DE1541747A1 - Facility for functional testing of relays - Google Patents

Description

"device for functional testing of relays" (addendum to patent patent application P 14 66 685.4) Subject of the main patent, DBP .............. (patent application P 14 66 685.4) is a device for the functional test of relays with at least a working and / or closed switching contact pair and at least one field winding or other controllable electromechanical switching devices containing a Step switching means for switching the test processes, a signal compensation field for identification of the respective test process as well as optical error display means and one per se For automatic test equipment known programmers, depending on the type of DUT determines the test sequence with the help of a first stepping mechanism and also with the help of another, synchronized with the first step mechanism operated step switch mechanism the test positions according to a specified pole designation of the test item during the test sequence to the one provided with the same pole designation Signal lamp field transmits.

With the facilities of the Vorsteherlden, 0rt was the first opportunity created, Felais of different types with different Contact arrangements Regarding their functions z. B. the contact transition resistance, automatically and check the measured values visually or acoustically as a limit value or in the absolute To bring the size to the display. Such devices can also be used manually intervene in the measuring process. The test item is connected to the device with the help of an adapter connected.

If you want to test specimens with several excitation windings, you must to do this, a switchover must be made in the adapter. This is time consuming, so there is a need to improve these devices to the effect that the exciter occupancy switching can be done without interfering with the adapter.

Accordingly, the invention is based on the object of devices nor the main patent DBP ......... (patent application P 14 66 685.4) in this regard to design.

This task is paid for by facilities according to the main patent, which are characterized by a relay controlled by pushbuttons, which is used for test items with several excitation windings the excitation voltage coming from the poles of the One exciter winding to the other exciter winding urscholtet Particularly advantageous it is when switching the excitation voltage from one excitation winding to another not only manually by pushbuttons but also automatically can. This is achieved by switching the test object excitation @ Makes relay controllable via a pole of the program connector.

If several measurements are carried out in a row in an occupancy state are to be, which is often the case, the lustand of must be used for switching the excitation voltage provided relay when the program is advanced. Appropriate it is there when the person checking receives the exciter pole assignment displayed at the same time. Another advantageous elaboration of the devices according to the invention shows thus another relay on which, when the program is advanced, the status of the relay causing the excitation voltage switchover and by means of two Signal lamps display the exciter pole assignment.

When several series of measurements are carried out in succession automatically are to be, after all the desired measurements have been carried out at a certain The exciter pole assignment is the working position of the person responsible for switching the exciter assignment Relay and the relay holding this can be canceled again. Is to in a preferred embodiment of the device of the invention, another A relay that can be controlled via one pole of the program connector is provided, which controls the working position of the two relays mentioned above.

It is particularly useful, if not only for test items with several Excitation windings switch the excitation voltage automatically or manually without Intervention in the adapter can be made, but also the switching of the PrUflingspolari did. For this purpose, one embodiment of the invention is to be examined more polarized A push button switchable relay is provided that controls the polarity switches over on the excitation winding and this is indicated by means of two signal lamps brings.

In order to be able to carry out this switchover in an automotive way, one further, particularly preferred embodiment of a device of the invention the relay effecting the polarity switchover via one pole of the program connector designed controllable and has a holding account with the help of which it is even stop.

Since when testing a polarized relay, the armature positions cannot be determined in advance, must be part of an automatic measurement sequence at least two pole changes are made.

In order to be able to make these switchings automatically, a Another embodiment of the invention, another via a pole of the program connector controllable relay provided, which the working position of the polarity switching, cancels self-sustaining relay.

When testing relays, the response values of the device under test are also important of special interest. For this reason, in a preferred embodiment the invention provides possibilities to manually apply the test excitation voltage or to be able to isolate them. Two pushbuttons are used for this purpose by means of a relay the test specimen excitation voltage can be applied or switched off manually.

To devices according to the invention also for testing with alternating voltage Being able to use excited test subjects became an embodiment of the invention Created for optional operation with DC or AC excitation voltage. at In this version, a transformer and a relay supplying the excitation voltage are provided, the excitation voltage from the transformer either directly or via a rectifier the test specimen excitation coil applies as well as a voltage measuring unit for both operating modes, their access or. Shutdown also takes place through this relay. Should also the response current can be determined, an additional relay is to be provided for this purpose, which by means of two signal lamps to display the respective operating mode as well as one stroke mechanism each For both operating modes, which are also switched on and off by this relay he follows.

