SU847494A1 - Device for step-wise charging of reservoir capacitor - Google Patents

Description

current inverter with increased supply voltage. This is due to the fact that the moments of the next switching of keys do not depend on the value of the supply voltage, and this leads to a decrease in the efficiency of the device. The purpose of the invention is to increase the efficiency when stabilizing the form of consumed current from the primary power source. The goal is achieved in that the device for step charging of the storage capacitor, containing a current inverter connected to the power source and containing a sensor of the consumed current, parapections of the transformer having K secondary windings To rectification bridges, each of which is connected to the conclusions of the transformer secondary windings of the CTByKMUix, To controlled keys, each of which is connected to one of the outlets One of the corresponding rectifier bridges, K dividing diodes connected in the opposite direction between the corresponding control key and another output of the rectifying bridge, all of the isolating diodes are connected in series with each other in accordance with and parallel to them the storage capacitor and the pulse distributor key control, is provided with a threshold device, the input of which is connected to the output of the current consumption sensor, and the output to the input of the distributor of key control pulses. On (iwr, 1 is a functional diagram of the device proposed; FIG. 2 - voltage plots at its main points. The step-charging device for the storage capacitor consists of a current inverter 1, comprising a zadal generator of current 2, an electric shunt 3 and a power amplifier made of transistors 4 and 5, a step-up transformer 6 having four secondary windings with a different conversion factor, four rectifying bridges and diodes 7-10, 11-14, 15-18, 19-22, transistor switches 23- 26, commutating diodes 27-30, NAC the optional capacitor 31, the distributor 32 of the key control pulses and the threshold device 33. The device operates as follows: The master current generator 2 generates a variable square voltage that is applied to the basics of the transistors 4 and 5, Stabilizing the charging current consumed from the primary source power supplied by a voltage that is removed from the electrical coupling 3 of the feedback and fed to the regulating input of the current source. The process of switching the secondary windings of the step-up transformer is controlled by a pulse distributor 32 using transistor switches 23-26. The operation of the pulse distributor 32 starts at the moment when the storage capacitor 31 is discharged to the load (not shown in Fig. I). or at the time of connecting the device to the primary power source. At the first initial moment of time, the distributor 32 pulses turns on the transistor 26 and taking into account the transformation ratio of the lower second transformer 6 is charged by the storage capacitor 31, wherein the charging current of the secondary circuit of the transformer flows through the rectifying bridge 19-22, the transistor 26, the diodes 29, 28, 27 and the capacitor 31, at the time point at which the voltage storage capacitor is equal to the voltage of the primary power source, taking into account the transformation ratio of the lower secondary winding and taking into account the voltage losses on the elements 4, 5, 6, 19-22, 26, 19-27, the threshold device 33 is triggered, the threshold device is triggered the current consumption from the primary power supply is below the set value due to the transition of the transistors 4 and 5 to the saturation mode, in which they cannot function as a current regulator. A pulse is generated at its output, which is fed to the input of the distributor 32 pulses. When this pulse is applied, the pulse distributor 32 shuts off the transistor 26 and turns on the transistor 25. By turning on the transistor 25, the storage capacitor is charged through another secondary winding of the transformer, through diodes 15-18, transistor 25 and diodes 28, 27, 30. 5847 To provide the required mode The operation of the charge circuit during the second step. The transformation ratio of this winding is usually chosen 2 times larger than the first secondary winding. When the second secondary winding is turned on in the charge circuit, transistors 4 and 5 automatically switch from the Nascene mode to the 4946 current source mode. After the end of the second charge step, in a similar manner, the transistor 26 is additionally turned on, as a result of which simultaneously switching on the two secondary windings of the transformer causes an increase in energy in the storage capacitor. The table shows all stages of the operation of the transistor switches,

A full cycle of charging the storage capacitor consists of 15 steps. As a result of each step of operation of the device, the voltage on the capacitor increases by the same amount, and the duration of each subsequent charge step increases by an amount equal to the duration of the first charge step. FIG. Figure 2 shows the diagrams of voltages and currents of the main points. Plot 34 shows the nature of the voltage change on one of the windings of the downstream transformer 6, on Egnor 35, the current in the circuit of the cumulative booster sensor, and on plot 36, the current in the primary power source circuit. The increase in efficiency when using the invention is ensured by the full use of the output voltage of the converter with all allowable changes in the supply voltage. 7 Invention formula A step-by-step charging accumulator capacitor containing a current inverter connected to a power source and containing a current consumption sensor, a transformer having K secondary windings, K rectifying bridges, each of which is connected to the terminals of the corresponding secondary transformer windings, To controllable keys, each of which is connected to one of the outputs of the corresponding rectifying bridge, to decoupling diodes connected in the opposite direction between the corresponding control key and other output of the rectifying bridge, all of which dissolving 8 48 diodes are connected in series with each other in accordance with and in parallel with them the storage capacitor as well as the key control pulse distributor, characterized in that, in order to stabilize the consumed from the power source of the current, it is provided with a threshold device, the input of which is connected to the output of the sensor of the consumed current, and the output to the input of the distributor of control pulses of the keys. Sources of information taken into account in the examination 1. UK patent number 1.231,500, cl. H 2 H, 1972. 2. US Patent No. 3.750.005, cl. 321-18, 1973.

Claims (1)

Formula of the invention The diodes are interconnected by the following: A device for stepwise charging a storage capacitor, comprising a current inverter connected to a power source ₅ and comprising a current consumption sensor, a step-up transformer having K secondary windings, K rectifier bridges, each of which is connected to the terminals of respective existing secondary windings of the transformer, K controlled keys, each of which is connected to one of the outputs of the corresponding rectifier bridge, K decoupling diodes, 15 included in in the opposite direction between the corresponding controlled key and the other output of the rectifier bridge, and all the decoupling ones are connected according to and parallel to them, an accumulative capacitor is connected, as well as a key management pulse distributor, characterized in that, in order to increase the LSC while stabilizing the current consumed from the power supply, it is equipped with a threshold device, the input of which is connected to the output of the current consumption sensor, and the output to the input of the key control pulse distributor.