DE1296261B - Device for functional testing of relays or other controllable electromechanical switching devices - Google Patents

Description

The task of a relay to switch the secondary energy circuit, the contact takes over. In its simplest form, this switching process is a closure or interruption of a circuit. Often, however, a relay is a series of contacts that can be called idle, work, switchover, twin work, follow-up contacts etc. designated, assigned.

Making contact requires a force which, however, affects the primary circuit, d. H. on the excitement.

Safe contact actuation is the main task of the relay and the Execution of the contacts is the basic task of the entire construction. The one at the beginning The mentioned secondary circuit acts back on the primary circuit, which in turn is dependent the necessary contact load, the contact paths for suit and waste. Next to For the requirements already listed, the greatest task falls to the contacts.

There is a fault in the contact if the known Influences from foreign layers or so-called skin layers, caused by organic vapors, chemical influences, pollution of the narrow resistance as well a contact deformation or metal migration, etc., the contact resistance in a the order of magnitude is no longer desired, about 0.1 to 0.5 ohms. For determination the contact resistances under the known conditions may be measuring voltage and measuring current do not exceed a certain value.

The contact actuation can be described as good if the contact in the closing circuit with a corresponding contact resistance briefly without Side effects, such as bruises, etc., work.

The quality of a contact is therefore mainly determined by the transition resistance determined at the closing point of the contact materials. To measure these contact resistances, which is known to be in the order of magnitude for normal contacts between 0.005 and 0.1 A number of devices are known. However, these have to be carried out Measurements, for example on the contacts of a test object with several closing circuits, cumbersome, time-consuming and faulty, as the measuring mechanism is attached to the contacts must be applied or a galvanic connection is required to the contact resistances to eliminate the terminals. Measurements on test objects with several test objects are also difficult Changeover contacts, as a faultless one after testing the closed-circuit closing circuits Function has not yet been proven. Only when switching to the working position (apply the excitation voltage), which, however, requires the use of further aids, and subsequent measurement of the contact resistance of the closing circuits on the working side, results in the possible determination of the serviceability of the test object. This with Measurements to be carried out to determine the contact resistance take a long time on such test objects are due to the necessary leads in the measuring circuit as well as the measuring voltages and measuring currents that are often applied too high, finally also through the leads to the contact material in the test object itself, with not afflicted with insignificant errors. It is known that when using high measuring currents the exact determination of a transition resistance on the contact materials of a Test object is not possible at all. For smaller test objects, for example the test with the known measuring devices is only partially or only at large Expenditure of time and additional resources possible.

The present invention eliminates these mentioned shortcomings. Outgoing from a device for functional testing of relays with at least one working and / or a pair of normally closed switching contacts and at least one field winding or others controllable electromechanical switching devices containing a step switching means to switch the test processes, a signal lamp field to identify the respective Testing process and optical error display means, the invention is characterized by a programmer known per se for automatic detection devices, which, depending on the type of test item, determines the test sequence with the help of a first stepping mechanism determined and in addition with the help of another, synchronous with the first stepping mechanism operated stepping 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.

This program-controlled, automatically or manually operated test device (Fig. 1) with special circuit and device with receptacle 2 (Fig. 1) Almost all pluggable devices can be tested using adapters 23 (FIG. 2) Poled and unpolarized as well as non-pluggable relays, these at the time of manufacture a corresponding plug-in socket, with a subsequent measurement being static and dynamic contact resistance through direct display 9 (Fig. 1) or limit value reporting 10 (Fig. 1) with automatic interruption of the test sequence or when accelerating of the pulse generator 25-26 (Fig. 4) of the test device described later, a record possible via a recorder on any contacts of a test object is. The measurement results determined by the recording can be compared and recorded and can thus be better evaluated. The automatic test facility also has a directly working contact number display 8 (Fig. 1) by each flashing Digits, according to the contact number arrangement of the test object, a starter devicel2 (Fig. 4) for automatic measurement, a pulse device 14 and 25 (Fig. 1 and 4) with forward switching, whereby the following test sequence is operated manually can and, in addition, measurements within the Test sequence can be bypassed, a stop device 13 (F i g. 1 and 4), by the last resistance measurement performed with an automatic measurement sequence and Contact number display remains, as well as a switchover control 27 (Fig. 4), through which any desired excitation voltage according to the test object through the Push button switch 11 (Figs. 1 and 3) set manually or by programming in program plug 5 (FIG. 1) in the automatic measuring sequence within a test sequence can be created. The excitation voltage can also be between the individual coarse levels can be controlled with a current display, whereby it can be seen, for example, at what minimum current the relay armature of a test object picks up (static response and waste values).