To avoid malfunctions in a preprogrammed Me # sequence that has already been initiated, be it through accidental or arbitrary manual input, it is It is expedient to provide a locking device for all manual input options. In a preferred embodiment, the Heinrich device according to the invention is used for this purpose a relay that is excited by the initiation of the programmed measuring sequence and blocks all manual input options.

In the devices of the invention, it is advantageous to reduce the excitation voltage of the test piece to be able to regulate continuously, for which purpose the primary voltage is expedient of the transformer supplying the test specimen excitation winding voltage. This is according to a preferred embodiment of the invention, a ring plate is provided, with the help of which the excitation voltage of the test specimen by setting the primary voltage of the transformer supplying the test sample excitation voltage can be continuously adjusted can.

Finally, it is essential with the devices according to the invention on an extraordinarily well stabilized measurement voltage, including a preferred one Embodiment a cadmium-nickel cell is provided.

The following is a particularly preferred embodiment of the invention explained in detail using the accompanying drawings.

In the drawings: FIG. 1 shows an overall view of the test device; Fig. 2 shows a section through the interior of the test device in a schematic representation; Fig. 3 Power supply part for the measuring and operating voltage with indicators for excitement; 5 shows the upstream for the introduction of the excitation voltage as well as the occupancy and polarity switching; Fig. 6 the two magnetic step switch with their closing circuit; 7 shows the circuit the start, stop, pulse and reset device; Fig. 8 the program connection # for the account compulsory field; 9 shows the representation of the measurement sequence on the receiving device for a test object with two changeover contacts; Fig. 10 shows a programming according to the embodiment according to Figure 9; Fig. 11 shows a contact arrangement, which with the present test facility can also be tested, with a provision the magnetic step switch takes place without interrupting the measuring and testing process; Fig. 12 the closing circuits of the two synchronously running stepping mechanisms in third impulse of a program template; and FIG. 13 shows the measuring circuit of the test device.

For a better understanding of the function of the test device, first the entire power supply is described with reference to FIGS. 1, 3 and 4.

The mains voltage comes through a fuse 22 and an operating switch 21 to the primary side of a transformer 28 and to the input of a ring actuator 193, the allows the continuous regulation of the primary voltage of an additional t94 transformer. A rectifier 30 (FIG. 3) supplies the measuring voltage for the contact or measuring circuit.

Sufficient stabilization is provided by a cadmium nickel cell 201 (Fig. 3), which acts as a buffer when the device is switched on through the working position of a relay 202 and connected via its normally open contact 203 to this voltage source The measuring voltage is finely adjusted by a controller 18 (FIG. 13), whereby a special measuring mechanism 9 (Fig. 1 and 13) should show full deflection. A destruction of the measuring mechanism 9 is as good as excluded. The condition according to which transition resistances can only be determined exactly when using the smallest measuring voltages and measuring currents, is also largely fulfilled with this Schaltungsan order. A second secondary winding 34 of the transformer 28 (Fig. 3) supplies via a rectifier 35 and the network Operating voltage for the test device.

With the help of a known multiple pushbutton assembly 11 (Fig. 4) You can use the secondary-side taps of a transformer 194 to determine the coarse voltage ranges (in the present test facility 2.5 -5 - 12.5 - 25 -50 - 125 - 250 and 500 Volts) for direct and alternating voltage.

The continuous voltage regulation takes place with the primary side connected ring actuator 193 (Fig. 4), with the help of the four changeover switches of the pushbutton assembly 11 (Fig. 4) for a coarse voltage setting can be: 1, ballast resistors 204 to 211 (Fig. 4) for the excitation DC voltage display at the same time, 2. additional series resistors 21.2 to 219 (Fig. 4) for apply the exciter alternating voltage display at the same time, 3. the Rough adjustment of the DC excitation voltage via rectifiers 220 and 221 for the Ranges 2.5 - 5 - 12.5 - 25 volts and via rectifier 222 for ranges 50 - Carry out 125 - 250 and 500 volts, and 4. the rough setting of the alternating excitation voltage for the ranges 2.5 - 5 - 12.5 - 25 - 50 - 125 - 250 and 500 volts, whereby a secondary-side tap for the desired voltage at the transformer 194 (Fig. 4) directly he follows.

