DE1616091C - Circuit arrangement for high-resistance continuity testing of lines - Google Patents

Description

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the state can gain almost the full no-load voltage of the batteries within a specified limit. Nevertheless

low resistance occurs at the test terminals. In this arrangement, too, there is another one

there is also the risk here that the voltage disadvantage is that with a low-resistance test object

and current-sensitive components during testing are too high for current-sensitive components

be harmed. Since the power consumption of the arrangement 5 current of several milliamperes through the test object

voltage is quite high, the battery voltage flows and that in the case of a test object with high

relatively quickly. As a result, resistance changes one for sensitive components to

also the acoustic indicator, so that from sound- high voltage of the order of 1 to

height and volume no reliable information 1.5VoIt are low-resistance at the test terminals

can be gained through the resistance of the test object. io can.

Another known electronic check number is in U.S. Patent 3,284,707, attempting a scarf these disadvantages are described by a measurement with a device arrangement for the continuity test, Bypass alternating current. It contains a phase that works with a blocking oscillator, whose Frekette oscillator, the frequency fed by a battery through the test object between 1 and 600 Hz will. The oscillator can be changed by a resistor in the 15. This arrangement has two measuring emitter circuits strongly negative feedback and can therefore open areas, one for resistances between Do not swing idle. Parallel to seeing zero and infinity, with the test specimen directly With the coupling resistance, the test terminals are switched into the control circuit of the blocking oscillator connected a capacitor. If the between and the resistance is zero, the frequency is 600 Hz see the DUT connected to the test terminals an ao and the resistance Infinite the frequency 1 Hz has very low resistance, the negative feedback is equivalent, and a second measuring range for resistance circuit through it in terms of alternating current, or would be between zero and about 50 Ω, in which the less bridged and the oscillator for the vibration blocking oscillator is preceded by a transistor, desgen brought. Naturally, however, the resistance is emitter on one through the test item and one area in which vibrations are possible, very 25 further resistance is formed by a voltage divider, narrowed and is roughly between 0 and 30 Ω, and in this case the resistance corresponds to zero the same is the area in which the oscilla frequency is 600 Hz and the resistance 50 Ω is the Fretor frequency depending on the resistance of the quenz 1 Hz. In both measuring ranges, however, can as-test object changes, very small and is barely 10% of the current through a low-resistance test object the fundamental frequency, so that with this arrangement 30 flow of several milliamps and at one neither tests on high-resistance objects, e.g. very high resistance, almost the full battery Forward direction polarized diodes, applied low-resistance voltage to the test terminals can, still distinguishable statements about ten, so that current and voltage sensitive objects approximate amount of the measured resistance to project, z. B. elekerhalten the input and output transistors are. But it is precisely in mediation facilities that are destroyed and similar complex systems from the. Like all other known arrangements It is of great importance that when scanning the lead one also has the disadvantage that it is only a clear acoustic display over the a very imprecise acoustic display over the respective resistance at the test terminals up to resistance between the two test terminals supplies, there contains higher resistances, since one can derive from it 40 the relationship between oscillation frequency and directly on the objects that are not even remotely located between the clamping resistance of the test object located, can close. The measurement with near is. In addition, even small changes in alternating current have an effect also brings about the essential issues of battery voltage, temperature and The disadvantage is that their results are not definitely age-related changes in the transistor paras, as they have a very strong effect on the use of vibrations and the can be easily falsified. Vibration frequency off. Therefore, this too

Furthermore, an electronic test buzzer arrangement when checking telecommunication lines is unknown (British patent specification 1017 251), which does not distinguish from gene whether the line consists of an astable multivibrator, which is controlled by one of the ends directly or via ohmic resistors or transistor amplifier stage in such a way that 50 over one or more polarized in the forward direction, it either oscillates or is blocked. The diodes to be tested or one or more transistor stretching resistors are connected to one another in series with a lower one, which often occurs with an electronic series resistor in the switching systems seen by a second. The voltage source supplying the control circuit of the amplifier is switched on because of the large number of lines in the telecommunication server and in this way influences the communication systems, but it is of particular importance to set the operating point of the amplifier stage. Since the fact that these different cases can be recognized quickly and the available control voltage can be compared to the certainty, in order to reduce the otherwise very low operating voltage of the multivibrator, lengthy tests can be simplified,
only two cases can be distinguished. The invention is based on the object of creating a testing resistor below a certain circuit arrangement, by means of which the Lei limit value lies, the amplifier supplies an output that can be tested without the need for an intermediate voltage that switches the multivibrator to the oscillator or brings electricity connected at the ends; If, on the other hand, the resistance to be tested and voltage-sensitive components are damaged, greater than the limit value mentioned, the output will be, but their presence and voltage of the amplifier are very small, and the multi-type can also be correctly identified. This vibrator task remains blocked. With this arrangement, according to the invention, in a circuit arrangement, no statements can be made about the size of the test for high-resistance continuity testing of lines, lings, but only about its overflow or underflow, in particular telecommunication lines, with direct current

