CS9101182A2 - Testing apparatus with direct-current voltage source - Google Patents

Description

-! Γ MP-102-? L-Ce

Testing apparatus with DC voltage source

Technical field

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a test apparatus with a DC voltage source for generating a measuring current, guided by a measured object, in particular to measure the protective conductor resistance and voltage equalization lines, and with a protective circuit against unsafe foreign voltages fed through the measured object.

Background Art

Testing devices designed to measure ohmic resistances need a DC voltage source from which a current is fed through the measured object, where a voltage drop occurs, from which the resistance of the object to be measured is determined. For separate circuit elements whose resistance is to be checked, for example, before being connected to an electrical circuit. There is no problem with such a measurement. However, other ratios are when the measured object is connected in a circuit and must be calculated with dangerous foreign voltages. This is particularly true of, for example, overcurrent conductors and equalizing conductors in the voltages whose resistance is to be measured.

According to VDE 0413, it is prescribed that such measurements are made with a measuring current of at least 0.2 A and a voltage of at least 4.5 V. Furthermore, it is stipulated that the measuring instruments used for this purpose must not be destroyed or endangered by the user in case of incorrect handling. The test apparatus must therefore be designed in such a way that the mains voltage, which occurs when the measuring inputs are incorrectly operated, does not cause any damage.

It is known that test devices are protected on the input side by power diodes in conjunction with a fuse.

The fuse is connected in series with the measurement input and is bridged together with the diode chain. The threshold voltage chain is higher than the voltage of the DC voltage source, so both this voltage, πρπ + οίζοίιπι m ó · η o r> v <τ »η H A 1 / + and n · ... ^ j. j ... so the measuring current, the voltages that are added to the dc voltage are virtually short-circuited. The short-circuit current causes the melter to react, which melts so that hazardous foreign voltage is isolated from the DC voltage source and cannot destroy its components.

Such an arrangement is inconvenient in the sense that any manipulation at which dangerous foreign voltages come to the measuring inputs will cause the fuse to melt. The test device is only ready for operation after the replacement of the fuse. 3e need to keep spare fuses at your fingertips Another disadvantage is that the diode chain consisting of power diodes and fuse holder take up a lot of space

SUMMARY OF THE INVENTION It is an object of the present invention to provide a test apparatus of the type described above to block dangerous extraneous voltages so as not to endanger either the apparatus or the operator, but to cancel the locking again and continue the measurement as the dangerous foreign voltage is removed.

The essence of the invention is that in order to block the external voltages with the opposite polarity on one side of the measured object, a blocking diode is connected in the current circuit between the measured object and the DC voltage source, and the suppression of the serial external voltages of the same polarity on the other side of the measured object is in the current circuit between a controlled semiconductor switch is engaged by this object and the DC voltage source, the control circuit of this semiconductor switch is sized to close the current circuit as soon as the total voltage of the DC voltage source and the external voltage exceeds 3 the threshold element voltage threshold in the control circuit, the threshold voltage being higher than the voltage DC voltage source, and the switching path of the semiconductor switch closes again as soon as the total voltage drops below the threshold voltage.

The invention makes it possible to isolate extraneous voltages that exceed the hazardous value, irrespective of their polarity, from the DC voltage source. Attaching a blocking diode is sufficient to block external voltages, which are opposite the DC voltage source. On the other hand, to isolate external voltage polarity, a semiconductor switch is provided so that its switching path remains permanently closed in the absence of extraneous voltages, thus flowing the measuring current necessary for the measurement so that the switching path of the semiconductor switch is blocked as soon as the total voltage of the DC voltage source voltage and external voltage, exceeds the threshold voltage of the threshold element. The threshold element is a part of a control circuit that monitors the sum voltage and controls one semiconductor switch.

When used to measure the constant current known resistivity, the measurement procedure is considerably simplified since the voltage drop across the object being measured is a measure of its resistance. It is therefore expedient to equip the test apparatus with a constant current source to test the protective conductors and the equalization lines. A particularly advantageous embodiment of the invention is that the semiconductor switch, a necessary co-regulating element in the constant current source, operates simultaneously as a locking switch to block dangerous voltage levels.

The control circuit necessary for constant current generation is expediently designed such that the inverting input of the control amplifier is coupled to a feedback resistance coupled in series with the switching path of the semiconductor switch and compares the negative feedback voltage to the reference voltage that is formed on the reference element and is supplied 4 to the non-inverting input of the control amplifier, wherein the control circuit supplies the respective output signal to the control input of the semiconductor switch.