Two power relays 195 and 196 (Fig. 3) allow in connection With two pushbuttons 223 and 224 you can switch between the two operating locations and exciter alternating voltage. After switching on the test device is initially by the rest position of relays 195 and 196 (Fig. 3) with the changeover contacts 225, 226, 227, 228 (Fig. 3 and 4) the operating mode DC excitation voltage switched on, what is indicated by a lamp 229 (Fig. 3) via the changeover contact 227, The corresponding ones are also located above the other changeover switch contacts 225 and 228 (FIG. 4) Display instruments in the circuit. On the cow side of the switchover contact 225 is a measuring unit 199 for direct voltage is applied. About the rest side of the retraining contact 228 there is a measuring mechanism 200 for direct current in the circuit. The operating mode is the alternating excitation voltage if desired, the switch-off takes place by actuating the pushbutton 223 (FIG. 3) the exciter DC voltage to the exciter AC voltage. The actuation of the push button 223 causes di. Work position of the Storkstromrelais 195 and 196, this Zus @ and is retained by the changeover contact 227 and at the same time one Signal lamp 230 (Fig. 3) indicates the operating mode exciter alternating voltage. The changeover contact 226 causes the switch-off through the working position of the heavy current relay 1.95 of the network for generating the DC excitation voltage, now about a Changeover switch of the pushbutton assembly 11 (Fig. 4) and the changeover contact 226 a The alternating voltage is picked up directly on the secondary side. About the already described Changeover contact 225, a measuring unit 197 for alternating voltage is applied. Simultaneously A measuring mechanism 198 for alternating current in the excitation circuit is connected via the changeover contact 228.

From the network (FIG. 3) there is accordingly one at connections 33 and 32 Stabilized measuring voltage for the measuring circuit described later, at connections 232 and 233 (Fig. 4) the excitation voltage as direct or alternating voltage and on Connections 42 and 41 (Fig. 3) provide the operating voltage for the test device.

However, in order to understand exactly the function of the entire test facility, the entire switchover control for the introduction of the exciter DC voltage is to be carried out for the time being with occupancy and polarity display for the test object (Fig. 5) are described, which is divided into three parts.

The DC excitation voltage applied to connections 232 and 233 (Fig. 4 and 5), which for the respective test object before the start of the measurement run through dar Push button assembly 11 (Fig. 4) described roughly and through the ring pin 193 fine some must be made, comes with the negative potential Via the idle sides of relays 236 and 240 to a connection point 256 of a receiving device 2 (Figs. 1 and 5) and with the positive potential 232 in that described later Working position of a relay 27 via 235 and 242 to 253 of the receiving device 2 (Fig. 1 and 5) of the testing device. The initiation of the excitation for the test object can basically only take place through the working position of the relay 27. the Excitation of relay 27 can by the program described later, which the automatic measuring sequence designed via connection 127 (Fig. 5) or by actuation the key 257. However, the latter is due to the placement of a relay 258 (Fig. 7) with the switches 259, 260, 26.1 and 262 (Fig. 5 and 7) only before the At the beginning or at the end of a measurement sequence, manual entries can be used to determine the fur the respective relay type is not the desired and therefore programmed measuring sequence disturb. Two lights 6 and 7 (Fig. 5) show Uber 145 the rest and Uber 144 the working position of the test object 24. The working position of the relay 27, which is retained by 144, causes the excitation of the test object 24 as well as 145, 237 and 247 the display of the excitation occupancy 263 and 269 with polarity indication. the Occupancy changeover from 263 and 269 to 265 and 267 (Fig. 5) is controlled by the control from 121 in the program or manually using a button 272 (Fig. 5). Here reaches, by the thereby triggered working positions of relays 239 and 244, which through 243 and 248 are retained, the excitation voltage U over 242 and 240 to 254 and 255 (Fig. 5) of the receiving device 2 for the test object 24. At the same time, the corresponding exciter occupancy numbers light up via a switch 247 265 and 267 with polarity display, whereas in the rest position the relays 239 and 244 apply the excitation voltage to 253 and 256 and via 247 corresponding exciter occupancy numbers 263 and 269 (Fig. 5) will illuminate. The pathogen occupancy numbers light up above 145, so simultaneously with the display 7 = work = work position of relay 27 = excitation of the test object 24. The resetting of an initiated pathogen occupancy 265, 267 to 263, 269 can be done by the program via a pole 123 (Fig. 5) or again before the beginning or at the end of a program manually with a button 271 (Fig. 5) take place. An impulse initiated by the program Uber 123 causes the working position of 249 and makes Uber a toggle switch 250 that keep Uber 243 and 248 Relays 239 and 244 (Fig. 5) de-energized.

