SU966829A1 - Controllable power supply source - Google Patents

Description

The invention relates to electrical engineering and can be used to power electrical and radio equipment. A stabilized power supply is known, which contains primary and regulating transformers, the primary windings of which are connected sequentially and the secondary ones are connected to the corresponding rectifiers and the regulating element with the control circuit 11. However, the efficiency of such a device is low, since the compensation of a change in the input voltage over the entire range is due to a change in the voltage drop on the adjustable resistance, which leads to a significant loss of power at this resistance. The device also has high losses in the control transformer and the auxiliary rectifier from the load current, since the resistances of these crossbars are connected in series to the load circuit. Also known is a regulated power source containing a power transformer, the secondary winding of which is connected in series with a power rectifier and filter, an auxiliary transformer, the primary winding of which is connected in series with the primary winding of the power transformer, and an auxiliary rectifier with filter is connected to the secondary winding, one output which is connected to the same output of the power rectifier, and the other is connected through an adjustable resistance connected in series It is connected to another output of the power rectifier, and the controlled input of the adjustable resistance is connected to the output of the control circuit J. n. This device eliminates additional losses from the voltage drop on the secondary resistance of the auxiliary transformer and on the diodes of the auxiliary rectifier,

since in it these circuits are connected via an adjustable resistance parallel to the output of the filter. Therefore, losses in the secondary winding of the auxiliary transformer and in the auxiliary rectifier are compensated in the power circuit, since the current in it is less than the load current by the amount of current flowing through the adjustable resistance. However, the main losses from changes in the supply voltage and load current at an adjustable resistance can be ten times greater than the losses in the windings of the auxiliary transformer and auxiliary rectifier. Therefore, the KPD of the device remains low.

The purpose of the invention is to increase efficiency and improve mass and size indicators.

The goal is achieved by the fact that in a regulated power supply containing a power transformer, to the secondary winding of which a main rectifier and filter are connected, the output of the filter is the output of the power supply, an auxiliary transformer whose primary winding is connected in series with the primary winding of the power transformer, and the secondary winding is connected to an auxiliary rectifier and regulating element consisting of a main adjustable resistance and a control circuit, the output of which is connected There is an additional adjustable resistance and decoupling diodes, the additional adjustable resistance is connected to the output of the auxiliary rectifier, and the controlled input of the additional adjustable resistance is connected to the control input of the adjustable resistance. entered by the second output of the control circuit, the first output of the main regulated resistance is connected to one output of the main rectifier, and its second output is connected to the same combined leads of the isolating diodes, the other outputs of which are connected to the corresponding outputs of the secondary winding of the auxiliary transformer.

In addition, other outputs of the decoupling diodes are connected to the input secondary taps of the auxiliary transformer.

FIG. 1 is a schematic diagram of the device; in fig. 2 is a diagram of the device when performing an auxiliary transformer with taps.

The device (Fig. 1) contains a power transformer 1, the secondary winding of which is connected to the input of the main rectifier, 2, the output of which is connected to the input of the filter 3. The output of the filter 3 is the output of the device. The primary winding of the auxiliary transformer 4 is connected in series with the primary winding of the transformer 1,

o the secondary winding of which is connected to the input of the auxiliary rectifier 5, to the output of which an additional adjustable resistance is connected. 6. One of the outputs of the main rectifier 5 of the body 2 is connected to the output of the main adjustable resistance 7, the other output of which is connected to the same output terminals of the power supply diodes 8, 9 whose other outputs are connected to the output

0 will give the secondary winding of the auxiliary transformer 4.

The controlled inputs of the main adjustable resistance 7 and the additional adjustable resistance 6 are connected to the corresponding output of the control circuit 10, the input of which is connected to one of the terminals of the device.

Instead of isolating diodes 8, 9, one isolating diode can be used. 11, but at the same time, the efficiency of the device decreases because of the additional losses in the auxiliary rectifier circuit 5.

The designations of the elements in FIG. 2 with. correspond to FIG. 1, but decoupling diodes 8 and 9 are connected to the secondary branches of the transformer.

The device works as follows.