The test device according to the invention also has a reset device 15 (Figs. 1 and 4) and a repeater 14 and 25 (F i g. 1 and 4), through which the test sequence is initially brought into the starting position and can be repeated. The present invention has the great advantage that both static and dynamic contact resistances can be measured. In the exemplary embodiment, the dynamic operation of the test facility is initiated manually, and it is via a controller 16-17 (Figs. 1 and 4), in connection with a 3-stage, astable multivibrator (Fig. 6), which produces an exact square-wave voltage supplies the DC excitation voltage to a square wave voltage with continuously adjustable frequency converted. With this facility, the flawless Function of a relay armature can be checked. Beyond that, however, there is the great one Advantage that with the mentioned recording via a known multiple writer Have all relay switching times that are important in practice determined.

The entire test facility with mounting device 2 (Figs. 1 and 2) and adapter 23 (FIG. 2) will now be described in detail in a program sequence described with reference to the drawings of an exemplary embodiment. It puts FIG. 1 shows an overall view of the test device, FIG. 2 a recording device with adapter and zero point standard or test item, F i g. 3 the power supply of the Test facility, F i g. 4 a start-stop device, pulse generator, device for static or dynamic operation, switching control for introducing the excitation voltage, Reset device (manual or automatic), execution of the excitation circuit for static and dynamic operation, F i g. 5 two synchronously operating step switching means with their locking circuits as well as a signal lamp field with connection to the program socket, F i g. 6 the circuit of the astable, transistorized multivibrator for introduction of dynamic operation, F i g. 7 program plug connections with four changeover contacts, Fig. 8 is a representation of an oscillographic recording of the exciter and Contact circle in dynamic operation, Fig. 9 is a schematic representation of a Extended test facility using a primary-side, continuous control of the excitation voltage with current and voltage display of a electronic limit value reporting as well as a known punch card or punched tape scanner for the program sequence, F i g. 10 a test object with four changeover contacts according to the embodiment.

The entire test facility is located in a desk housing, to enable a good observation of the measuring process. The respective Program plug 5 (Fig. 1), which has 60 contacts in the exemplary embodiment, plugged on. The arrangement of the receiving device 2 (Fig. 1), the measuring mechanism 9 (Fig. 1), the Contact number display 8 (Fig. 1) etc. can be found in FIG. 1.

Considering Fig. 3, the entire power supply should first the test facility are briefly explained. Via the primary side 28 of a transformer with mains control lamp 20, the secondary side 29 supplies via the rectifier 30, via the calibration regulator 18, via the resistor 31 and the measuring plant 9 the measuring voltage 32-33 for determining the contact resistance on a test object 24. The secondary winding34 supplies the operating voltage 41-42 for the function of the via the rectifier 35 Test facility. The secondary winding 36 supplies low values via the rectifier 37 Voltages (1 to 20 V), via the rectifier 38 higher voltages (40 to 80 V) as well as the excitation voltage 39-40 for the object under test; furthermore about the rectifier 43 the operating voltage 44-45 for the 3-stage multivibrator (Fig. 6). The excitation voltage 39-40 through the rectifier 37 or 38 is through a corresponding connection in the program plug 5 within a logical measurement sequence created. In the present exemplary embodiment, the desired excitation voltage is 39-40 for the coil design of the test object 24 by the corresponding pushbutton of the 10-flat pushbutton switch 11 set before the start of the measuring sequence. By a known changeover circuit is only one voltage switchable to a secondary side Avoid short-circuiting the transformer. By mutual ball locking The 10-fold pushbutton switch provides additional security for this. These manually introduced excitation voltage 39-40 passes over with its negative potential 39 the receiving device 2, the adapter 23 on one side to the excitation coil of the test object. The positive potential 40 is supplied to the device 16 and 17 via a break contact a normally open contact of the switching control 27 and causes the same after excitation by the program sequence of the step switch 47 and its closing circuits 48-57, which will be described later, the excitation of the test object 24. By arranging a two-pole toggle switch or a relay with two changeover contacts, which can also be operated by the program control, a change can be made make the polarity for the excitation of the test object, so that polarized relay can be checked. With the test device according to the embodiment you can test objects up to a maximum of eight changeover switches are tested. An extension would be possible, but not necessary in practice, since contact spring sets are generally used with more than 8 X U and 24 contact numbers do not occur.