Another advantageous embodiment of this test device is given by the arrangement of relays 234 and 251 (Fig. 5), reducing the polarity the DC excitation voltage in all voltage ranges mentioned in the exemplary embodiment, set with the push button assembly 11 and the ring plate 193 (Fig. 4) are switched and thus also polarized. Relays with any contact arrangement can be checked. The aforementioned switchover can also be carried out, as was the case with the Occupancy switching described, via the program according to 122 (Fig. 5) or manually by a button 274 (Fig. 5). An initiated polarity changeover Via 122 or the button ter274 causes the excitation of the relay 234 (FIG. 5), which then remains recovered via a changeover switch 238. The real one Two change-over switches 235 and 236 of the relay 234 (FIG. 5) change the polarity.

This reversal clearly shows that now 253 are negative and 256 of the receiving device 2 becomes positive. Finally takes place through the working position of relay 234 and changeover switch 237 the correct polarity display. A provision into the starting position, which in turn means switching the polarity Can be programmed via pole 124 or in the same way as for all others already described Switching functions, manual, when switching polities with a button 273 (Fig. 5), are triggered. If the programming takes place via 124, i. H. arrives a Pulse after 124, the Uber becomes a relay that is held by its own contact 238 234 is de-energized by the excitation of 251 and the opening break contact 252 (FIG. 5). This means that the Umscholtkontakte 235, 236, 237, 238 of the relay 234, which are in Circuit of the excitation voltage to the receiving device 2 are, again the rest position take in. Again, the exciter occupancy numbers light up with the correct one Polarity indication by the rest position of 234 and 237.

Using FIG. 7, which shows the circuit for the program block, the start function is to be described below. The actuation of a start button 12 (Fig. 7) causes the working position of two relays 133 and 258. The relay 133 is held via its AI working contact 135 and the relay 258 is held via 259. ras re lais 258 with its four changeover contacts 259, 260, 261, 262 locked, triggered manually. Functions that initiate the excitation voltage and the exciter occupancy and polarity switching. This happens on the following Way: A changeover contact 261 interrupts the circuit through its working position to the button 257 (Fig. 5) for introducing the excitation voltage, with a simultaneous Key 275 to initiate the rest position of a possibly excited test object 24 is briefly closed. A manual introduction of the excitation voltage to the holding device 2 or to the test object 24 is therefore through the interrupted circuit of the button 257 to relay 27 not possible. An introduction can only be made through the program Via pole 1.27 (Fig. 5). After the button 275 (Fig. 5) is short-circuited by 261, you can manually enter an already in the Uber 127 program by the working position of the relay 27, which is via the working contact 144 holds itself, excited test object cannot be brought into the rest position, since the Button 275 is short-circuited with its normally closed contact by 261 and the power is lost of the relay 27 and thus the rest position of an already excited test object 24 is only possible via a provision 15 described later. The same also applies to the switchover of the excitation occupancy, which is also done via the switch 261. of relay 258 interrupts the circuit to button 272 and this switchover prevented during a program call. The manual polarity switching is by the changeover contact 259 of the relay 258 prevented. Which now in detail described functions of preventing the manual Input, which are not desired during a programmed measuring and test sequence apply finally also for the last two reversing contacts of relay 258, where 262 prevent a changeover of the assignment and 260 a changeover of the polarity, The relay 133, which is also excited at the start and which holds over 1.35, takes over the initiation of the automatic measuring and testing process, initially with a pulse generator 25, 26 (Fig. 7) whose time from pulse to pulse by a POtentiometer 1.67 (Fig. 7) can be continuously changed by being put into operation. That through t34 energized relay 25 then causes a normally open contact 138 to energize a Relay 26. With this working position, the circuit of relay 25 is through 141 interrupted.

