RU2404439C1 - Two-stage electronic load - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: first stage of the electronic non-scattering load is made based on a transformer converter controlled with direct current with a choke at the input. The device employs an auxiliary converter which is connected through a bridge rectifier to the mains in order to provide initial charge of a storage capacitor, upon achievement of which a controller connected to the primary side of the control system begins to switch transistors of the first stage with shutoff, thereby increasing voltage across the storage capacitor to a given level. After that the controller transmits a sinusoidal reference signal to the secondary side and switches on primary and secondary power parts of the electronic non-scattering load.

EFFECT: high efficiency of the electronic non-scattering load, smaller dimensions, low cost of input filter, easier transmission of instructions from the controller, faster control during non-standard situations.

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Description

The invention relates to the field of converting technology, in particular to devices that allow loading various converters with direct current output, rechargeable batteries, direct current generators during various types of tests, including resource tests.

It is known that lengthy tests of electric power sources are carried out by connecting the source to a resistive load, which leads to a large and almost useless power consumption, and is also associated with technical difficulties in removing large heat power from the loads and, ultimately, entails financial losses for the enterprise, producing similar products. Therefore, electronic non-dissipative loads (ENN) are being developed, which can significantly (4 ... 6 times) reduce energy consumption during testing.

In [1], a test of a transistor rectifier is described, in which it is loaded on an inverter of the same power, and in order to save energy consumed during testing, an additional transistor rectifier is connected to the AC mains, the output power of which should cover the losses in the tested converter and in the inverter . The disadvantages of this device are the need to use two additional converters (inverter and additional transistor rectifier), the complexity and inefficiency of the test, because there is no controller that performs control and protective functions.

[2] described the technical solutions of two- and three-stage power transformers, which transmit energy to an alternating current network, however, the construction of the first stage associated with the output of the tested converter does not provide an increased power transformer efficiency, and the dimensions of the input filter turn out to be unacceptably large.

Closest to the proposed invention, the technical solution known to the authors for the totality of signs is the ENN, which is described in [3]. The ENN contains several stages of the power part, the first is connected to the device under test, the second provides galvanic isolation between the DC input and the network, and the third, based on the low-frequency inverter, transfers power from the device under test to the network. The disadvantages of this device are a three-stage structure, which causes insufficiently high efficiency, as well as limited control capabilities associated with the use of a digital controller on the secondary side of the power inverter, galvanically connected to the network.

The technical result of the invention is a significant increase in the efficiency of the power inverter, reducing the size and cost of the input filter, achieved by the fact that the first stage is based on a transformer converter controlled by a current with a choke at the input, an auxiliary converter connected through a bridge rectifier to the network to provide an initial charge is introduced storage capacitor, and the controller in the control system connected to the primary side of the system to send commands to the PWM controller and drivers of the DC-DC converter, which switches the first-stage transistors with overlapping, increasing the voltage on the storage capacitor to a predetermined level, after which the controller transmits a sinusoidal reference signal to the secondary side and turns on both the primary and secondary sides of the power part of the power supply.

In Fig.1 shows a General diagram of the connection of the ENN to the tested Converter (IP) and AC power. Figure 2 shows the structural diagram of the ENN. In Fig. 3 shows a diagram of the power part of the ENN. Figure 4 shows the structure of the control system. Figure 5 shows a diagram of the switching keys of the first stage of the ENN.

In figure 1 is indicated:

i _network , i _un , i _ann - the current taken from the network, the input current of the IP and the output current of the AIN

respectively.

_Network current i equal to the difference of currents i and i _{Ann un} and is small compared with the current i _u is consumed only in the loss of coating SP 2 and 3. The more ANN ANN efficiency, the smaller the current will be selected by the network 1, the less power consumption during the test.

The ENI can be performed according to a two- or three-stage structure [2, 3], and with the improvement of transistors and, in particular, an increase in the speed of IGBT transistors, the two-stage structure shown in FIG. 2 is preferable.

The proposed ENN contains a transformer converter with a choke at the input, controlled by current, in the first stage 4 and a high-frequency inverter 6 in the second (figure 2). In addition, in the diagram (Fig. 3) there is an auxiliary converter 10 and a control device 7. The auxiliary converter is designed, firstly, to obtain the voltages supplying the control device, and secondly, to create the initial charge of the output capacitor 5 of the transformer converter 4 with throttle inlet. The use of a transformer converter with a choke at the input in the first stage at low input voltage levels (20 ... 100 V) can significantly reduce losses in this cascade compared to any other circuit. It is assumed that the transistors and output diodes of the same types are used, the material of the transformer cores and the current density in the windings are the same. In addition, the input choke in the transformer converter reduces the ripple of the input current, which reduces the size and cost of the input filter and to achieve the minimum value of psophometric noise.

