CS241388B1 - Involvement to convert signals - Google Patents

Abstract

The signal conversion circuit solves the conversion of the control pulse signal into a galvanically separated signal of a changed shape and a higher energy level. The essence of the circuit lies in the connection of two controllable switches into one branch connected in series via a capacitor with the primary winding of the transformer, with at least one secondary winding connected preferably via a diode in series and via a parallel resistor with the output. The signal conversion circuit can be used in the construction of pulse control circuits, especially for the area of connection with thyristors and triacs.

Description

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The signal conversion circuit solves the conversion of the control pulse signal to a galvanically isolated signal of changed shape and higher energy level. The essence of the connection consists in connecting two controllable switches in one branch connected in series via a capacitor with a primary winding of the transformer, at least one secondary winding connected preferably via a diode in series connection and via a parallel resistor to the output. The signal conversion circuit can be used in the construction of pulse control circuits, especially for the field of connection with thyristors and triacs.

Knows Ml b- ea

The invention relates to a signal conversion circuitry and to the conversion of a control pulse signal to a galvanically isolated signal of changed shape and higher energy level.

The prior art signal conversion circuitry solves the signal conversion such that the switching element is connected directly in series with the inductive element and the desired shaping is achieved by complex pulse control circuits.

A disadvantage of the known connections is therefore the complexity of the volume and structure of the elements used, and thus the low stability of this conversion.

These main disadvantages are eliminated in the field of application of the signal conversion circuit according to the invention, which is characterized in that the first input terminal is connected to the power input of the first switching member, the second input terminal is connected to the power input of the second switching member, the third input terminal is connected to the pulse input of the first switching member and to the pulse input of the second switching member, the output of the first switching member and the output of the second switching member are coupled at a node connected to the fourth input terminal via a capacitor and primary transformer winding in series; At least one secondary winding connected to the output terminals is connected to the transformer.

The first secondary winding is connected to the output terminals via a first diode in series connection and a first resistor in parallel connection bridging these output terminals.

An advantage of the signal conversion circuitry of the present invention is that the timing of the output converted signal is synchronous to the future control signal at the input. The desired shape of the output signal as well as the choice of its polarity are achieved by suitable selection of the parameters of the elements used.

The drawing shows an exemplary embodiment of a signal conversion circuit according to the present invention, with two secondary windings connected on the secondary side of the transformer.

The first input terminal 1 is connected to the power input 21 of the first switching member 10, the second input terminal 2 is connected to the power input 24 of the second switching member 11. The third input terminal 3 is connected to the pulse input 23 of the first switching member 10 and to the pulse input. 28 of the second switching member 11. The output 22 of the first switching member 10 and the output 25 of the second switching member 11 are connected at a node 9 connected to the fourth input terminal 4 via a capacitor 12 and a primary winding 13 of the transformer in series. On the secondary side of this transformer, a first secondary winding 15 connected to the output terminals 5, 6 is connected through a first diode 17 in series and a first resistor 18 in parallel, bridging these output terminals 5, 6, and a second secondary winding 18 connected with further output terminals 7, 8 via a second diode 19 in series and a second resistor 20 in parallel to bridge these additional output terminals 7, 8.

Any controllable switching element, such as a transistor, relay, etc., is considered as a switching member.

A different supply voltage is applied to the input terminals 1, 2, for example a positive voltage is applied to the first input terminal 1, a negative voltage is connected to the second input terminal 2. Constant voltage is applied to the fourth input terminal 4.

By applying a pulse signal to a third input terminal 3, such as a square wave signal, the signal passes to the pulse input 23 of the first switching member 10 and to the pulse input 26 of the second switching member 11. The rising edge of the pulse signal switches the first switching diaper 10 and opens the second switching member 11. The state thus formed lasts for the duration of the positive pulse. The falling edge of this pulse signal expands the first switching member 10 and switches the second switching member 11.

When the first switching member 10 is closed, the positive voltage in the form of a positive pulse passes from its output 22 to node 9 and further through. the capacitor 12 and the primary winding 13 to the fourth input terminal 4. Upon subsequent state change, i.e. the closed state of the second switching member 11, the negative voltage in the form of a negative pulse passes from its output 25 to the node 9 and further through the capacitor 12 and the primary winding 13 the fourth input terminal 4.

Charging the capacitor 12 'causes rapid changes in the magnetic flux in the core 14, causing the pulses on the secondary windings 15, 16 to excite. The pulse from the first secondary winding 15 passes through the first diode 17 to the output terminal 9 diode 19. As a result, there are positive polarity pulses at the output terminals 5, 6 and negative polarity pulses at the output terminals 7, 8.

The first resistor 18 and the second resistor 20 represent minimum loads.

The signal conversion circuit according to the invention is used in the field of pulse control circuits, in particular in the field of connection with thyristors and triacs. A very specific application is in the construction of DC voltage converters.

Claims (2)

SUBJECT A signal conversion circuit, characterized in that the first input terminal (1) is connected to the power input (21) of the first switching member (10), the second input terminal (2) is connected to the power input (24) of the second switching member ( 11), the third input terminal (3) is connected to the pulse input (23) of the first switching member (10) and to the pulse input (26) of the second switching member (11), the output (22) of the first switching member (10) and the outputs (25) of the second switching member (11) are connected at a node (9) connected to the fourth input INVENTION with a clamp (4) via a capacitor (12) and a primary winding (13) of the transformer in series connection, at least one secondary winding (15) connected to the output terminals (5, 6) being connected to the secondary side of the transformer. 2. The signal conversion circuit according to claim 1, wherein: the first secondary winding (15) is connected to the output terminals (5, 6) via a first diode (17) in series and a first resistor (18) in parallel these output terminals (5, 6).