Only the rest position of the delayed releasing relay 26 triggers the Repeat the process described. An Uber 140 and a potentiometer 167 charged capacitor 276 causes relay 26 to drop out with a delay. The pulse generator 25, 26 finally controls two step switches 46, 47 (Fig. 6) whereby over 136 step switches 46 and via 139 step switch 47 is controlled. The step switch acts they are electromagnetic relays with a main and sub pole with ten of each other independent closing circles, a tightening winding and an ejecting winding. The armatures are activated individually and one after the other by impulses on the pull-in winding are given, attracted to the main pole. By being remanent this main pole will be the individual anchors also held in the pulse pause. These anchors are also Assigned to ten groups. By a magnetic counter-excitation Above the discharge winding can be done in any position of the armature or the closing circles all armatures are reset The mode of operation of such a magnetic relay is assumed to be known. The two step switches 46 and 47 (Fig. 6) have two separate tasks in the circuit in the embodiment Step switch 46 controls the MoB circuit to determine the static contact resistance of the test objects, whereas through 47 the program required for the test object Is placed via a program plug 5. The one from relay 25 (Fig. 7) via 139 (Fig. 6) controlled step switch 47 with its contacts 178 to 187 (Fig. 6 and 12) according to 48 to 57 and the corresponding connections in program plug 5 (Programming for the respective relay type or contact arrangement) design the entire automatic Me # and test call.

With corresponding connections in the program plug from 48 to 57 still 85 to 96, 97 to 108 and t09 to 120, where 85 to 96, 97 to 108 and 109 to 120 (Fig. 8) represent the connections of the lights for the contact number display 8, For any contact number assignment of a test object 24, the corresponding Contact numbers, which are each located in the measuring circuit, via the step switch 47 with its contacts 178 to 187 after 48 to 57 and the corresponding connections are displayed in program plug 5. At the same time you can with any Position of the step switch 47 desired programs of the excitation voltage introduction, Ex @ excitation and polarity switching, which are already detailed have been described. For a better understanding, a Programming for a non-polarized relay (Fig. 9) with excitation 277, 278 and two changeover switches are shown, the number of which can best be seen in FIG is.

It was already mentioned in the description of the test facility's start function executed that by the pulse generator 25, 26 Uber 136 and 139 the two step switches 46, 47 can be controlled. The first pulse would therefore be due to the synchronous operation of the two step switches, the changeover switches 168 and 178 close, with 168 the measuring voltage (Fig. 6), line 32 to 61 and 178 the plus potential of the operating voltage 42 (Fig. 6) brings to 48. 48 in connection with 89, 90, 91 leave the Idle account numbers 279, 280 light up, where 168 is the measuring circuit of pole 61 of the On @ ahmevorrichtung 2 via the normally closed contacts 279, 280 of the test object 24 to 70 (Fig. 9) closes. With the second impulse, the normally closed contact numbers 282, 283 light up on and in the measuring circuit are the rest contacts 282, 283 from 62 to 70 (Fig. 9). figure 12 shows the closing circles 170 and 180 at the third pulse of the pulse generator 25.26.

The arrangement of the relay 27, which, as already described, causes the excitation voltage to be introduced and its changeover contact 143 (Fig. 7) which still switches 125 or 126 in the program, idle and normally open contact numbers can be displayed already electrically separate from each other, which is a significant simplification is given in the programming.

So it happens that # with the first and second impulse of the program sequence due to the lack of the negative potential at 103 or 106 and the rest position of 143 to 125 the contact number 281 for the first and the contact number 284 for the second Impulse does not light up. Excitation exposure initiated by the Uber 50 after 127 (Fig. 10) the relay 27 is energized. This, through the switch 143 of the relay 27 in Program from 125 to 126, automatically switching negative potentiol 41 to 39 has the consequence that now with impulse three the contact number 281 and with impulse four the account number 284 lights up, with the two work accounts at the same time 280, 281 (third pulse) and 283, 284 (fourth pulse) of test specimen 24 in the measuring circuit About the recording. device 2 (Fig. 1 and 2) from 63 or 64 to 70 (Fig. 9) after the contact numbers 280 and 283 ends over 102 and 105 after 132 are directly connected to minus, the normally closed contact numbers appear on the first pulse 280, 279, with the second pulse 283, 282, with the third pulse the make contact numbers 280, 281 and on the fourth pulse 283, 284 for display.