In addition, the control circuit integrated into the control circuit is formed so that the control transistor is connected to the control input of the semiconductor switch by its pin-emitter path and the end of the feedback resistor and the base of the transistor are coupled to the voltage divider that is connected. a series with a control circuit threshold element, wherein the voltage divider bridges the switching path of the semiconductor switch with serial feedback resistance.

In parallel to a series connection consisting of a switching path of a semiconductor switch and a feedback resistor, a varistor is connected to protect the semiconductor switch from overvoltage peaks.

The constant current source, consisting of a DC voltage source and a control circuit, is only to generate a constant current, which causes a voltage drop on the object being measured, as measured by the test apparatus. Measurements of this voltage drop must be made using a measuring circuit that evaluates the measured current and, if necessary, indicates a result.

As a semiconductor switch, there is expediently a power transistor, preferably a field-driven transistor, wherein the path and emitter-collector form the switching path of the gate electrode controlling the input. An embodiment of the invention is illustrated in the drawing. The test apparatus connection comprises a DC power source which supplies a control circuit K for generating a constant current I1. This current I is available as input current terminals 13, 13 as a measuring current. The constant measuring current X flows through the measured object Rx and causes a voltage drop on its resistance, which is determined by the measuring circuit M and evaluated.

If the measuring inputs A, B are not accidentally connected to the protective conductor under test, but the phase conductor is operated as a result of the error, the resulting external voltage in the circuit is to be blocked. To suppress external voltages with opposite polarity, a blocking diode V4 is connected between the first measuring input A and the positive pole of the DC voltage source Ug so as to block currents flowing in the opposite direction to the direct current source Ug. However, when the polarity of the foreign voltage at the measurement inputs A, B is reversed, this voltage is the same polarity in series with the DC source Ug, so that a voltage is present that far exceeds the DC voltage Ug. Such a sum voltage would cause an unacceptably high power dissipation on some circuits of the circuit, which could cause them to be destroyed, and this must be prevented.

A D-S circuit of the power transducer controlled by the field, which is a controlled semiconductor switch (Q) and a feedback resistor (R5) connected in series with this power transistor, is connected between the second measuring input B and the negative terminal of the DC source Ug. The switching path D-S of the controlled semiconductor switch V8 can be closed via control input 13 or opened to interrupt the power circuit. For this purpose, the control input G1 feeds the control signal output signal K_.

The control circuit K comprises a control amplifier V3 which compares the voltage drop applied to its inverting input (-) and taken from the feedback resistance R5, with the reference voltage applied to its non-inverting input (+), and controls the semiconductor switch V8 forming the control element. that the current in the sense of maintaining a constant measuring current is increased or decreased. The reference voltage is generated by the reference element V2, which is connected via a resistor R1 to the auxiliary voltage U1. In the control circuit K, a control circuit 1 is integrated, which is functionally completely independent of the control circuit and also includes an AuI reference element connected in series with two resistors R3, R4 forming a voltage divider and forming a serial circuit which is connected in parallel to a V-circuit switching circuit D-5 of the semiconductor switch V8 and the feedback circuit R5. The transistor V7, connected to the voltage divider with resistors R3, R4, by its emitter-collector path, controls the input of the semiconductor switch V8 to the negative pole of the auxiliary voltage U1, to which the resistor R4 of the divider and the return resistor R_5 are also connected. The control circuit L can also be used without control circuit elements (&quot; serving to maintain a constant current, only in connection with the DC voltage source Ug). In this case, the voltage divider through which the biasing control electrode G_ of the semiconductor switch V8 comes in is sufficient to ensure that the D-S switching path remains closed in the absence of extraneous voltage. To explain the function of the other circuit elements, it should be noted that the R6 resistor works as a varistor that lowers the overvoltage peaks, thereby protecting the V8 semiconductor switch. Capacitor C1 belongs to the DC source υ_θ voltage and thus forms a filter capacitor. The diode V1, which is connected in parallel to the capacitor C1 and polarized in the same way as the diode V4, shortens the very steep peaks of the live voltage, which are not immediately suppressed by the semiconductor switch V8 to protect the DC voltage source. Removal of R2, located between the output of the control amplifier V3 by the control electrode G of the semiconductor switch V8, serves to limit current.