In the exemplary embodiment, a relay with four changeover contacts should now be used are checked, whereby the following contacts are checked with corresponding numbers should. Toggle switches 72, 75, 78 and 81, rest side 71, 74, 77 and 80, working side 73, 76, 79 and 82. The rest side to be checked would therefore be 71-72, 74-75, 77-78 and 80-81, the working side 72-73, 75-76, 78-79 and 81-82.

The test object 24 is first placed on the corresponding receptacle 188 of an adapter 23 is inserted. This socket 188 has a galvanic silver wire Connection to adapter base 60.

Adapter 23 with test object 24 is then on the receiving device 2 attached to the test device. Should other test objects come to the test, so on the receiving device 2 of the test device as well as on this itself nothing changed, which is another great advantage in terms of the present Invention is. Only adapters and program plugs are exchanged. By the program plug can be a programmer controlled by punch cards or tape 5 are not applicable.

The usual shortcomings in the measurement of micro-resistances, as already mentioned excludes the present invention.

The measuring voltage 32-33 is parallel to the measuring mechanism 9. Also parallel for this purpose there is a constant resistance 31 of approximately 0.1 ohm. The special measuring mechanism 9 shows full deflection when the calibration controller 18 is operated. The measuring voltage 32-33 is 1 to 5 mV at the open terminals. This circuit arrangement is a Destruction of the measuring mechanism as good as impossible, which is an advantage of the present Invention is. The condition for measuring contact resistance when in use The smallest measurement currents and voltages are thus largely met. The measurement (Direct display in ohms on the scale of the measuring mechanism) of the contact resistance of the Contacts of a test object are connected in series via the measuring contact of the test object and a respective one resulting from the program Contact of the magnetic step switch 46 and its closing circuits 61-69 parallel to 32-33, which causes a voltage drop and therefore for display comes. The twin contacts of the magnetic step switch 46, its function is assumed to be known, are made of special contact material and possess an optimal, equal transition resistance value.

To determine the zero point of the Ohmeichung on the directly calibrated Scale of the measuring mechanism 9, which is due to the contact resistance of the step switch 46, the supply lines within the testing device and the adapter 23 are about a tenth the length of the scale lies before the electrical zero point, it is initially a zero ohm standard 24, the contact materials of which are galvanically connected, in connection with the adapter 23 attached to the receiving device 2 of the testing device. By plugging it in corresponding resistance standards on the test socket of the adapter can be the further The ohmic calibration of the scale can be set from 0.005 to 1 ohm. This results in, that when measuring a test object only the actual contact resistance to be displayed on the contact materials. In the example mentioned, the one to be tested Objects with four changeover contacts are connected in the adapter by silver wires from the test socket to the base of the adapter. The numbers of the changeover contacts 72, 75, 78 and 81 of the socket for holding the test object are in the adapter base 60 connected and have after plugging the adapter onto the receiving device 2 over 70 a connection after 33 of the measuring voltage. The numbers of the idle page71, 74, 77 and 80 have corresponding connections to the adapter base 60. After plugging in the following connections arise from the contact rest sides of the test object: 71 after 61, 74 after 62, 77 after 63 and 80 after 64. The numbers of the working page of the test sockets also have corresponding connections to the adapter socket, and there are after Plug in the adapter, as already described, from: 73 after 66, 76 after 67, 79 after 68 and 82 after 69. There is also a connection in the base of the adapter from 83 to 84 (Fig. 4), the one after removing the adapter 23 from the recording device 2, by interrupting the negative circuit 41 of the Operating voltage for the Test device, the automatic one described later or manual measurement sequence stops. Before describing the entire test and measurement process however, according to the embodiment of the invention and the object to be tested (four toggle switches) the necessary connections in the program plug 5, the side is plugged onto the program socket 4 of the test device, are explained.