The control system 7 is disclosed in figure 4. It consists of two galvanically isolated parts: the primary and secondary sides of control. On the primary side are the key management drivers for the DC-DC converter 29, the PWM controller of this converter 30 and the digital controller 31. On the secondary side are the drivers for controlling the inverter keys 36, the inverter key management logic block 35, the PWM controller of the inverter 34, the transition determination unit mains voltage through zero 33 and a signal filter 32, eliminating distortion of the mains voltage.

The device operates as follows. After connecting the ENN to the output of the device under test (voltage Uin, Fig. 3 is applied) and connecting to an alternating current network (U network), the rectified voltage through the bridge rectifier 9 is supplied to the auxiliary converter 10.

This converter generates several DC voltages supplied to the primary and secondary sides of the control device for the operation of analog and digital nodes. In addition, the converter provides a preliminary charge of the storage capacitor 5 connected to the output of the transformer converter 4 with a choke at the input to the voltage amplitude of the network (at a nominal voltage value of 220 V the amplitude value is 311 V). The pre-charge of the capacitor 5 is made through the charging resistor 11. After the pre-charge is completed, this resistor is bridged by the contacts of the relay 12 according to the signal from the controller 31 located on the primary side of the control device (Fig. 4).

In this state, the power switches of the transformer converter with a choke at the input 4 and inverter 6 are locked and no energy is supplied from the power supply to the device under test. After receiving a signal by the controller 31 about the completion of the preliminary charge of the capacitor 5, the controller controls the keys 13 ... 16 of the transformer converter 4 with a choke at the input. These keys work with overlapping, that is, there is a time interval when the keys of two racks (13, 14 and 15, 16) are in an open (conductive) state, as shown in Fig. 5 (a rack refers to two bridge transistors vertically located on circuit, for example, transistors 13, 14). Therefore, when the keys of two racks are open, current flows through the input choke 17 and the current sensor DT1 18, the voltage on the transformer windings is zero and energy is not transmitted to the secondary side of the transformer. In another interval of the switching period, the keys (13, 16 or 14, 15) diagonally located on the circuit and the energy from the source under test, the inductor 17 through the primary winding 20 of the transformer 19, the secondary winding 21 and the rectifier bridge 22 are fed to the charge of the capacitor 5. the voltage on this capacitor reaches the set value (400 V), the signal "Set input current" (Svht), which is supplied to the primary side of the control device 7, sets the required current, which must be taken from the tested device. Upon receipt of the Zvht signal by the controller 31, the latter, using the PWM controller 30 and the drivers 29 located on the primary side of the control device 7, sets the required duty cycle of the keys 13 ... 16 of the bridge. At the same time, on the secondary side of the control device 7, a sinusoidal signal is received from the controller, which is close in shape to the rectified voltage of the network and is phased with the network using block 33, which determines the transition of the network voltage through zero. This signal is fed to the PWM controller 34 of the inverter 6 and is intended to specify a sinusoidal current at the output of the power supply. The second stage (inverter) begins to work in the diagonal of the bridge on the keys 23 ... 26, which includes the current sensor DT2 27, inductor 28, input DUT and network 1, an alternating current is supplied, the phase of which coincides with the phase of the network. The keys of the inverter bridge 23 ... 26 work in such a way that the higher the voltage on the capacitor 5, the more the current leaves the AIN 3. One rack of keys of the inverter bridge (for example, keys 23, 24) switches with the mains frequency. In each half-period of the network, in the mode of pulse-width modulation at high frequency, only one transistor of the right rack operates, and the PWM period is divided into two intervals - pulse and pause. In the pulse interval, one transistor of the right rack is turned on, and in the interval of a pause, both transistors of the same rack are turned off.

Literature

1. Yu.S. Cherkashin, A.I. Zubov. “Energy recovery during testing of electrical equipment in the process of its manufacture”, Electricity, No. 3, 2007, pp. 56-58.

2. R.P. Rudzenskas, M.M. Tanaev, V.I. Meleshin. "Principles of building an electronic non-dissipative load." Electrical Engineering, No. 3, 1998, pp. 28-32.

3. V.I. Meleshin. "Transistor Converter Technology", Publishing House "Technosphere", 2005, 632 p.

Claims (1)

An electronic two-stage non-dissipative load (ENN), the power part of which consists of a first stage in the form of a DC-DC converter connected to the output of the tested converter by its input and a second stage in the form of an inverter that transfers energy to the input of the tested converter or to an alternating current main, the output of the first stage has a storage capacitor, both stages are controlled from the control system, characterized in that the first stage is based on a transformer converter controlled by current, with a choke at the input, an auxiliary converter is introduced, connected through a bridge rectifier to the network to provide the initial charge of the storage capacitor, and a controller in the control system connected to the primary side of the control system to send commands from it to the PWM controller and DC-DC drivers a converter that switches the first stage transistors with overlapping, increasing the voltage at the storage capacitor to a predetermined level, after which the controller transmits a sinusoidal signal to the secondary side The primary reference signal also includes both the primary and secondary sides of the power part of the ENI.

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