The connection of 50 and 121 (Fig. 1o) also causes the excitation voltage to be introduced 127 also the switchover from 253, 256 to 254, 255 (Fig. 5). Still the measurements of the two rest and work accounts required on the examinee Determination of the transition resistances on the contact materials have been made with pulse five the entire measuring and test sequence through the one described below Reset by means of a link m program plug 5 from 52 or 128 (Fig. 10) can be terminated. This reset can also be done manually during a program via button 15 (Fig. 7) or by programming 48 to 57 (Fig. 6 and 12) to 58, 59 and 128 (Fig. 7l. Those with the numbers 149 to 159 and 286 to 289 (Fig. 5, 6 and 7) designated normally closed or normally open contacts of the test facility characterize these functions. By arranging two relays 146 and 147 (Fig. 7) is the stated resetting of the two magnetic step switches 46 and 47 in their auto gear position without interrupting the measuring and testing process possible, whereby almost all of the center-stroke arrangements occurring in practice are checked can.

As an example, FIG. 11 shows a test object with an account order of three changeover switches and three other normally closed contacts is presented. They are accordingly six normally closed and three normally open contact measurements required. By the arrangement the relays 146 and 147 (Fig. 7) can be said contact arrangement properly check, although there are only nine closing circuits in the measuring circuit of the step switch 46 are.

This is done in the following way: In the first pass, the Normally closed contacts 290, 293, 296, 299, 301, 303 measured over 61 to 66. On the second pass, after the excitation has been initiated, the work accounts still to be measured become 292, 295, 298 via 61 to 63 (Fig. 11) are displayed.

The arrangement of the relays 146 and 147 generally enables this End of the automatic measurement sequence in the first pass through 58 (Fig. 7) of the program plug 5 and in the second run at any position of the program step switch 47 over 59 are initiated. There is also the possibility even the most complicated account orders, for example follow-up, idle, work contacts, to consider.

Should a reset be desired when the measuring process is completed this can be programmed via pole 128 (FIG. 7).

In the test object 24 shown in FIG. 9 with two changeover switches this would mean that a connection from 52 (= impulse five) to 128 in the program plug 5 must be made. The relays 148 thereby going into the working position and 285 (FIG. 7) foils over the initially charged over 156 and the resistor 305 Capacitor 306 and the resulting discharge through the working position delayed from 156. As already described in detail, the two are magnetic Step switches 46, 47 brought into their starting position by their shedding winding.