For directly working contact number display 8 are in the present Test facility 24 built-in contact numbers, with each contact number assignment corresponding connections of the test object are made in the program plug, which are identified by flashing digits in the automatic or manual measuring sequence will.

For the test object named in the example, the program plug 5, which is later plugged into the program socket 4 of the test device, the Connections 98-101-104-107-130 made. The ends of the contact number lamps the changeover switches 72, 75, 78 and 81, corresponding to the test object, are therefore at the point 130 of the program plug. This in turn has over the receiving device 2 and the adapter socket 60 has a connection 83-84 (FIG. 4) according to point 132 of the program socket 4. The establishment of a connection in program plug 5 from 132 to 131 (F i g. 7) introduces the negative potential of the operating voltage 41 for the test device.

Removing the program connector 5 also interrupts the Adapter 23 the automatic or manual measuring sequence, with a re-plugging displays the last measurement made.

Other connections in the program plug: 48-53-85-86-87, accordingly contact numbers 71-72-73; 49-54-88-89-90, corresponding to contact numbers 74-75-76; 50-55-91-92-93, corresponding to contact numbers 77-78-79; 51-56-94-95-96, accordingly the contact numbers 80-81-82. Connections from 97-100-103-106 to 125 are respectively Established via a diode to avoid current branching according to 125 (contact number rest side 71-72, 74-75, 77-78 and 80-81) and from 99-102-105-108 also via a diode to 126 (contact number working page 72-73, 75-76, 78-79 and 81-82). Another Connection from 52 to 127 and a final connection from 57 to 128 is below described in the entire function of the automatic test device.

After connecting the automatic test device to the AC voltage network and after switching on by means of rotary switch 21, the control lamp above 20 lights up, the arrangement is ready for use after a few minutes. The power supply has already been described on page 6. However, the automatic measuring sequence can only are initiated when adapter 23 with test item 24 and program plug 5 are attached are, initially via a break contact of the switchover control 27, the control lamp "Rest" 6 lights up, indicating that the test object 24 is not excited. The for the test object 24 specified excitation voltage must also in the present embodiment can be set by pressing the corresponding pushbutton. By pressing the "Start" button 12 with normally open contact is initially the relay 133 via the normally closed contact 158 of the relay 148 is energized, which then holds itself via its own contact 135. At the same time, the Normally open contact 134 of the pulse generator 25 and 26, whose pulse frequency is continuously controlled by the potentiometer 167 can be changed, put into operation, whereby the entire automatic measuring sequence is initiated. The two working contacts 136 and 139 are used to control: via 136 the 10-pole step switch 46 and via 139 the 10-pole step switch 47. Be via the closing circuits 48-57 of the magnetic step switch 46 the contact number display 8, the switchover control 27 is actuated and via the relay 146, 147 and 148 initiated the reset described later and thus the automatic measuring sequence ended.

Pulse one closes the circuit of 32 of the via contact 168 Measurement voltage according to 61 of the recording device, via the intermediate adapter and via the first break contact of the test specimen 71 and 72 back via the adapter via 70 after 33 of the measuring voltage. At the same time, pulse one closes through contact 178 Circuit from the positive pole of the operating voltage source 42 via 178, the connections in the program plug 48-85-86 and via the two control lamps 71 and 72, whereby the Control lamp 71 over point 97 of the diode in the program plug to 125 and over the Normally closed contact of 143 receives the negative potential of the operating voltage 41, while the Control lamp 72 between 86 and 98 its negative potential through the connection in the program plug 98 after 130 received. The pulse sequence one to four shows the respective rest transition resistances 71-72, 74-75, 77-78 and 80-81, with the associated contact numbers at the same time light up. Pulse five energizes through contact 182 and through the link in the program plug 52 to 127 the relay held by the normally closed contact 157 27, which then remains excited via a normally open contact 144. Since the test item 24 is already on the minus side of the excitation voltage for more than 39 (FIG. 4), now by the working position of the relay 27 via the normally closed contact 161 and the normally open contact 142 placed the test object on the positive pole 40 and excited. At the same time is through the lighting up control lamp "work" 7, via the work contact 145 the work position of the test item is displayed. Another working contact 143 of the relay 27 sets the Negative potential of the operating voltage in the program plug from 125 to 126, whereby, as already described and easily recognizable, six in the further pulse train up to nine the control lamps corresponding to the normally open contacts of the test object 72-73, 75-76, 78-79 and 81-82 light up and at the same time the respective transition resistances come to the display.

