HU190567B - Circuit arrangement for generating alternating current, for transferring thereof between circuits with different voltage and for stabilizing thereof - Google Patents

Abstract

The invention relates to a comparator with field effect transistors in n-channel silicon gate technology. These comparators are used in particular for integrated parallel A / D converters with a resolution of 8 bits. The object of the invention is to develop a transistor and surface minimum comparator whose offset is compensated and which is also suitable under structural and process parameter variations of the n-channel silicon gate technology for an 8-bit parallel A / D converter. According to the invention, the object is achieved by arranging a switching transistor for positive feedback between the output of the comparator and the input of the first amplifier stage. A dummy transistor additionally reduces the comparator offset. The control of the decoder logic is provided by an AND gate. Fig. 1

Description

BACKGROUND OF THE INVENTION The present invention relates to a circuit arrangement for generating, transmitting and stabilizing alternating current between circuits of different voltages comprising a chopper circuit, a current sensing unit, a filter circuit, a tin-oscillating inverter and a control circuit.

In practice, and in the literature, many switching arrangements are known that provide stable alternating current for transmission between circuits of different voltages. This is needed, among other things, to provide heating current for high-voltage vacuum tubes. Among these, there is a distinguished application where the control of the anode flow of the pipe is effected by changing the effective value of the heating current. A typical example is the heating current regulation of X-ray tubes, where for a given anode voltage the control of the anode current and hence the intensity of the radiation depends on the high accuracy of the heating current value.

Some of the solutions for the tasks described above adjust the effective value of the current by changing the resistance from a pre-stabilized voltage. In more advanced electronic circuits, measuring the true effective value of the actual current and feeding it back to the control unit can provide a practically perfect solution. The first group of switches is characterized by its simple, robust design, low operating frequency - typically 50 or 100 Hz - and low cost. The pre-stabilized voltage is usually produced by ferro-resonance methods (eg in heating circuits of MEDICOR EDR 750 / B or NEODIAGNOMAK X-ray machines). They have the disadvantage that they can be realized with relatively large geometric and weight dimensions, have poor efficiency, require lengthy and cumbersome work to set the AC value, and do not always meet the accuracy requirements. With more advanced electronic circuits, the operating frequency can be raised to the kHz range, resulting in size and weight loss, and the accuracy that can be achieved depends on the quality characteristics of the circuitry units used, and hence the cost. The efficiency can be significantly increased by applying switching control. The disadvantage here is that the measurement of the effective value of the actual aram is usually performed in a secondary circuit with a potential significantly different from that of the control unit (50-100kV) and transmitted to the processing site by bridging a large voltage difference. This significantly increases the cost and complexity of the circuitry, and inversely proportional to the reliability.

Technical advances, increasing demands for quality and reliability have necessitated the generation of AC currents capable of transmitting between different voltage circuits of highly efficient, highly controllable effective value. Circuits that provide this are required to be small in volume and weight, efficient, reliable, and inexpensive.

The present invention relates to a circuit arrangement which satisfies the above requirements. / It is based on the recognition that the change in the ratio between the average value of the input current and the effective value of the output current of an ohm-inductive load-bearing rectangle generating rectangular voltage is well dependent on the load time constant, and the self-oscillation frequency is This allows the signal to be mapped on a control loop potential proportional to the effective value of the output current at a relatively high self-oscillation frequency. Thus, a simple design, low cost, reliable operation, low volume and weight, high efficiency switching arrangement can be realized for generating AC, transmitting and stabilizing between different voltage circuits.

The invention thus provides a circuit arrangement for generating alternating current and for transmitting and stabilizing it between circuits of different voltages having a chopper circuit, a current sensing unit, a filter circuit, a self-oscillating inverter, which are connected in series. The invention is characterized in that the output of the current sensing unit providing a signal proportional to the current value and the current reference signal is sent to the control input of the chopping circuit through a control circuit. The self-oscillating inverter has a synchronous output which is directly connected to the synchronizing input of the DC chopper, so that the DC chopper frequency is twice the inverter's self-oscillating frequency.

