FI94686B - voltage Measuring Circuit - Google Patents

Description

1 94686 Voltage measuring circuit

The invention relates to a voltage measuring circuit, in particular for measuring the output voltage of a switch power supply, comprising a transformer having a primary and a secondary winding with a primary winding of the transformer for periodically switching the measuring voltage of the first switching means to the measuring circuit of the first switching means.

10 Switching power supplies typically have a power transformer

T1 having a primary winding W1 and a secondary winding W2 and dividing the switch power supply into two galvanically separated parts, a primary circuit and a secondary circuit, as illustrated in Figures 1 and 2. The DC switch power supply on the secondary side 15 has at least a rectifier D2 and a filter capacitor C1. The primary side typically has a switching transistor TRI that connects the DC voltage of the transformer DC1 to the primary winding of the transformer T1 at the operating frequency of the switch power supply. The output voltage DCQUT of the switch power supply depends on the switching frequency of the transistor 20I TRI, which is therefore attempted to be adjusted depending on the output voltage so that the output voltage remains desired. The problem in such a circuit is the measurement of the output voltage DCqut-. from the secondary side of the power supply and transferring the measurement result or control from the secondary side to the galvanically isolated primary side for controlling the transistor TRI.

In a known solution, the feedback control information is taken through a power transformer, as illustrated in Figure 1. Then a second secondary winding W3 is connected to the power transformer T1, the measurement voltage of which is rectified by a rectifier D1 and fed to a control circuit 11, which in turn controls .

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In another known solution, illustrated in Fig. 2, the output voltage DCQUT is measured directly from the output of the switch power supply by a control circuit 21 located on the secondary side of the switch power supply, and the control signal is fed to the primary side using a isolating unit 22. However, such a solution requires relatively many additional components.

GB-A-2,153,113 discloses a DC-DC converter in which the output voltage of the converter is connected by a transistor-10 controlled by a switching frequency present in the secondary windings of the power transformer of the converter to the primary windings of the isolation transformer. The voltage induced on the secondary windings of the isolating transformer is rectified and fed back to the control electronics of the transformer. In this connection, too, voltage losses across the rectifier diode and the switch-15 field-effect transistor cause measurement errors. The faster the circuit is made, the worse the accuracy of the measuring circuit.

It is an object of the present invention to provide a circuit for measuring the output voltage of a switch power supply, which avoids the above-mentioned problems and further achieves other advantages.

This is achieved by a voltage measuring circuit of the type shown in the introduction, for which according to the invention. characterized in that the measuring circuit comprises a second switching means connected in series between the output terminals of the measuring circuit 25 to rectify and connect the voltage induced in the secondary windings of the transformer to the output terminals of the transformer circuit, and the means mode.

In the present invention, the output voltage of the switch power supply is measured by a series connection of a measuring transformer and a switching means which preferably has a resistive voltage-35 te / current behavior in a conductive state. The switching means periodically switches the voltage to be measured to the primary winding of the transformer, whereby the voltage is induced in the secondary winding of the transformer. The voltage of the secondary winding of the transformer is rectified by a switching means of the same type as that used on the primary side of the transformer and connected to the output terminals of the measuring circuit as a measured value to the switch power supply control circuit located on the primary side of the power supply. The switching means are synchronized with each other, whereby the signals present in the power supply 10 can be advantageously used. Errors caused by the secondary components of the power supply are eliminated because the actual output voltage is measured. In the known solutions according to GB patent application 2,153,113 and Fig. 1, the voltage visible at the terminals of the transformer is measured, but the actual output voltage 15 is smaller by the voltage drop of the rectifier diode and the switching transistor. The voltage drop of the rectifier diode, in turn, is temperature dependent and also has variation due to component scattering. When synchronized switching elements without a PN boundary-20 surface are used in the invention, errors due to the temperature dependence of the interface are eliminated. In addition, the measuring circuit according to the invention can be implemented with a smaller number of components than the known measuring circuits.

