SU1023644A1 - Controllable pulse converter - Google Patents

Abstract

A CONTROLLED PULSE CONVERTER containing a hot capacitor connected via a direct conductive diode and charge circuit to the source of input pulses, a discharge circuit connected to a storage capacitor through a reverse conductive diode, characterized in that in order to extend the dynamic range in duration convertible pulses / d-1 storage capacitors, and key elements, and integrating circuits are inserted into it, while storage capacitors are connected in cascade and connected via Corresponding to the common busbar, to the connection point of the storage capacitors and the key elements, a potential power supply bus is connected via the reset button, controlling the inputs of the key elements to the source of the input pulses through the corresponding integrating elements.

Description

The invention relates to the field of pulsed technology and can be used in devices that delay input pulses by U time, which depends on the duration of the input pulse, for example, in a time relay. Devices are known that use the charge of a capacitor from a power source for the duration of the input pulse. The closest in technical essence to the proposed is a pulse device containing a storage capacitor, a capacitor charge circuit consisting of a resistor and a diode, a capacitor discharge circuit consisting of a transistor switch, an operational amplifier with a gain equal to one. wives The device is fed with rectangular pulses whose frequency is constant. At the output of the device, square-wave pulses have a saw-tooth shape. The disadvantages of the device include the absence of an automatic change in the essential storage capacity with a varying duration of the input pulses; the impossibility of the device operating at a varying frequency of the input pulses, i.e. operation at a fixed frequency. The purpose of the invention is to expand the dynamic range in terms of the long-term convertible pulses by. ensuring a valid ratio of the duration of the input pulse to the duration of the charging capacitor capacitance when the duration of the input pulses varies. To achieve the specified deli in a controlled converter power. containing a storage capacitor connected via a diode c. direct conduction and charge circuit to the source of input pulses, a discharge circuit connected to the storage capacitor through a diode in reverse conduction, n-1 storage capacitors, h key: input elements, to integrating circuits are introduced, and storage capacitors the corresponding key elements are connected in cascade and connected to the common bus; to the connection point of the storage capacitors and key elements: through the reset button, the potential power supply bus is connected; ments connected to a source of input pulses through the respective integrating elements. The drawing shows an electrical schematic diagram of the device. The controlled pulse converter contains a capacitor charge circuit, consisting of a resistor 1, an adjustable resistor 2 and a diode 3, a discharge circuit consisting of a resistor. 4, the transistor 5 and the diode b, the first key having a resistor 7, a capacitor 8, which form the time -. the master circuit of the key. and the thyristor 9, the first storage capacitor 10,. the resistor 11 and the LED 12 are included in the anode circuit of the first key, the LED-13, the reset button 14 and the resistor 15 included in the anode circuit of the second key, the second storage capacitor 16, the key containing the thyristor 17, the resistor .1-8 and the capacitor 19, forming the time specifying the chain of the second key. . The converter works as follows. In the absence of input rectangular pulses, transistor 5, thyristors 9 and 17 close. The charge on the storage capacitors 10 and 16. is absent, because the charge circuit of these capacitors is broken. ; . When a series of square-wave pulses is input to the device, then the first pulse from this series is opened by thyristor 9, so. as the charge of the capacitor 8 connected to the control electrode of the thyristor 9 is less than the charge time of the capacitor 19 of the second switch. This means that the length of the first pulse is a prerequisite in order to connect this or that key or sub-. turn them all on at the same time. After opening the thyristor 9, start the charge of the capacitor 10., along the circuit: resistor 1, variable resistor 2, diode 3, capacitor 10, thyristor 9, common potential bus. But since the charge of the capacitor 10 began not from the moment of the filing of the positive-im-. pulse, and ino after some time after its arrival, then the storage capacitor 10 will charge partially. During a pause, the capacitor 10 is discharged along the circuit; d.od b, transistor 5, resistor .4, common potential bus, thyristor 9.. The capacitors 8 and 19 of the charging time of both switches are also discharged through resistors 7 and 18, respectively. The thyristor 9 is in the open state because its anode is connected through a resistor 1.1, an LED 12 and a reset button 14 to a positive potential of the power source. Glow LED. 12 indicates the open state of the key. It turns out that the first pulse of the series brings the converter to the working state and at the device output this pulse has an underestimated amplitude level.

The second and subsequent rectangular input pulses are converted into exponential pulses. In the absence of input pulses, the converter leads to the initial state by pressing the reset button 14. If pulses with a longer duration arrive at the device input, the first pulse again automatically brings the device into a working state, opening the keys on the thyristors 9 and 17, since during this period capacitors 8 and 19 have time to charge to the potential ensuring the opening of these thyristors. With this connection, 15 parallel capacitors 10 and 16 and the total storage capacitance increase and equal to the sum of the indicated capacitors. The first output pulse has a low level of c1 amplitude. oQ From subsequent pulses, the device operates in the same way as in the case of connecting one storage capacitor. The converter may contain and -th number of stages, storage capacitors connected automatically depending on the duration of the input pulse. In this case, the storage capacitors and resistors in the charge circuit are selected so that the ratio of the duration of the input pulse to the charge time of the capacitors is constant. With the help of such a converter, it is possible to shift the input pulses by the same value, taking into account their duration.

The use of the invention will allow the application of a converter to be developed when creating, for example, a relay, automatic circuits, and also eliminates the need to develop a number of converters that operate only at certain frequencies.

input pulses, which will reduce the range of converters.

Claims (1)

CONTROLLED CONVERTER. PULSES, comprising a storage capacitor connected through a diode in direct conduction and a charge circuit to a source of input pulses, a discharge circuit connected to a storage capacitor through a diode in reverse conduction, characterized in that, in order to expand the dynamic range for the duration of converted pulses / into it introduced and-1 storage capacitors, and key elements, and integrating circuits, while storage capacitors are cascaded and connected through the corresponding elements to the common a potential power supply bus is connected to the bus, to / the connection point of storage capacitors and key elements via the reset button, the control inputs of the key elements are connected to the source of input _e pulses through the corresponding integrated elements. SU .... 1023644