This is done via the working contacts 157, 159 for discard processing the two step switches 46, 47 (Fig. 6), other work contacts of the relay 148 and 285 (FIG. 7) cause the reset of any initiated in the program and the functions of pathogen initiation, pathogen occupancy and Polarity switching. Relay 285 with changeover switches 287, 286 causes the stop of the pulse generator 25, 26 being by the Changeover switch 1.34 the relay 25 is de-energized. An existing excitation is caused by the drop in relay 27, switched off by 157 (Fig. 5), this rest position and thus also the rest position of the test object 24 is indicated by the indicator light 6 (FIG. 5) via 145 and at the same time the exciter assignment numbers 263 to 270 go out. The already the functions of the excitation occupancy and polarity switching described in detail, which may have been introduced in the program according to the test object by a further normally open contact 288 (FIG. 5) of relay 285 (FIG. 7) again brought into the starting position, with any work in progress and yourself self-holding relays 239, 244, 234 (Fig. 5) are de-energized. The one in resetting Inactive relays 133 and 258 now allow over the respective break contacts a manual input of the excitation, excitation and polarity switching. A push button 257 (FIG. 5) receives its positive voltage via the normally closed contact 261 42 to control the relay 27. Dos The same applies to the assignment and polarity switchover, whereby the assignment 254, 255 to the receiving device 2 (Fig, 5) via the rest contact 261 and a button 272 (Fig. 4) and dex polarity growth over a normally closed contact 259 and a button 274 manwell can be vorgenemmen. The manual return Via the button 15 (Fig. 7) the entire automatic M @ # sequence is terminated in any case. In the programming, this would be equivalent to a pulse of 128, whereby also the two relays 148 and 28 are er @ gt4 After a test object 24 (Fig. 11) in the first run the six normally closed contacts 290, 293, 296, 299, 301st and 303 have come to the display, the reset is at pulse seven of 54 still 58 initiated without interruption of the measuring process. In the second run must, after still measuring the three working contacts 292, 295, 298, at the fourth Impulse the measuring sequence is ended. Before the programming to the one shown Contact arrangement (Fig. 11) is explained further, let us first look again pointed out that the resetting of the step switches 46, 47 in each. Case at tenth pulse must take place. In the exemplary embodiment, this reset takes place at seventh pulse of 54 (Fig. 6) still 58 (Fig. 7). That initially aroused and then by a capacitor 307 charged over 150 after 150 delayed falling Relay 146 causes a pulse via normally open contacts 149 and 152 (FIG. 6) bring the desired return to the discharge coils of the step switch 46, 47 without interrupting the test run. Another working contact of 146 brings through 151 the relay 147 located above the normally closed contact 159 (FIG. 7), which then Uber holds his own contact 155. This working position results through the normally open contact 153 of the relay 147 a connection from 59 to 128 (Fig. 7). An impulse after 59, now initiated by the program, would already be the reset, which is described in detail, also applies to itself holding relay 147 by energizing 148 with its contact 159 to waste would be brought. After six measurements are made in the first run and accordingly three more required must be in the second run in the fourth Pulse the entire test sequence can be terminated, which is indicated by the connection from 51 after 59 (Fig. 6 and 7) in the program plug 5 is reached. One can now clearly recognize that the mentioned connection from 51 to 59 has no meaning in the first pass has, because due to the rest position of the relay 147 through 153 (Fig. 7) no electrical Connection between 128 to 59 exists. It can therefore contact arrangements with a maximum of nine toggle switches (s eighteen automatic measurements), which, however, are in the Practice kcum occur, be checked. With the button 13 (Fig. 7), the break contact the initiated, programmed Ma # and Prufob can run at any Measurement on a test object can be stopped, whereby the Stremkreis of the self-sustaining relay 133 over 135 nor? Ol 42 of the @etriobssvoltage is interrupted. Possibly already in the program eGuided functions of the excitation, Assignment or polarity are retained by the working position of relay 258. This must be initiated manually when a poor contact resistance occurs The stop function can also be performed automatically using an adjustable limit indicator 10 (Fig, 1), which has a normally closed contact, trigger. When the Set limit value opening break contact 10 (Fig. 7) makes the Uber 135 holding relay 133 de-energized, the pulse generator 25, 26 through 134 in already is stopped as described. By pulling off the defective test object 24 the display of the incorrect contact number remains recovered and another sequence of the program, by pressing the button 12 again by the circuit interruption 41 of 83 still 84 of the receiving device 2 prevented. The measuring circuit is opened by the absence of the test piece 24 and the measuring mechanism shows full scale again.

The pulse generator 25, 26 can by the button 14 (Fig. 7), which is with is provided with a working contact, can also be operated manually. This will go through the negative potential of the operating voltage of the pulse generator 25, 26 is excited, which at the same time the advancement of the two crotch switches 46, 47 causes and it can thereby the programmed measurement and test sequence, which has already been described in detail, is accelerated will. In the main, however, the button 14 is only used for measurements that are not desired a contact arrangement within a program sequence or in the event of a repetition actuated. The measuring circuit already mentioned (Fig. 13) is made up of the special twin circuits 168 to 176 (Fig. 6) of the magnetic step switch 46, all of which are optimal Have the same resistance, Uber 61 to 69 and Uber the respective contact to be measured of the test specimen formed according to 70 of the receiving device 2. When open. Measuring circuit the full deflection of the measuring mechanism is set with a controller 18 (Flg.13), which is also the end point of the measuring circle. Here, the measurement voltage is at the Measuring mechanism 9 with an internal resistance of approx. 15 ohms, 5 m-V.