: The invention will now be described with reference to exemplary embodiments with reference to the accompanying drawings, in which Figures 1 and 2 show schematic diagrams of two known switching power supply measurement and control circuits, Figure 3 shows a schematic circuit diagram 30 of a measuring circuit switch mode power supply.

Fig. 5 shows a schematic circuit diagram 35 of the measuring circuit of Fig. 3 applied to a second switch source;

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The measuring circuit according to the invention can be applied in any measuring application where an accurate voltage measurement is required and it is desired to transfer the measurement result between galvanically separated device parts.

The basic structure of the invention is illustrated by the circuit diagram of Fig. 3, which shows only the most essential components for the operation of the measuring circuit according to the invention.

The measuring circuit according to the preferred embodiment of the invention shown in Fig. 3 comprises a measuring transformer T2 having a primary winding W4 and a secondary winding W5. A switching component TR2 with a resistive voltage / current behavior in a conductive state is connected in series with the primary winding W4 of the transformer T2. The series connection of the winding W4 and the switching component TR2 15 is connected between the measuring or input terminals A and B of the measuring circuit. A second switching component TR3 of the same type as the switching component TR2 used on the primary side is connected in series with the secondary winding W5 of the transformer T2. The series connection of the secondary winding W5 and the switch component 20 TR3 is connected between the output terminals C and D of the measuring circuit. Switch components TR2 are any switch components that conduct in only one direction to provide a rectification function and have a desired resistive voltage / current behavior in a conductive state, such as semiconductor switch components. In a preferred embodiment of the invention, TR2 and TR3 are MOSFET switch components controlled by gate electrodes G1 and G2.

The measuring circuit according to Figure 3 operates as follows. The switching component TR2 switches the measurement voltage across the input terminals A and B under the control signal supplied to the gate electrode G1 from the periodic to the primary winding W4 of the measuring transformer T2, whereby a voltage across the winding W4 induces a corresponding voltage across the secondary winding W5. 35 The switching component TR3, controlled by the control ”signal applied to the gate electrode G2, rectifies the current across the secondary winding W5.

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5 94686 induced voltage and connects the rectified secondary voltage to the output terminals C and D of the measuring circuit. The switch components TR2 and TR3 are synchronized with each other so that they are in the conducting state and the non-conducting state 5 substantially simultaneously.

Figure 4 illustrates the application of the measurement circuit of Figure 3 to a DC-DC switch power supply. Figure 4 shows only the circuit components relevant to the description of the invention. As will be apparent to one skilled in the art, other additional components may be included in the switch power supply connection.

In Fig. 4, the switch source comprises a transformer T1 which divides the power supply into a primary side (input side) and a secondary side (output side). The transformer comprises a primary winding 15 W1 and a secondary winding W2. On the primary side, a switching transistor TRI is connected in series with the primary winding W1 of the power transformer T1, which switching at frequency f connects the incoming DC voltage across the series connection to the primary winding W1, over which the voltage 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, whereby the voltage across the capacitor C1 forms the DC output of the power supply. Ion DCq ^. The input terminals A and B of the measuring circuit 41 according to the invention shown in Fig. 3 are connected to the output terminals of the power supply over the capacitor C1 • 25. The output terminals C and D of the measuring circuit 41 are connected to the control circuit 42 on the primary side of the power supply. Thus, according to the invention, the measuring circuit 30 can measure the switched-mode power supply from the secondary side output voltage, and transmits a measurement result galvanically separated in the secondary side control circuit 42. The control circuit 42 may simplest form differential amplifiers, which compares the 41 produced by the measuring circuit voltage I-35 influencing the hydrodynamics preset reference voltage (which corresponds to the desired output voltage dCqUT) to produce their differential voltage, and a modulator circuit controlled by said differential voltage.

