DE1029924B - Electrical testing device for determining line breaks and insulation defects in the wiring of electrical calculating and accounting machines - Google Patents

Description

Electrical test device for determining line interruptions and insulation faults in the wiring of electrical calculating and accounting machines For the electrical testing of cables it is known with the help of an automatic Test device every single wire for current continuity, the insulation of the wires against each other and to test against earth. If an error is found, the test procedure interrupted and the error is indicated by a signal. Checked this way Cables or harnesses are used to connect to the chassis of electrical apparatus of the individual components, such as electron tubes, resistors, capacitors, etc., built-in.

The electrical calculating and accounting machines generally exist from a larger number of individual chassis units, and it is therefore advisable to to carry out a test of these chassis units before they are installed in the machines to be built in. With the known test device, however, a test is such Chassis units not or only with great difficulty, modifications and expenses possible and associated with considerable loss of time, especially if a larger number of identical units is to be tested.

The present invention avoids these deficiencies in an electrical one automatic test device for the determination of interruptions and isolation errors the wiring of apparatus parts of electrical calculating and accounting machines by according to the invention after inserting the apparatus part to be tested in a corresponding adapted mounting frame of the test device the individual lines of the test object in a known manner with the help of an exchangeable circuit board for certain test programs are placed in electrical circuits, via which electromagnetic control is known Step switch successively test pulses are passed, under their control both a short circuit between adjacent lines or between one line and the chassis frame of the device under test as well as a line break and the type and location of the error with the help of the respective position of the selector switch is displayed and further testing is interrupted.

The switching of the electromagnetically controlled step switch takes place under the control of a timer with a frequency of four switching steps per second in that the advancement of the contact arms of a step switch only begins after the contact arms of the previously effective step switch after their full circulation have returned to the basic position, at what point in time the pulse circuit is interrupted by the solenoid controlling this step switch and is closed via the solenoid of the following step switch.

If no line interruptions or insulation faults are found, then the automatic test cycle is ended in less than 1 minute and the supply indicated by a special signal lamp. Upon finding an error during the test is interrupted and a buzzer sounds, and the type and the The location of the error is indicated by a combination of dials and illuminated ones Lamps displayed.

After the repair or the written note of the fault can the test can be continued by operating a hand switch.

The test device according to the invention has the great advantage that in checking the wiring for line breaks, line contact and Insulation faults also affect the components mounted on the chassis units, such as B. plugs, soldering strips, tube sockets, resistors, coils, etc., with their Solderings are included.

Further details of the invention emerge from the exemplary embodiment of the testing device, which is described in the margin of the drawings. 1 shows a perspective view of an embodiment of the invention, FIG. 2 shows a form of a Chassis frame and their wiring combination, 3 shows a vertical Section through the chassis to be tested, which is in the intended mounting frame is inserted, Fig. 4 is a left side view of the device with the side plate removed, 5 shows a section through the circuit board with the connecting contacts and circuit connections, 6 shows a part of the circuit board for grounding unused electrodes of the chassis receptacle, 7 shows a schematic representation of one of the rotary step switches used, 8 shows a view of the switchboard with the associated elements, FIG. 9 shows an electrical one Diagram to explain the basic theory of the invention, Fig. 10 a simplified Partial circuit diagram of the actual test circuits, FIG. 11 a similar diagram of the automatic controls of the device, Figures 12A, 12B and 12C the complete Circuit diagram of the device.

The best way to ensure that the test facility or device works To explain, a typical network arrangement supported by a chassis 100 should first be explained to which the test method can be applied. The chassis (Fig. 2, 3) comprises a frame 101 in which transverse insulation strips 102, 103, 104 and 105 are arranged and the top with a number of tube sockets 106 and is provided with sockets 107 at the bottom. There are several in each insulation strip angled terminals 108 each with a vertical pin 109 and a self outwardly extending horizontal pegs 110 (Fig. 2) embedded. This chassis forms the basis of a pluggable unit, which after completion is a Contains a variety of different tubes, resistors, capacitors, etc.

Such units that come in several standard widths and component combinations are produced in different numbers and in different arrangements in certain types of - electrical, electronic, calculating, office machines od. Like. Used.

The electrical combination is in each pluggable unit in two Working aisles. In the first step, predetermined tenons 109, Tube base terminals 111 and / or lower base terminals 112 by jumper wires, such as z. 113, connected to form nodes, i.e. H. Electric sub-combinations connected terminals to which the corresponding components are to be connected. In the second step, the components are then between the corresponding nodes are used.