The impulse ten finally ends via 187 the connection in the program plug 57-128, which energizes relay 148 and releases it with a delay, the automatic Measurement sequence. At the same time, the two magnetic contacts are made via the working contacts 157 and 159 Step switches 46 and 47 brought into their starting position by their shedding winding, and the normally closed contacts of 158, 156 and 157 open by their working position Circuit of the relay 133, which was initially held via 135, which is now goes to rest position. The rest position of the relay 133 also opens the circuit of the pulse generator 25-26 interrupted by opening the contact 134, whereby the entire, automatic measuring sequence is ended. Finally, the working position of Relay 148 the opening of the contact 157 and thus brings this over in the program sequence 127 energized and over 144 relays 27 held to waste. This will increase the excitation voltage switched off, and the control lamp shows the changeover contact 145 again Rest position of the test object. A desired one takes place in the same way Reset by pressing the »Reset« key 15. The automatic test sequence can be stopped at any time by manually operating the »Stop« button 13 (Fig. 1 and 4) with its normally closed contact, whereby the relay 133, which is held via 135, is de-energized and the circuit of the pulse generator 25-26 is interrupted, stopped, where the last resistance measurement and contact number display remains.

If there is a contact fault on a test object, then the stop button 13 is pressed. The test object can then be removed from the adapter 23 and after eliminating the contact error known from the contact number display 8 is to be reattached. The result of the error elimination then comes immediately see full ad. The test sequence is then continued manually Operation of the »Start« button 12. The entire test sequence can also be operated manually by briefly pressing the »Impulse« button 14 one or more times, which is marked with their normally open contact, the relay 25 of the pulse generator energized and the two step switches 46 and 47 can each move forward by one position. This arrangement brings the Advantage that unwanted measurements can be ignored.

Another great advantage is that an arrangement which can be expanded, in the exemplary embodiment by relays 146 and 147, the previously described resetting of the magnetic step switches 46 and 47 in their starting position without interruption of the measuring and test sequence by the Pulse generator 25 is possible. This allows test objects with more than ten closing circuits, as it only has the magnetic step switch can be tested, and it can thereby the end of the automatic measuring sequence with the first run of the magnetic Step switch 47 pre-stored and in the second pass at any Position of 47 to be initiated. Let me give you an example again for a better understanding listed, but only the connections in the adapter 23 and program plug 5, which are important for this function.

There should be the contact resistances at the closing circuits of a Test object 2 X changeover switch + oXrest can be determined. The changeover switches of the six normally closed contacts and normally open and normally open contact changeover switches of the two changeover contacts are in the Test socket connected and placed at 70. Rest and working side of the two changeover contacts are also connected, with contact one, idle and work side, at 61 and Contact two, rest and work side, lie at 62. Then the quiet sides of the follow six normally closed contacts from 1 to 6, each connected to 63 to 68. It accordingly, in the case of an automatic measurement sequence, the contact resistances come with impulses one to two of the first two changeover contacts on the rest side, with an impulse three to eight the Contact resistance of the six normally closed contacts on the rest side for display. In the program sequence of the step switch 47 this would mean that via 48 to 55 the respective Contact numbers are displayed. For the outstanding contact checks of the two switching contacts on the working side is in the manner already described and in the present case at pulse nine via 56 to 127 and the relay 27 the test object excited. At the same time, the connection from 56 to 58 in the program plug the relay 146 is energized via the normally closed contact 154, which then drops out with a delay and through the working contacts 149 and 152, the two step switches in their starting position set back. At the same time the relay is activated via the normally open contact of 151 147 excited via the normally closed contact 159, which is then excited via the contact 155 State remains. By the working position of the relay 147 and its working contact 153 creates a connection from 128 to 59. Since the two step switches in their The initial position has been reset and the automatic measuring sequence has not been completed, accordingly, the two working-side contact resistances come at impulse ten and eleven as a result of the excitation of the test object through 168, 169, 61 and 62 for display, where also in turn the corresponding contact numbers via 48, 49 and via the working contact 143 of relay 27 and the connections in the program plug light up. Through the Connections from 50 to 59 in the program plug, the measuring sequence is now with the third Second cycle pulse ended. This circuit arrangement results the fact that the first time the step switch is passed, the Reset is triggered, but on the second pass through that in the first pass Relay 147 put in readiness, the automatic measuring sequence is ended. Of the Changeover contact 159 in the circuit of relay 147 caused by the working position also the resetting of the circuit arrangement just described.