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and acoustic display of the test result is coupled with the adjustable voltage divider,

an oscillator with a connected loudspeaker, in such a way that the calibration is carried out by plugging in and

at which the measuring current is turned over a series resistor to the point of application of the test terminal

is fed into the test object and the pre-resistance oscillator oscillations can occur,

stood at the same time as a resistance to Arbeitsspuükt- 5 In the following the invention is based on a

setting of a DC voltage amplifier is used in F i g. 1 illustrated embodiment in more detail

to the output of which an oscillator is connected, described and explained in its mode of operation,

its use of vibration by the output voltage Fig. 2 gives some details about the me-

control of the amplifier, thereby solving the mechanical structure of the calibration socket and the assigned

that the DC voltage amplifier has a differential test terminal again.

is stronger, the first input of which is connected to the high-resistance. The arrangement according to FIG. With the help of an adjustable voltage divider between the resistor 17 and the Zener diode 8, it is possible to set the output voltage from a stabilized voltage of about 5 V ge differential amplifier to such a value. This voltage is applied to the test object R _x , which corresponds to the test object, via one of the bar that is present at a resistance at the test resistors 3/1 and 3/2, which corresponds to the end value of the display range. is just that big; that the oscillator is connected to terminals 1 and 2. Terminal 1, with its highest frequency and lowest amplitude, is expediently designed as a test probe and begins to oscillate. 20 mechanically coupled to a contact 7 in the voltage-The starting point of the oscillations of the oscillator feed; which is only closed, as mentioned above, is a certain one when the probe 1 is used. As assigned to the resistance value of the device under test. As a result of making contact, a high level of display accuracy is achieved later on by means of. So that the F i g. 2 described;

Allocation even after a long time and below 25 The series resistor is in the example shown

different conditions is true, is in a white 66 kO large. As a result, R _x flows through the test item

Formation of the invention a calibration option for a current of at most 75 μΑ when R _x - 0. On

given that for the exact determination of a resistance R _x of 100 Ω, a

Vibration start to the pre-resistance a voltage of about 7 _S 5 mV, from which the on

The size of the end value of the display range corresponds to a test object of 100 Ω output power

ehender calibration resistor is connected} whose 0.6 μW is calculated. The highest performance that

second connection can be brought out and can be handed over to a test object for calibration,

the test not connected to the series resistor runs on 90 μW; This can also do a lot

terminal is connectable. sensitive objects such as planar trans-

In order to achieve a higher accuracy with the mainly 35 sistors; not be damaged;
To obtain interesting values, the pre-resistance 3/1, 3/2 is narrowed in the middle under the display area. For the application it is divided, and its center tap leads to the input, however, even if with values beyond an impedance converter stage 1O ₅ the display signals high in the actual test range - input resistance and a low output ¹ - are supplied, albeit with a lower one Gensmg- 40 has resistance. A zener diode 9 in the input unit. Therefore, an advantageous development of the circuit of the impedance converter stage is used; possibly the invention characterized in that for area voltages occurring at the test terminals switching the pre-resistance from several in to derive. The impedance converter stage 10 is made up of series and / or parallel-connected resistors on the input side with an input of a differential, which is partly connected to amplifier 11 via a range switch 45. The other input of this can optionally be switched on and the various amplifiers - also correspond via an impedance end values of the display areas. converter stage 14 - to a voltage divider 15 to If there are several display areas * closed * the one of several in series and in parallel, each area should be calibrated separately. The switched resistors are built up. In one embodiment of the invention, one of these is 50 resistors, the resistor 15 / lj is a balancing effect that as many calibration resistors as display potentiometers and areas that can be readjusted during calibration are provided which are unipolarly combined. The resistor 15/2 is also adjusted and connected to a calibration socket and with the bar, so that any changes that can be connected to the series resistor through another pole via the range switch, the aging of the components, can only be switched on after a long period of time. 55 result, can be taken into account if necessary. The parallel resistor 15/3, on the other hand, is connected to test terminals. At the same time it must be of lesser importance. He should only be connected to the tolerances and the operating voltage source. the remaining resistances and the one-time calibration is then carried out by readjusting the fixed setting of the arrangement,
adjustable voltage divider at the second input of the 60 between the two outputs 12 and 13 of the differential amplifier. An advantageous further development of the differential amplifier 11 is the oscillator 16 of the invention, which simplifies the calibration process. It contains a germanium transistor that the calibration resistor is connected to a socket which is inversely - ie with swapped emitter and which is operated when inserting the relevant test terminal Kollektoranschlussö - so that the contact for the 65 oscillations is already established in a manner known per se with a very small span voltage supply closes and also connects the voltage, about 35 mV, between the outputs 12 and test terminal with the calibration resistor and insert 13. The oscillator vibrations are also designed to be rotatable and mechanically ductile transmitted to an amplifier 18, which they