Signals already present in the power supply are preferably used for the control and mutual synchronization of the switching components TR2 and TR3 of the measuring circuit 41 according to the invention. In the embodiment shown in Fig. 4, a control signal for the gate G1 of the switch component TR2 is produced by the control circuit 44 from the voltage across the secondary winding W2 of the power transformer T1. Correspondingly, a control signal is produced for the gate electrode 10 of the switching component TR3 by the control circuit 43 either from the primary voltage across the primary winding W1 of the power transformer T1 or alternatively from the control signal of the transistor TRI. In this way, the control circuits 44 and the control signals of the measuring circuit 41 also remain galvanically separated from each other because they are taken from different sides of the power transformer T1 and fed to different parts of the measuring transformer T2. However, the primary switching frequency present in all control signals is the switching frequency of the transistor TRI, whereby the switching components TR2 and TR3 operate in synchronism with each other.

In the alternative embodiment shown in Fig. 5, a control signal for the gate G1 of the switch component TR2 is provided by the control circuit 54 and a control signal for the switch component. TR3 to the gate electrode G2 by the control circuit 53. The control circuits 53 and 54 are synchronized with each other via a transformer T3, whereby the control circuits 53 and 54 and the control signals produced by them are galvanically separated from each other. The transformer T3 is completely independent of the power transformer T1 and its signals, so that the control circuits 53 and 54 can control the measuring circuit at a higher operating frequency than the operating frequency of the switch power supply.

The invention can also be applied in switch-mode power supplies implemented in other ways.

Otherwise, the accompanying figures and the related description are intended only to illustrate the present 7,94686 invention. The details of the measuring circuit according to the invention may vary within the scope of the appended claims.

Claims (8)

1. Voltage measurement circuit especially for measuring output voltage from a chopper type power source comprising a transformer (T2) with a primary and secondary winding (W4, W5), one with the transformer's primary winding (W4) between the input terminals of the measuring circuit (A, B) first switching means (TR2) for periodic coupling of measuring voltage 10 to the primary winding of the transformer (W4), characterized in that the measuring circuit further comprises a second coupling means (C3, D) connected to the output circuit (C, D) of the measuring circuit in series with a voltage induced and transformed in the secondary winding of the transformer into the output terminals (C, D) of the measuring circuit, and a means (43, 44) for synchronizing the first and second switching means with each other, and the first and second switching means (TR2 , TR3) has a resistive voltage / current function in a conductive state. 2. Measuring circuit according to claim 1, characterized in that the first and second coupling means (TR2, TR3) are semiconductor coupling components, preferably MOSFET coupling components. '' 25 3. Measuring circuit according to claim 1 or 2, characterized in that the means for synchronizing the first and second coupler means (TR2, TR3) control the coupler means by means of control signals obtained from the chopper power source. 30 Measuring circuit according to claim 3, characterized in that the chopper power source comprises a power transformer (T1) with a primary and secondary winding (W1, W2) and the means for synchronizing the first and second switching means (TR2, TR3) first control circuit 35 (44) controlling the first switching means with a first control signal received from the secondary side of the power transformer, and a second control circuit (43) controlling the second switching means with a second side signal from the power transformer's primary side. , which has the same frequency as the first control signal. Measuring circuit according to claim 4, characterized in that the first control signal is formed by the voltage in the secondary winding of the power transformer (W2) and the second control signal is formed by the voltage of the primary winding (W1). 6. A measuring circuit according to claim 3, 4 or 5, characterized in that the frequency of the control signals is the same as the operating frequency of the chopper power source. Measuring circuit according to claim 1 or 2, characterized in that the means for synchronizing the first and second switching means (TR2, TR3) comprises a first control circuit (54) controlling the first switching means, a second control circuit ( 53), which controls the second switching means, and a transformer (T3), through which the control circuits 20 are synchronized with each other. Measuring circuit according to any of the preceding claims, characterized in that the chopper power source comprises a power transformer (T1) with a primary and secondary winding (W1, W2), and a power supply. 25, the primary voltage regulating control circuit (42, TRI), and the output terminals (C, D) of the measuring circuit are connected to said control circuit.