In a preferred embodiment of the circuit arrangement according to the invention, the self-oscillating inverter is configured such that a single transformer output is a self-known astable multivibrator circuit having a timing circuit fed by a separately stabilized DC voltage and a sync signal output to a two connected. The self-oscillating inverter input is the center output of the primary winding of the unstable multivibrator with transformer output, and the AC output of the self-vibrating inverter is the secondary winding of the transformer.

Preferably, the chopping circuit is formed by serially switching a comparator having a signal translator and a non-signal input, and a known chopper circuit having a logic control input.

BRIEF DESCRIPTION OF THE DRAWINGS The invention will now be described with reference to the drawings, in which:

Fig. 1 shows an exemplary circuit arrangement according to the invention;

Figure 2 illustrates a preferred embodiment of a circuit arrangement according to the invention.

Fig. 1 illustrates an exemplary circuit arrangement according to the invention, having a chopping circuit 2 with a synchronization input 4 and a control input 3, a price sensing unit 5 having an output proportional to the center value 13, a filter circuit 6 and a synchronous output 8. It has a self-oscillating inverter and has a control circuit 9 having a first input 10, a second input 11 and an output 12. The terminal 1 of the DC voltage supply source X is connected via the chopper circuit 2, the current sensor unit 5 and the filter circuit 6 to the input of the self-oscillating inverter 7, whose synchronous output 8 is connected to the synchronization input 13 of the chopper circuit 2. an output signal providing a signal with a mean value is connected to the first input 10 of the control circuit 9, the terminal 14 of a current reference source is connected to the second input 11 of the control circuit 9 and the output 12 of the control circuit 9 is connected to the control input 3. the output of the self-oscillating inverter is also the AC output of the switching arrangement. The exemplary circuit arrangement of the present invention stabilizes the effective value of the alternating current generated by the self-oscillating inverter 7 so that the output of the chipping circuit 2 is constant with the control circuit 9 as a function of the output current measured by the current sensor unit 5. holds. The filter circuit 6, located between the chopper 2 and the self-oscillating inverter 7, produces a smooth DC voltage at the input of the self-oscillating inverter 7. The input current of the filter circuit 6 is equal to the average value of the input current of the self-oscillating inverter 7, which is also the output current of the chopping circuit 2. The circuit arrangement thus maintains the mean value of the input current of the self-oscillating inverter 7 at a constant value. Depending on the time constant of the ohm-inductive load connected to the output of the self-oscillating inverter 7, the change in the ratio between the average value of the input current of the self-oscillating inverter and the output current of the inverter can be kept below any value. Thus, the switching arrangement according to the invention stabilizes the effective value of the AC current transmitted between the various voltage circuits, depending on the choice of the self-oscillation frequency. The circuit arrangement according to the invention is also suitable for power control. In this case, an additional regulator is required.

In the preferred embodiment shown in Fig. 2, the self-oscillating inverter circuit 7 comprises a first transistor 15 and a second transistor 16 with two inputs and two outputs supplied from an output terminal 20 of a stabilized DC source with a single winding primary coil 18. transformer and a summing amplifier 19 with two inputs. The timing circuit 17 having two inputs and two outputs, the first transistor 15 and the second transistor 16 form a known unstable multivibrator. The summing amplifier input 19 with two inputs is connected to the bases of the first transistor 15 and the second transistor 16 and its output forms the synchronous signal output 8 of the inverter. The primary center terminal of the transformer 18 having a single-phase center-tap primary coil is connected to the filter circuit 6 supplying the inverter input voltage, the two primary coils terminating at the collectors of the first transistor and the second transistor 16. The chopping circuit 2 consists of a known chopper circuit 22 having a logic control input 23 and a comparator 21 having a signal inverter and a non-inverting input, the output of the comparator 21 being connected to the logic control input 23 of the chopping circuit 22 and the non-inverter input is the same as the control input 3 of the hacking circuit 2. The transformer secondary terminals 18 of the single-phase center-tap-doped primary coil form the alternating current output of the circuit.