The signal from the output of the device is fed to the input of the control circuit 10, which controls the state of the adjustable resistances 6, 7, thereby ensuring the operating mode of the transformer 4 necessary to maintain a predetermined voltage value at the output of the device.

Claims (2)

When the supply voltage and load currents are close to the nominal, the value of the additional adjustable resistance 6 is close to infinity, the secondary winding current of the auxiliary transformer 4 flows through the auxiliary rectifier 5, decoupling diode 11, the main adjustable resistance 7, filter 3 and the load connected to the output of the device. In this case, the magnitude of the main adjustable resistance 7 is close to zero, i.e., the rectifiers 2 and 5 are connected in parallel and their entire output voltage is given to the load, therefore, the CP / J of the device in this mode is maximum. When the network voltage rises, the control circuit Yu increases the value of the main adjustable resistance 7, at which the voltage drops from the auxiliary rectifier 5 current. When the network voltage is equal to the maximum allowable, the additional power coming from the auxiliary transformer 4 into the circuit, divided equally between the load and the main adjustable resistance 7. When the voltage is lower than the nominal, the value of the main adjustable resistance 7 is zero and the control circuit is 10 compresses the value of the additional adjustable resistance 6, which, at the lowest possible input voltage, becomes equal to zero. Auxiliary transformer 4 is short-circuited, there is no PS in it, and the efficiency of the stabilized rectifier is maximum. In this mode of operation of the device, the voltage on the code of the auxiliary rectifier 5 becomes less than the voltage at the output of the main rectifier 2 and in order for the current to pass. Through the main adjustable resistance 7 from the main rectifier 2 does not flow through the additional regulated resistance 6 The device has introduced a decoupling diode 11 (or decoupling diodes 8, 9). Thus, the maximum losses in the regulated resistances 6 and 7 are not determined by the entire range of variation of the supply voltage, but only half of this range, and the device efficiency becomes maximum h, approaching the efficiency of the unregulated device at both the minimum and nominal value supply voltage values. The principle of operation of the circuit in FIG. 2 is no different from the operation of the circuit of FIG. 1. The above connection of the power supply diodes 8 and 9 to the secondary leads of the transformer 4 allows the transformer ratio of this transformer to be chosen freely and, thus, to provide the optimum voltage range. on an additional adjustable resistance 6 or to choose the optimal range of currents flowing through it, which allows the best way to use the element that works 5 29. 6 as an additional adjustable resistance 6 on current and voltage. Using as an additional adjustable resistance of power elements, for example, transistors in the optimal mode, allows, on the one hand, to fully use the installed power of these elements, i.e., remove the weight and dimensions of the device, on the other hand to increase its efficiency, especially at low output voltages. The increase in efficiency in these cases is due to the fact that the voltage drop across the primary winding of the auxiliary transformer is reduced with a fully saturated adjustable transistor acting as an additional adjustable resistance. Claim 1. Adjustable power supply containing a power transformer, the secondary winding of which is connected to the main rectifier and filter, filter output is the output of the power supply, an auxiliary transformer, the primary winding of which is connected in series with the primary winding of the power transformer, and the secondary winding is connected to the secondary the rectifier and the regulating element consisting of the main adjustable resistance and the control circuit, which is connected to the control an adjustable resistance input, characterized in that, in order to increase efficiency and improve weight and size parameters, additional adjustable resistance and isolating diodes are introduced, while additional adjustable resistance is connected to the output of the auxiliary rectifier, and control input of additional adjustable resistance is connected to the input secondary 1M control circuit output, the first output of the main adjustable resistance is connected to one output of the main rectifier, and the second of its output One is connected to the same combined leads of the power supply diodes, the other leads of which are connected to the corresponding leads of the secondary winding of the auxiliary transformer. 2. The power supply of claim 1, wherein the other transceiver diodes are connected to 7 966829.8 introduced secondary taps1. USSR author's certificate auxiliary transformer. № 418840, class. G 05 F 1/32, 1972. Sources of information, 2, USSR Copyright Certificate taken into account in the examination of Mb 687546, nod. H 02 M 7/12, 1977. with “o t // ±