SE511049C2 - Device for evaporating gas at a nuclear power circuit to measure the output voltage of a switching current source - Google Patents

Abstract

The invention relates to a voltage measuring circuit, especially for measuring the output voltage of a switched-mode power supply. According to the invention a first switching transistor (TR2) periodically switches the output voltage to a primary winding (W4) of a measuring transformer (T2). The induced secondary voltage of the transformer (T2) is rectified and switched to a control circuit by a second switching transistor (TR3). The first and second transistors are synchronized and exhibit a resistive voltage/current behaviour in a conducting state. <IMAGE>

Description

511 10 15 20 25 30 35 H., V:. ~. u ~ '_ 049 rectifier D1 and is led to the control circuit ll of the switch transistor TR1. measurement error due to the leakage inductance of the transformer T1 and This is a simple solution, but it causes the voltage drop across the rectifier.

In another known solution, shown in Figure 2, the output voltage DC is measured directly from the output of the switching current source, the medium suction control circuit 21 located on the secondary side of the switching current source. The control signal is transmitted to the primary side by means of an isolation unit 21. many additional components.

However, this solution requires relative GB application No. 2,153,113 discloses a DC / DC converter in which the output voltage of the converter is connected to the primary winding of an isolation transformer by means of a transistor which is controlled by the switching frequency of the secondary winding of the converter power transformer. The voltage induced across the secondary winding of the isolation transformer is rectified and fed back to the control electronics of the converter. Also in this connection, the voltage drop across the rectifier diode and the switch transistor causes measurement errors. The accuracy of the measuring circuit is worse the faster the circuit is made.

The object of the present invention is a circuit for measuring the output voltage of a switching current source in such a way that the above-mentioned problems are avoided and other advantages are achieved.

This is achieved with a voltage measuring circuit of the type stated in the preamble, which according to the invention is characterized in that the measuring circuit further comprises a second coupling means connected in series with the secondary terminals of the longitudinal terminals of the secondary circuit to rectify the voltage induced in the transformer. the voltage to the output terminals of the measuring circuit, and a means for synchronizing the first and the second coupling means with each other, the first and the second coupling means having resistive voltage / current properties in the conducting state .

In the present invention, the output voltage of the switching current source is measured by means of a series connection of a measuring transformer and a switching means with preferably resistive voltage / current properties in the conducting state. The coupling means couples the voltage to be measured periodically to the primary winding of the measuring transformer, whereby the voltage is induced in the secondary winding of the measuring transformer. The secondary winding voltage of the measuring transformer is rectified with a coupling means similar to that used on the primary side of the transformer.

The rectified voltage is connected to the output terminals of the measuring circuit to be conducted as a measured value to the control circuit of the switching power source on the primary side of the power source.

The measuring circuit is bidirectional in that the coupling means during use allows current to flow in both directions with resistive voltage drops. Because the mode of operation of the measuring circuit according to the invention is bidirectional, it transmits measuring information substantially faster than the measuring circuit according to GB application specification No. 2 153 113, since the secondary winding of the measuring circuit during an operating cycle has a voltage equal to the primary voltage or direct proportion with the primary voltage. The coupling means are synchronized with each other, whereby the signals that occur in the power source can be utilized. The faults caused by the components on the secondary side of the power source are eliminated because the actual output voltage is measured. In GB application No. 2 153 113 and in the known solutions according to Figure 1, the voltage across the transformer terminals is measured, but the actual output voltage is lower due to the voltage drop across the rectifier diode and the switch transistor. The voltage drop across the rectifier diode 511 049 10 15 20 25 30 35 4 is for its part temperature dependent and further variations occur due to component tolerances. When synchronized coupling elements without PN junction are used in the invention, the errors caused by the temperature dependence of the PN junction are eliminated because the resistances of the coupling elements can be made many times smaller than the impedance of the measuring circuit. In addition, the measuring circuit according to the invention can be designed with a smaller number of components than the known measuring circuits.