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with respect to the positive terminal of battery 20, the respective end value of the display range is the same,

and an earpiece 19 feeds directly. is a calibration circuit with resistors 5/1 and

The arrangement shown in Fig. 1 is included on 5/2. Resistance 5/1 is 100 Ω, designed for a display range from 0 to 100 Ω. Um and the resistance 5/2 10 ΙίΩ. With each actuation this, in relation to the series resistance, 5 of the range switch 4 is processed via the contact to the resistance range, the series 4/2 also form the resistance 3/1, 3/2 and the resistance R _{x to be tested for the switched-on display range} Corresponding calibration resistor to the series resistor is connected to one branch of a bridge circuit. The branch in question must consist of the voltage divider 15 for calibration. Mende calibration resistor 5/1 or 5/2 with the test The bridge is balanced when R _x about 130 Ω ίο connected terminal 1 and also the contact 7 is in. In this case, the differential amplifier supplies test terminal 1 to be closed. Then the 11 is no output voltage. At higher values adjust potentiometer 15/1 so that the oscillation of R _x occurs between points 12 and 13, although gate 16 just begins to oscillate,
voltage, but it is of such polarity that the calibration was carried out with one hand that the oscillator 16 cannot oscillate. At 15, the calibration resistances 5/1 and 5/2 are lower values of R _x arises between the jointly connected to a socket 6, which is shown in Fig. 2 points 12 and 13 a voltage of correct phase in section. The socket 6 consists of a layer that is just as high at R _x = 100 Ω, namely non-conductive material and has a breakthrough about 35 mV that the oscillator with its high, through which a contact 23 into the interior the socket most frequency and lowest volume is led to vibrate. The contact 23 is with the Eichwidergen begins. The starting point of the vibrations would be, here briefly referred to as 5, connected. With the potentiometer 15/1 in each case of the socket 6 the axis 24 of the potentiometer can be set exactly to R _x = 100 Ω. Rigidly coupled in the area between 15/1. The input of the socket 6 see R _x - 100 Ω and R _x = O Ω increases the output has at least one flat surface 22, and the voltage of the differential amplifier approximately linear 25 same, the contact tip of the test terminal 1 from 35 mV to about 70 mV . The frequency of the oscil- at least one flat surface 21. When the Einsteklator voltage changes in this area by about ken the test terminal 1 in the socket 6 is a factor of 3; it goes from about 4.5 kHz to 1.5 kHz, a coupling between these two parts is achieved. As a result, the resistance values, which have the effect that when rotating the test object R _x, can be estimated very precisely by ear. 30 test terminal 1, the socket 6 is also rotated.
Another help here is the volume, which The test terminal 1 contains two contact springs, in the area mentioned also large changes, one of which is subject to the conductive contact tip, since the voltage on the earpiece drags, while the other in the idle state is about 100 mV at R _x = 100 Ω up to almost 5 V with contact under the action of a spring - R _x = O increases. 35 tip not touched. Only when the test terminal opens

In order to also _{be able to detect higher values of R x} - resistance meets and the spring is compressed, if a second spring is in the arrangement of Fig. 1, the second spring also reaches the conductive display area provided, which goes from 0 to 10 kΩ tip, and contact 7 is closed. Instead of and by means of a range switch 4 with two contact springs, a reed contact 4/1 and 4/2 can optionally be switched on. 40 Arrange the contact in the test terminal 1, which is cut off and switched via the contact 4/1, namely the one magnet resistor 3/1 of the series resistor that can be moved with the contact tip.

for this the resistance combination 3/3, 3/4 effective. Consequently, the test is made when plugging in. The resistors 3/3 and 3/4 are clamped 1 in the socket 6 selects the following three effects that their parallel connection at R _x = 0 achieves 45. By the pressure of the contact tip on the resistor 3/1 and at R _x = 10 kΩ the resistance contact 23, the connection with the calibration resistor 3/1 is made in series to a resistance of 100 Ω was 5 and also the contact 7 in the is equivalent to. In this way, the same test clamps for the voltage supply are closed, conditions that are up to 100 Ω for the test. Furthermore, a mechanical connection is now made between the test clamps via the coupling 21, 22, so to speak a hundredfold 1 and expands. The absolute display accuracy is now produced by the potentiometer axis 24, which of course is correspondingly lower, but it is important to adjust the potentiometer 15/1 by turning the test terminal 1, which is less important than the relative accuracy. The calibration process, which in turn has remained unchanged. thereby expands to a mere plugging in and

To ensure that the point of application of the 55 turn the test clamp until the oscillating

Oscillator vibrations in any case with the perator vibrations.