Furthermore, the already mentioned expansion of this arrangement is no longer necessary possible that by the pulse train of the encoder 25-26, which in the embodiment controls the two step switches 46 and 47 synchronously from 1 to 10, the advancement of the measuring step switch 168 by the program step switch 47 one or more Times can be exposed. This is done by the fact that another relay, which can be controlled via 48 to 57, with a break contact in the circuit of the Tightening winding of 46 and its own working contact through which the excitement received remains, the incoming direct current pulses from the encoder via 136 to the pull-in winding interrupts. The activation of another relay with a normally closed contact in the circuit the excitement 48-57 cancels this state again.

This makes it possible to use all types of contact spring sets, such as follow-up, rest, work contacts, etc. to be checked.

Another great advantage of the testing device is that the direct display of the respective contact resistances of a test object, which in present embodiment takes place via a special moving coil measuring mechanism, by the installation of a limit indicator 10 (FIG. 1) can be conveyed. The connection can also take place in connection with the direct display. A normally closed contact of the by the switching transistor of the limit monitor controlled relay is in the circuit of relay 133 and causes when a set limit value is exceeded the interruption of the measuring process, as described under the »Stop« function.

In the same way, an optical or acoustic signal can be given will. The contact number display remains due to the interruption of the measuring process and the contact error can be recognized immediately. A human failure the test person can also be excluded by this arrangement of the limit value reporting.

The test time for a test object can be determined by the already described Acceleration of the pulse generator shortened by setting the voltage divider 167 will; In the present exemplary embodiment, however, this is due to the inertia the display measuring mechanism and the great damping limited. The time from test pulse to Test pulse is about 3 seconds; thus the test time for a test object is with four switches about 30 seconds.

If series are to be tested, it is advisable to connect one Writer to terminals 1 (Fig. 1), the pulse generator accordingly in a known Way is accelerated. These measurement results determined in this way can be better evaluated and can also be compared and registered.

It has already been indicated that with the present invention several Tests on any arranged closing and opening circuits of a relay can be carried out. With the already mentioned control button 7 in Connection with the 3-stage multivibrator (Fig. 6), which produces an exact square-wave voltage supplies and a continuously adjustable frequency from 1 to 100 dz by means of a potentiometer 19, the correct function of the relay armature must first be ascertained. The test can be carried out on the rest-side or work-side closing circuits of a Test object take place, the relay 160 is energized by pressing the button 17 and then holds on to his own contact 162. The working position of 160 sets the multivibrator (Fig. 6) into operation via 163, its last transistor stage a special relay 164 operates, whose contacts 165 and 166 the positive potential 40 of the excitation voltage is applied to the test object and interrupted again. Through the Regulator 19 (F i g. 1 and 6) with calibration scale of the multivibrator can be any desired Set the excitation frequency so that the switching frequency of a relay can be determined can. It is known that when a test object is excited with a rectangular Voltage, as in the present exemplary embodiment, over the entire measuring process the normally closed and normally open contacts of a relay can happen, certain values for the Response, waste and turnaround times must be adhered to. Used for this in practice an excitation frequency of normally 25 Hz, which is also with the present Test device can be set. Testing a relay in the dynamic Operation is again with the already known example with four changeover switches explained.