In the following, the invention will be described by way of example with reference to the accompanying drawings, in which Figures 1 and 2 show a basic circuit diagram of two known measuring and control circuits for a switching current source, Figure 3 shows a basic circuit diagram for a measuring circuit according to the invention, and figure 4 shows a basic circuit diagram of the measuring circuit according to figure 3 where it is applied in a switching current source.

The measuring circuit according to the invention can be used in any measuring application where exact voltage measurement is required and where the measuring result is desired to be transferred between galvanically insulated apparatus sections.

The basic construction of the invention is shown in figure 3, which shows only the components which are essential for the function of a measuring circuit according to the invention.

The measuring circuit according to a preferred embodiment of the invention, shown in Figure 3, comprises a measuring transformer T2 with a primary winding W4 and a secondary winding WS. A switch component TR2 with resistive voltage / current properties in the conducting state is connected in series with the primary winding W4 of the transformer T2.

The series connection of the winding W4 and the switch component 10 15 20 25 30 511 049 5 TR2 is connected between the measuring or input terminals A and B of the measuring circuit. A second switch component TR3 of the same type as the switch component TR2 used on the primary side is connected in series with the transformer T2 secondary winding W5. The series connection of the secondary winding W5 and the switch component TR3 is connected between the output terminals C and D of the measuring circuit. The switch components TR2 and TR3 can be any switch components which lead in only one direction to achieve a rectifying effect and which have the desired resistive voltage. / current properties in conducting states, for example semiconductor switch components_ In the preferred embodiment of the invention, TR2 and TR3 MOSFET switch components are controlled by the gate electrodes G1 and G2.

The mode of operation of the measuring circuit according to Figure 1 is as follows. The measuring voltage which occurs between the input terminals A and B is periodically connected to the primary winding W4 of the measuring transformer T2 by means of the switch component TR2 controlled by a control signal which is applied to the gate electrode G1 of TR2. As a result, the voltage appearing across the primary winding W4 induces a corresponding voltage across the secondary winding W5. The induced voltage across the secondary winding W5 is rectified and the rectified secondary voltage is connected to the output terminals C and D of the measuring circuit by means of the switch component TR3 controlled by a control signal applied to the gate electrode G2. The switch components TR2 and TR3 are synchronized with each other so that they are in the conductive and non-conductive states, respectively, substantially simultaneously.

Figure 4 shows the application of the measuring circuit according to Figure 3 for a DC / DC switching current source. Figure 4 shows only the circuit components that are essential for describing the invention. As will be apparent to one skilled in the art, the switching power source may also include other additional components.

In Figure 4, the switching current source comprises a transformer T1, which divides the current source into a primary side (input side) and a secondary side (output side). a secondary winding W2.

The transformer comprises a primary winding W1 and On the primary side, a switching transistor TR1 is connected in series with the primary winding W1 of the power transformer T1. The transistor TR1 switches with the switching frequency fop the incoming DC voltage across the series connection to the primary winding w1, and the voltage across said winding induces a corresponding voltage across the secondary winding W2. The voltage across the secondary winding W2 is rectified by a rectifier diode D2 and filtered by a filter capacitor C1, the voltage across the capacitor C1 constituting the DC voltage output of the current source DC The input terminals A and B for the measuring OUT circuit 41 according to the invention are connected. to the output terminals of the current source via the capacitor Cl. connected to a control circuit 42 on the primary source C and D of the current source 41. The control circuit 42 provides the control signal for the transistor TR1. In this way, it is possible with the measuring circuit according to the invention to measure the output voltage on the secondary side of the switching current source and to transmit the measuring result galvanically isolated to the control circuit 42 on the primary side. In its simplest form, the control circuit 42 may be a differential amplifier which compares the voltage generated by the measuring circuit 41 with a predetermined reference voltage (which corresponds to the desired output voltage DC) and generates their differential or false OUT voltage, and a modulator circuit. which is controlled by said fault voltage.