While at positive voltage at the measurement input A, the V4 circuit closes the current generated by the external voltage and thus protects the circuit elements of the circuit from destruction, it takes a locking function at the negative input voltage at the measuring input A_

semiconductor switch V8. This is enabled by the control circuit L1 in which the reference element V5 is dimensioned so that the Zener voltage lies just above the maximum supply voltage of the DC source Ug. Thus, once the total voltage, consisting of the DC voltage of the source _U _ 4 x _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ __, the current flows through the voltage divider with resistors R 3, R 4, such that a positive voltage is applied on the basis of the control transistor V7, which reduces the voltage of the control electrode G of the semiconductor switch V8 to a negative value. The switching path D-5 of the semiconductor switch V8, which is normally closed, thus opens, thus preventing further current flow. The R3 resistor and the V8 solid state switch are set to the maximum external voltage. When the external voltage is removed, the constant voltage source is again ready for operation.

Claims (7)

8 f. f! > "T __ - * 3; '- 1 V- f i i - · ·"' 'PATENT N AND RD ΐ <Y ____________ _ j 1. A DC voltage test apparatus for generating a measured current through a measured object, in particular for measuring the resistance of protective conductors and balancing the voltage, and with a protective circuit for isolating foreign voltages applied through the measured object, characterized in that a blocking diode (V4) is connected to the current circuit between this object and the voltage source (Ug) and the same polarity on the other side of the measured voltage is applied to the current circuit between the object and the voltage source (Ug). (Rx), a controlled semiconductor switch (V8) is connected to the current circuit between it and the voltage source (Ug), wherein the control circuit (L) of the semiconductor switch (V8) is sized to close the current circuit when -current voltage from DC voltage (Ug) and voltage exceeds the threshold voltage threshold (V5) belonging to the control circuit (L), and the threshold voltage is higher than the DC voltage (Ug), and the switching path (DS) of the semiconductor switch (V8) is closed once the sum voltage drops below the threshold voltage. Test apparatus according to claim 1, characterized in that the controlled semiconductor switch (V8), in addition to its closing function, also serves as a control element in the constant current regulating circuit (K). Test apparatus according to claim 2, characterized in that the control circuit (K) comprises a control amplifier (V3) which is connected to the feedback resistance (R5) in the semiconductor switch path (DS) by its inverting input (-). V8) and compares the feedback voltage arising therefrom with the reference voltage applied to its non-inverting input (+) and generated on the next reference element (V2) and supplies the control input (G) of the semiconductor switch (V8) the corresponding output signal. Test apparatus according to one of Claims 1 to 3, characterized in that the control circuit (L) comprises a control transistor (V7) which is connected between the control input of the semiconductor switch (V8) and the opposite end thereof by its collector-emitter path. the feedback resistor (R5) and whose base is connected to the voltage divider resistors (R3, R4), which is connected in series with the threshold element (V5) of the control circuit (K), wherein the resistor voltage divider (R3, R4) bridges the switching path (DS) a semiconductor switch (V8) with a series feedback resistor (R5). Test apparatus according to one of Claims 1 to 4, characterized in that it is connected in parallel to a series circuit consisting of a switching circuit (DS) of a semi-conductor switch (V8) and a feedback resistance (R5). varistor (R6). Test apparatus according to one of Claims 1 to 5, characterized in that at the output (A, B) of the serial circuit formed by the blocking diode (V4), the DC source (Ug), the feedback resistance (R5) and the switching path (DS) of the semiconductor switch (V8) is connected to the measured object (Rx) closing the current circuit, whereby the voltage drop at this measured object (Rx) decreases the measuring circuit (M) and eventually indicates it. Test apparatus according to one of Claims 1 to 6, characterized in that the semiconductor switch (VB) is a power transistor, in particular a transistor array, whose emitter-collector path (D-S) forms a switching path and the gate electrode (G) control input. 11 List of reference numbers UQ - DC sourceK - regulation circuitA, B - input terminalsR χ - measured in the circuit - V-blocking diode DS - switching path Vg - field-effect power transistor - controlled semiconductor switch rj - feedback resistance G - control input V3 - control amplifier V2 - reference element R1 - resistor - auxiliary voltage L - control circuit V5 - reference element threshold R3, R4 - divider V7 - control transistor R6 - resistor - varistor Cl - filter capacitor - diode R2 - resistor π π · ·