With the direct display of the contact resistances comes due to the inertia of the measuring mechanism at the four normally closed contacts as well as the four normally open contacts a certain Average resistance value for display.

If these mean values deviate within the rest-side or work-side Examine each other so is the adjustment of the spring set is essential disturbed; provided that there are no major undesirable effects in the static test Contact resistances were shown. Switching the dynamic Operation to static operation is carried out by pressing key 16, whereby the via the normally closed contact of the button and 162 holding relay 160 is de-energized. A The dynamic operation initiated in the test sequence is also used via the known Resetting and termination of the automatic measuring sequence or during activation of 148 in the automatic measuring sequence by opening contact 158, as already described, completed. One located in the supply circuit for the excitation voltage 40 of the test object Normally closed contact 161 goes into the working position during dynamic operation, which means that now the closing and opening circuits of contacts 165-166 the feeding of the symmetrical, cause rectangular excitation voltage.

Probably the greatest advantage of the present invention is that that in addition to the test by direct display or recording via a recorder of static transition resistances at any arranged contacts of a test object, so the secondary closing circuits, at the same time a test of the primary excitation circuit and the functions resulting from the excitation can take place. Under use an oscilloscope or a recorder, the secondary operations of a Test object can be observed or recorded. Using a known Two-beam oscillographs or a multiple recorder, which are sent to the test facility can be connected to 3 for the X direction and 1 for the Y direction, the start-up, response, stroke, bounce and turnaround times can be determined by observation or determine the recording.

Claims (14)

Claims: 1. Device for functional testing of relays with at least one make and / or break 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 to identify the respective test process as well as optical error display means, g e k e n n n z e i c h -n e t d u r c h one per se for automatic test equipment known programmer (25-26), depending on the type of test item (24) with the help of a first stepping mechanism (46) determines the test sequence and beyond with the aid of another operated synchronously with the first stepping mechanism (46) Stepping mechanism (47) the test positions according to a predetermined pole designation of the test item (24) to the one with the same pole designation during the test sequence provided signal lamp field (8) transmits. 2. Device according to claim 1, characterized in that the contact transition resistance standing test as an optical display means one provided with an adjustable limit value contact (10) Moving coil measuring mechanism (9) is used to be as sensitive as possible. 3. Apparatus according to claim 1 or 2, characterized in that to switch the two stepping mechanisms (46, 47) one optionally also manually actuatable pulse generator (25, 26) is used. 4. Device according to claim 2 and 3 with a relay for automatic Interruption of the test in the event of an error, characterized in that the relay (133) de-energized by means of the limit value contact (10) and thereby the circuit the pulse generator (25, 26) is interrupted. 5. Device according to one of claims 1 to 4, characterized in that that the second stepping mechanism (47) via the programmer (4, 5) the termination the programmed measuring sequence and the resetting of the two stepping mechanisms (46, 47) triggers. 6. Device according to one of claims 1 to 5, characterized in that that for dynamic testing the test object excitation windings with square-wave voltage pulses a pulse generator (190) are applied. 7. Device according to one of claims 1 to 6, characterized by a circuit arrangement (13, 133) for arbitrarily switching off the pulse generator current. 8. Device according to claim 6, characterized in that the pulse generator (190) is continuously adjustable with respect to the pulse frequency. 9. Device according to one of claims 6 to 8, characterized by the excitation winding connections to special, externally accessible sockets (1) for Connection of evaluation devices. 10. Device according to one of claims 1 to 9, characterized by means (19) for setting the pulse frequency of the pulse generator (190). 11. Device according to one of claims 1 to 10, characterized by a punched card or strip-controlled programmer (191, 192). 12. Device according to one of claims 1 to 11 for test items with Changeover contacts, characterized in that the for the normally open and normally closed contacts a changeover contact provided connections in the adapter (23) with each other are connected. 13. Device according to one of claims 1 to 12, characterized by a reset switch (15) to terminate the automatic test sequence resetting the stepping mechanisms (46, 47). 14. Device according to one of claims 1 to 13, characterized by a switching unit (11) for the optional setting of the operating voltage of the Test object excitation windings.