For control and mutual synchronization of the switch components TR2 and TR3 for the measuring circuit 41 10 15 20 25 30 35 511 049 7 according to the invention, signals already present in the current source can be used. In the embodiment according to Fig. 4, the drive circuit 44 from the voltage across the secondary winding W2 of the power transformer T1 provides a control signal for the gate G1 of the switch component TR2. Correspondingly, the driving circuit 43 provides either from the primary voltage of the power transformer T1 over the primary winding W1 or alternatively from the control signal of the transistor TR1 a control signal for the gate electrode G2 of the switch component TR3. In this way, a galvanic isolation is maintained between the drive circuits 44 and control signals of the measuring circuit 41, since they are obtained from different sides of the power transformer T1 and are fed to different sides of the measuring transformer T2. However, the primary switching frequency for all control signals is the switching frequency of the transistor TR1, the switching components TR2 and TR3 operating in synchronism with each other.

In the alternative embodiment according to Figure 5, the drive circuit 54 provides a control signal for the gate component TR2 gate G1 and the drive circuit 53 provides a control signal for the switch component TR3 gate electrode G2.

The drive circuits 53 and 54 are synchronized with each other through the transformer T3, the drive circuits 53 and 54 and the control signals they provide being galvanically isolated from each other. The transformer T3 is completely independent of the power transformer T1 and its signals, so that the drive circuits 53 and 54 can control the measuring circuit with a higher operating frequency than the operating frequency of the switching current source, whereby the circuit can be realized with components of substantially smaller size.

The invention can also be applied in switching power sources designed in some other way.

The accompanying drawings and the accompanying description are intended solely to illustrate the present invention. The measuring circuit according to the invention may vary in detail within the scope of the appended claims.

Claims (8)

10 15 20 25 30 35 511 049 9 Patent claims Voltage measuring circuit, in particular for measuring the output voltage of a switching current source, comprising a transformer (T2) with a primary and a secondary winding (W4, WS), a first switching means (TR2) connected in series with the primary winding (W4) of the transformer between the input terminals (A, B) of the measuring circuit for periodically connecting the measuring voltage to the primary winding of the transformer (W4), characterized in that the measuring circuit further comprises a second coupling means (TR3) connected in series with the secondary winding (WS) between the measuring terminals (C , D) to rectify the voltage induced in the secondary winding of the transformer and to connect the rectified voltage to the output terminals (A, B) of the measuring circuit, and a means (43, 44) for synchronizing the first and second coupling means with each other, wherein the first and the second coupling means (TR2, TR3) have resistive voltage / current properties in the conducting state. Measuring circuit according to Claim 1, characterized in that the first and the second coupling means (TR2, TR3) are semiconductor switch components, preferably MOSFET switch components. Measuring circuit according to Claim 1 or 2, characterized in that the means for synchronizing the first and the second coupling means (TR2, TR3) controls the coupling means by means of control signals obtained from the coupling current source. Measuring circuit according to claim 3, characterized in that the switching current source comprises a power transformer (T1) with a primary and a secondary winding (w1, W2), and that the means for synchronizing the first and second coupling means (TR2, TR3) comprise a first drive circuit (44) which controls the first coupling means by means of a first control signal obtained from the secondary side of the power transformer, and a second drive circuit (43) which controls the second coupling means by means of a second control signal obtained from the primary side of the power transformer, the first and second control signals being of the same frequency. Measuring circuit according to Claim 4, characterized in that the first control signal is obtained from the secondary winding (W2) voltage of the power transformer and the second control signal is obtained from the voltage of the primary winding (W1). Measuring circuit according to Claim 3, 4 or 5, characterized in that the frequency of the control signals is the operating frequency of the switching current source. Measuring circuit according to Claim 1 or 2, characterized in that the means for synchronizing the first and the second coupling means (TR2, TR3) comprises a first driving circuit (44) which controls the first coupling means, a second driving circuit (43). which controls the second coupling means, and a transformer through which the drive circuits are synchronized with each other. Measuring circuit according to one of the preceding claims, characterized in that the coupling current source comprises a power transformer (T1) with a primary and a secondary winding (W1, W2), and a control circuit (42, TR1) connected to the primary side of the power transformer as controls the primary voltage, the output terminals (C, D) of the measuring circuit being connected to said control circuit.