1 sheet of drawings

Claims (5)

1 2 The invention relates to a circuit arrangement for the high-resistance continuity test of lines, in particular telecommunication lines, with direct current 1. Circuit arrangement for high-resistance and acoustic display of the test result by means of Continuity test of lines, especially 5 of an oscillator with a connected loudspeaker, Communication lines ,. with direct current and acu, with which the measuring current via a series resistor Stical display of the test result is fed into the DUT by means of a and the Vonvider oscillator with connected loudspeaker, stood at the same time as a resistance to the operating point which the measuring current is used via a pre-setting of a DC voltage amplifier, stand is fed into the DUT and the io is connected to an oscillator at its output, Series resistor at the same time as resistance to its oscillation use through the output span operating point setting a DC voltage of the amplifier is controlled. Amplifier is used, at the output of which an oscillator is used to test the continuity of lines tor is connected, whose vibration use so-called Schnarrsummer known from a consist of the output voltage of the amplifier and 15 battery and an electromagnet controls is characterized, according to the principle of Wagner's hammer ar- that the DC voltage amplifier (11) a dif- work. The line to be tested is reference amplifier, the first input of which is directly fed into the current high-resistance series resistor (3) and laid out for the electromagnet. If you If the second input with an adjustable resistance is sufficiently small, a current flows Voltage divider (15) is connected, through which the energizes the electromagnet. Then the pulls the output voltage of the differential amplifier armature and interrupts the circuit, whereby (11) can be set to such a value that the armature drops out again, and the circuit again it closes at a resistance (R _x ) at the test terminal and so on. The constant back and forth men (1 and 2), which corresponds to the end value of the indicator movement of the armature, causes an audible purr, area corresponds, is just so large, "that the frequency and volume of the mechanical Oscillator (16) with its highest frequency and structure and the current strength, so also from lowest amplitude begins to oscillate. Line resistance, depend. The disadvantages of this 2. Circuit arrangement according to claim 1, the known arrangement consists in that to Erredurch characterized in that for the exact determination of the electromagnet a high current through the tion of the vibration application must flow to the Vorwider- test item and that in the case of a shelter (3) one of the size of the final value of the fracture between the test terminals the full empty display area Corresponding calibration resistor (5) running voltage of the battery over a low one is connected, the second connection of which is internal resistance at the test terminals. When and for calibration with the not with the 35 one with the test clamps, for example in a Series resistor (3) connected test terminal (1) switching system, a bundle of wires scans and is connectable. at the input of a transistor amplifier 3. Circuit arrangement according to claim 1, da- rät, can thereby zerdurch the input transistors marked that the area switchover will be disrupted. Each time you switch the the series resistor (3) from several sparks produced in series 40 armatures are also increased. and / or resistors connected in parallel (3/1 frequency voltages in adjacent lines in bis 3/4) exists, some of which are reduced by more than one, which lead to considerable disruptions. Schnarrreichswitch (4/1) Buzzer can be optionally switched on because of the constant mechanical and the different end values of the stress on the armature and breaker contact display areas correspond. 45 also has a short service life. Another 4. Circuit arrangement according to claim 1 disadvantage of these devices is that the frequency and the to 3, characterized in that as many calibration volume of their snarling copy and age resistances (5/1, 5/2) How display areas depend on the equipment and are therefore not comparable are seen that are unipolarly combined and provide information about the resistance of the test object, placed on a calibration socket (6) and with the 50 Because of the last-mentioned disadvantages one is in their pole via the range switch (4/2) more recently to electronic check numbers connected to the series resistor (3) instead of a Wagner hammer are. an oscillator with a connected loudspeaker 5. Circuit arrangement according to claims for acoustic display of the measurement result entchen 2 and 4, characterized in that the 55 hold. A known device of this type (the electrical calibration resistor (5) with a socket (6) connective equipment, 1966, no. 3) consists of a test terminal ( 1) in a manner known per se becomes the one to which the test terminals are in series. When contact (7) for the voltage supply closes, the resistance of the connected between the measuring terminals and, moreover, the test terminal with the test object closed is sufficiently small, the calibration resistor (5) vibrates and connects the rotating oscillator. Frequency and amplitude of the Schwinbar is designed and mechanically coupled to the voltage divider (15) that can be set audibly via a loudspeaker, which changes to a certain extent with the fact that the calibration is carried out by inserting and resisting the Test item, but also with turning the test clamp up to the point of use 65 the state of charge of the battery. A disadvantage of this can be the oscillator oscillations. The arrangement is again that the entire operating current for the oscillator flows through the device under test ¹ and that in the case of a test object with high