switching inverter power source for arc welding. EPE′97 Conf. 1997. Trondheim. PP 4333-4337 proposed and described a welding inverter circuit based on a bridge circuit with a phase shift. A feature of the circuit is a special control algorithm in which the transistors of the leading half-bridge switch at zero voltage, and the slave - at zero current. In addition, a non-linear saturable inductor is installed in series with the primary winding of the transformer. In a saturated state, the inductor has an inductance close to zero, thereby not affecting the functioning of the power circuit. When changing the polarity of the current flowing in the primary circuit, the inductor briefly leaves saturation mode. This ensures the formation of a time interval during which the current in the primary winding of the transformer is close to zero and does not affect the processes of recharging the output capacities of the keys of the master and slave half-bridges. The scheme has the following disadvantages:

1. The complexity of the key management scheme of the slave half-bridge.

2. With a very small load and (or) a small angle of the phase shift, the keys of the leading half-bridge are not switched at zero voltage. The presence of additional capacities connected in parallel with the keys of the leading half-bridge leads in this case to the appearance of additional dynamic losses.

The closest analogue is the solution described in US 5,875,103 (a variant of the circuit depicted in Fig. 9 of US patent 5,875,103).

This device contains two inverters - master (200 ′) and slave (300 ′), which are connected in parallel at the power inputs. High-frequency transformer 900 is connected to the inverter AC outputs. In addition, inductors 24 and 34 are connected to the AC outputs parallel to the transformer, one for each inverter, which are connected by other terminals. The capacitive divider 400 ′ consists of two capacitors connected to the connection point of the inductors, as well as the positive and negative power buses, respectively. The alternating current flowing through the inductors 24 and 34 creates an additional reactive load on the inverters 200 ′ and 300 ′, respectively, ensuring that the power switches are turned on at zero voltage in the low load and idle mode, as well as at a small phase shift angle.

However, the prototype has several disadvantages:

1. The asymmetric operation of the inverters 200 ′ and 300 ′ leads to the appearance of a constant component of the voltage at the inductors 24 and 34, the consequence of which is their one-sided magnetization through current, and the asymmetric operation of the upper and lower switches. The consequence of this may be the loss of the switching mode at zero voltage and an increase in dynamic losses.

2. During transients, the slave inverter 300 ′ provides an unbalanced mode of operation, which leads to one-sided magnetization of the inductance 34.

The basis of the claimed invention is the task of providing a switch-on mode at zero voltage, including under conditions of unstable load and changing power parameters, eliminating the influence of asymmetric operation of inverters on switch-on mode at zero voltage, and providing switching mode at zero voltage as when changing load from idle mode stroke to the nominal value, and when changing the phase shift angle from 0 ° to 180 °.

The technical result is achieved in that the phase shifting inverter containing the master and slave half-bridge inverters, a transformer, is characterized in that it contains a saturation choke that is connected in series with the primary winding of the transformer, forming a serial circuit connected between the outputs of the master and slave half-bridge inverters, the first serial an oscillatory circuit consisting of a first capacitance and a first inductor connected to the output of the leading half-bridge inverter, m the saturation reactor can be connected to the output of the leading half-bridge inverter, and the primary winding of the transformer is connected to the output of the slave half-bridge inverter, or the saturation reactor can be connected to the output of the driven half-bridge inverter, and the primary winding of the transformer is connected to the output of the leading half-bridge inverter.

In FIG. 1 of the claimed invention, an embodiment of a phase-shifting inverter converter is shown, which comprises a master and a slave half-bridge inverters, a transformer Tr1, the primary winding of which on one side is connected in series with the saturation reactor DrN. The saturation inductor DrN at the other end of the winding is connected to the output of the slave half-bridge inverter, and the primary winding of the transformer Tr1 is connected to the output of the leading half-bridge inverter, which also connects the first inductor Dr1, which forms the first sequential oscillatory circuit together with the first capacitance C1. As an embodiment, the first additional capacitor Сд1 can be connected to the connection of the first inductor Др1 with the first capacitor С1, which forms the first capacitive divider with the first capacitor С1, and in this case the first inductor Др1 is connected to the first capacitive divider С1-Сд1. Connecting an additional capacitance Сд1 allows improving the starting characteristics of the leading half-bridge inverter. That is, in this design, the slave half-bridge inverter does not contain auxiliary circuits. In addition, it does not contain additional capacities, except for stray output key capacities. The option is justified by the fact that the saturation reactor ДРН enables the transistors of the slave half-bridge inverter to be switched on at zero current. This option does not allow to exclude dynamic losses when turning off the transistors of the driven half-bridge inverter, however, it has a minimum number of power circuit elements.