A wire resistor 31 is of the order of magnitude parallel to the measuring mechanism from 80 ohms. This circuit arrangement results in two further great advantages. Firstly, destruction of the measuring mechanism 9 is excluded and, secondly, that Condition, which still Transition resistance probes on the contact materials of a test object only when using the smallest measuring voltages and measuring currents exactly can be determined, largely fulfilled. To fix vna review of the electrical Zero point of the Ohmeichung on the directly calibrated scale of the measuring mechanism 9, which as a result of the constant contact resistances 168 to 176 of the magnetic step switch 46 and the silver wire lead from the measuring mechanism 9 to 70 of the recording arrangement 2 is about 1/5 of the scale length in front of the mechanical zero point of the measuring mechanism 9, is a pluggable standard instead of the test items 24 as a short-circuit bridge between 70 and 61 to 69 attached.

This standard is attached to the receiving device 2.

With all closed positions from 61 to 69 above the zero point emergency after 70, the display may only deviate slightly from the zero point of the ohmmedification. This means that when measuring a test object, only the actual Transition resistances of a contact arrangement are displayed. The rash of the Measuring mechanism 9 is therefore of the size of the transition resistance on the contact materials of a test object and is ii range from 0.005 to 1.2 ohms directly to the Display brought.

After a voltage of 5 m-V is present, there is a voltage drop at 18 of about 1.25 V.

For the short circuit from 70 to 61 to 69 (Fig. 13), which is the zero point the ohmmalization and is shown with the zero point standard attached as test object 24 becomes 1/5 the voltage at the measuring mechanism 9, i.e. 1 m-V. For the lead resistance results in a resistance of approximately 20 m-ohms.

This means that minor errors in the measuring circuit are of no significance for dos Measurement result.

Claims (1)

Claims 1. Device for functional testing of relays with at least one working and / or closed switching contact pair and at least one excitation winding or other controllable electromechanical switching devices containing a Step switching means for switching the test processes, a signal lamp field for identification of the respective test process as well as optical error display means and one per se programmer known for automatic test equipment, which depending on the type of The test sequence is determined with the aid of a first stepping mechanism and also with the help of another, synchronized with the first scrap plant operated stepping mechanism the test positions according to a specified pole designation of the test item during the test call to the one provided with the same pole designation Signal lamp field Transfers according to patent ......., .., ... (Patent application P 14 66 685.4), characterized by a push button (272) or (271.) controlled relay (239), dos for test objects with several excitation windings the excitation voltage coming from poles (232) and (233) from one excitation winding (253; 256) switches to the other field winding (254; 255). 2, device according to claim 1, characterized in that the relay (239) is controlled to minus via a pole (121) of the program plug (5). 3. Device according to claim 2, characterized by another Relay (244) that receives the status of (239) when the program is advanced and by means of two signal lamps that display the exciter pole assignment. 4. Device according to claim 3, characterized by another Via a pole (123) of the program plug (5) controllable relay (249) that the Relays (239) and (244) are in the working position. 5. Device according to claim 1, characterized by an Uber push button (274) and (273) switchable relay (234) that changes the polarity on the excitation winding switches over and displays it by means of two signal lamps. 6. Device according to claim 5, characterized in that the relay (234) is controlled via a pole (122) of the program plug (5) and itself holds. 7. Device according to claim 5 and claim 6, characterized by another relay that can be controlled via a pole (124) of the program connector (5) (251), which cancels the working position of the relay (234). 8. Device according to claim 1 to claim 7, characterized by two pushbuttons (257; 275) through which the test object excitation voltage is activated by means of a relay (27) manually can be created or switched off. 9. Device according to claim 1 to claim 8, for optional operation with DC or AC excitation voltage, characterized by the excitation voltage supplying transformer (194) and a relay (195) that takes the excitation voltage from the transformer (194) either directly or via rectifier (220; 221) to the test object excitation winding applies as well as a voltage measuring unit (197; 199) for both operating modes, with their The relay (195) is also used to switch on and off. 10, device according to claim 9, characterized by a further Relay (196), which uses two signal lights to indicate the respective operating mode Display brings, as well as a current meter (198; 200) for both operating modes, their The relay (196) is also used to switch on and off. 11. Device according to one of claims 1 to 10, characterized through a relay (258), which is triggered by the initiation of the programmed measuring sequence is excited and all manual input options are blocked. 12. Device according to one of claims 1 to 11, characterized by a ring plate (1.93) for continuous Regulation of Excitation voltage of the test item (24) by setting the primary voltage of the transformer (194). 13. Device according to one of claims 1 to 12, characterized by a cadmium-nickel cell (201) to stimulate the measuring voltage.