Powering the timing circuit 17 providing the inverter self-oscillation frequency and the base current of the transistors 15, 16 from a separately stabilized voltage source has the advantage that the base currents of the first transistors 15 and second transistors are not provided at the input of the self-oscillating inverter. current sensing unit. Otherwise, this would lead to an additional error. As a result of the operating principle of the unstable multivibrator, the sum of the base voltages of the transistors 15, 16 results in an almost triangular oscillation at a repetition frequency twice the self-oscillation frequency. This is applied as a synchronous signal to the signal inverter input of the comparator 21 and thus provides the voltage required for pulse-width modulation of the chopper circuit 22. As a result, the chopper circuit 2 operates symmetrically 37 every half period of the output voltage of the self-oscillating inverter, which provides amplitude symmetry of the output voltage of the self-oscillating inverter 7, thereby eliminating additional errors.

The present invention has the following advantageous properties compared to known alternating current stabilization circuits:

-The output stabilizes the effective AC output value with a predetermined accuracy without complex and costly current-efficient output.

- It does not require the transmission of information between different voltage circuits. -Simple design, high efficiency, small scale implementation, low cost.

The disadvantage is that:

-The accuracy depends on the operating frequency, which requires a single careful adjustment for a given load circuit constant.

Claims (5)

PATENT CLAIMS A circuit arrangement for generating alternating current and for transmitting and stabilizing it between circuits of different voltages, comprising a chopper, a current sensing unit, a filter circuit, a self-oscillating inverter, which are connected in series to receive a DC voltage supply within a given range. ) is connected via the chopper circuit (2), the current sensing unit (5) and the filter circuit (6) to the input of the self-oscillating inverter (7) whose synchronous signal output (8) is connected to the synchronization input (4) of the chopper circuit (2) a current sensing unit. An output (13) providing a signal proportional to the current value (13) is connected to the first input (10) of the control circuit (9), a current source source terminal (14) is connected to the second input (11) of the control circuit. the output (12) of the circuit (9) is the smell connected to the control input (3) of a pond circuit (2), the output of the self-oscillating inverter (7) is also the AC output of the circuit arrangement. The circuit arrangement according to claim 1, characterized in that it is self-vibrating An inverter (7) is configured such that one of the inputs of a timing circuit (17) powered by an output terminal (20) of a stabilized DC source is a first transistor (15). To 10 collectors, one input to the collector of a second transistor (16), one output to the base of the first transistor (15), another output to the base of the second transistor (16), emitters of the two transistors (15) (16) By connecting 15 to each other and a zero potential point, it forms a known unstable multivibrator, one input of a summing amplifier (19) with two inputs connected to the base 20 of the first transistor (15), the other input to the base of the second transistor (16). (7) consists of a synchronous signal output (8) and has a single-phase center-tap primary coil A primary center terminal of 25 transformers (18) forms the input of the self-oscillating inverter (7), one of the primary winding terminals is connected to the collector of the first transistor (15) and the other primary winding end is connected to the collector of the second transistor (16); the chopping circuit (2) being configured so that the input of the chopping circuit (22) is formed by using a known chopping circuit (22) having a logic control input (23) and a comparator (21) having a signal converter and a non-translating input. the input of the chopping circuit (2) and the output of the chopping circuit (2), the signal input of the comparator (21) the synchronization input (4) of the chopping circuit (2), the input of the non-inverting circuit (2). forming a control input (3) and an output of the comparator (21) connected to the logic zero input (23) of the hacking circuit (22); the secondary winding terminals of the transformer (18) form the alternating current output of the circuit.