In FIG. 2 shows an embodiment of a phase shifting inverter converter. In this design, a second sequential oscillatory circuit consisting of a second inductor Dr2 and a second capacitor C2 is connected to the output of the driven half-bridge inverter. An embodiment may be connecting a second additional capacitance Sd2 to the connection point of the second inductor Dr2 with the second capacity C2 to create a second capacitive divider C2-Sd2. The second sequential oscillatory circuit eliminates dynamic losses when the transistors of the slave half-bridge inverter are turned off, and the second additional capacitance Sd2 is connected to improve the launch of the slave half-bridge inverter.

In FIG. 3 shows an embodiment of a phase shifting inverter converter. The first choke Dr1 and the second Dr2 are connected to the AC outputs of the master and slave half-bridge inverters, respectively. Unlike the prototype, they do not have a common connection point, thereby providing separate and independent loads for the master and slave half-bridge inverters. The first capacitor C1 or the first capacitive divider C1-Cd1 is connected to the opposite end of the first inductor Dr1. The calculation of the parameters of the elements is carried out in such a way that the current flowing through the first inductor Dr1 provides a recharge of the output capacitances of the keys during the switching intervals, while at the same time not leading to a significant increase in static losses. The difference between the slave half-bridge inverter is that during transients and during adjustment, its keys operate with a variable duty cycle. Recharging the capacities of the slave half-bridge inverter can lead to a temporary violation, and in the case of unstable load, to the loss of soft switching mode. To overcome this drawback, the second inductor Dr2 and the second C2 form a second sequential oscillatory circuit, the values of which are selected so that its resonant frequency exceeds the operating frequency of the phase-shifting inverter converter, and the voltage swing across the first capacitor C1 and the second capacitor C2 is close to the supply voltage.

An operation mode of the phase-shifting inverter converter is possible, in which the second sequential oscillatory circuit resonates with the operating frequency of the phase-shifting inverter, resulting in the possibility of unlimited voltage growth with the possibility of breakdown of the elements of the phase-shifting inverter. To prevent such situations, it is advisable to introduce diode limiters D5 and D6 of the amplitude voltage fluctuations into the design - Fig. 3.

The use of these technical solutions guarantees a soft switching mode with a decrease in the output load up to the idle mode, as well as with a decrease in the fill factor, and allows you to create phase-shifting inverter converters in accordance with the task of ensuring the smooth operation of the phase-shifting inverter converter when working with constant load, changing load and abruptly changing load when working with digital modules.

Claims (7)

1. Phase-shifting inverter converter comprising a master and slave half-bridge inverters, a transformer, characterized in that it contains a saturation choke, which is connected in series with the primary winding of the transformer, forming a series circuit connected between the outputs of the master and slave half-bridge inverters, the first series oscillatory circuit consisting of from the first capacitance and the first inductor connected to the output of the leading half-bridge inverter. 2. Phase shifting inverter converter according to claim 1, characterized in that the saturation inductor is connected to the output of the leading half-bridge inverter, and the primary winding of the transformer is connected to the output of the driven half-bridge inverter. 3. Phase shifting inverter converter according to claim 1, characterized in that the saturation inductor is connected to the output of the slave half-bridge inverter, and the primary winding of the transformer is connected to the output of the leading half-bridge inverter. 4. Phase shifting inverter converter according to claim 1, characterized in that the device of the leading half-bridge inverter contains a first additional capacitance connected to the connection of the first capacitance with the first inductor and forming the first capacitive divider. 5. The phase-shifting inverter converter according to claim 1, characterized in that it comprises a second sequential oscillatory circuit consisting of a second capacitance and a second inductor connected to the output of the driven half-bridge inverter. 6. The phase-shifting inverter converter according to claim 1, characterized in that it comprises a second sequential oscillatory circuit, consisting of a second capacitor and a second inductor connected to the output of the driven half-bridge inverter and a second additional capacitor connected to the connection of the second capacitor to the second inductor and forming the second capacitive divider. 7. The phase-shifting inverter converter according to claim 1, characterized in that it contains diode limiters of the amplitude voltage fluctuations.

Images