Many such units are very complicated, and one such unit includes, for example, 13 vacuum tubes and 108 diodes, and 630 connecting pins or Connector terminals are arranged in 150 nodes. If only now an exam would be done after complete assembly would be noted and a long one to find every fault in the complicated jumper wire network and extremely difficult operation required. It is therefore very beneficial that the basic wiring network already before the installation of the electrical components to consider. Also in this case, and especially when several double units are to be established, would be the testing of all node connections according to the usual Methods a lengthy and arduous work, in which, moreover, human Failure would be possible. Such a unit in about 4 minutes including the time required to start the testing machine be checked, and at the same time becomes the factor due to the automatic mode of operation of human error eliminated.

As already mentioned and shown in FIG. 3, node connections Tubular base clamps 111 and / or lower base clamps 112 as well as the pegs 109 include. Since all of these connecting devices take the exam in the same way, may hereinafter be referred to as connection electrodes for the sake of brevity and simplicity are designated.

Basically, the device works using it certain electrical relationships, which are determined by the simplified circuit diagram according to 9 are shown. Fig. 9 shows three groups X, Y and Z of five each Connection pin 109, which corresponds to the groups with X1 to X5, Y1 to Y5 and Z1 to Zs are designated. The tenons of each group are interconnected by jumper wires 113 connected and via the same resistors Rzs RV and Rz to the distribution point G connected. The distribution point G is connected to a direct current source via a resistor Rç 114, the other side of which is on the earth 115.

A test procedure is carried out with this connection arrangement, which, when a ground line 116 is applied to point X1, also increases the resistance of points X2, X3, X4 and X5 against earth. A faulty open circuit or a line break between point X1 and one of points X2 bis X5 is thereby established. When point X1 is grounded, current flows through the in series lying resistors Rz and Rg, and assuming that the current source 114 is a Provides voltage of 330 volts and that none of the points Y1 and Z1 is grounded, flows a current 1 of the strength I = (1) and the voltage drop across the resistor Rg Vg = R, (330) Rz + R9 (2) However, if a short circuit between the point X1 and a point of one of the other two groups, e.g. B. the point Y1, there is, flows the test current through the parallel connected resistors Rx and R ", and the resulting voltage drop across the resistor Rg is greater than before, namely Rg (330) - Rg + (0.5) Rx (3) So if the voltage drop V0 is measured, the higher value of equation (3) indicates a short circuit between point X 1 and one of the points of the Y or Z group, while the smaller voltage drop Vg of the equation (2) indicates that there is no such short circuit. To this Way can either be an open circuit between the points of group X or a short circuit between any point of group X and points Y1 and Z1 to be established.

To apply this fundamental consideration, the present Invention the device described below for automatic testing of all connections of each group or each node point both for faulty open circuits as well as short circuits and to indicate the type and location such mistake before.

The cabinet 117 (Fig. 1) supports a forward sloping upper control panel 118 and a receptacle 1161 which holds the pluggable unit frame 101 and the necessary electrical test connections to the network of the unit manufactures. The recording container 119 (Fig. 3) includes insulating side panels 120 and an insulating base plate 121, by means of which it can be placed on top of the cabinet 117 is attached. In the front part of the cabinet are an upper and a lower transverse plate 122 and 123 of insulating material fixed between the side panels 120 and in similarly two insulating panels 124 and 125 in the rear of the cabinet like this arranged that the frame 101 is inserted between the rear and front panels can be. Narrow insulating rails 126 are provided on the side plates 120, to guide the frame into a central position when it is inserted. Upon reaching The multi-pin plugs 127 fastened to the base plate 121 act in this position with the lower sockets 107 of the plug-in unit. Great on the front and rear plates 123 and 125 inwardly and outwardly slidably attached Multiple plugs 128 and 129 each have four rows of elastic contact springs 130 provided, which individually the various horizontal pins 110 of the pluggable Ability to grasp unity. As FIG. 3 shows, are in the operative position the plug, the pin 110 between the contact springs 130 and the rigid insulating bars 131; which ensures good electrical contact. The ones on the contact springs 130 connected insulated wires 132 are combined into flexible cables 133, which are guided through the base plate 121 into the interior of the cabinet. As a result the multiple plugs 128 and 129 can easily follow the elasticity of the cables 133 moved inside and withdrawn by handles 134. Although the plugs 128 and 129 of course each can be designed as a single unit that extends over extends the entire width of the container frame, they are preferably in several Units, e.g. B. 128a, 128b and 128c (Fig. T), divided for handling and to facilitate adaptation to test chassis networks of different widths. The plugs 128 and 129 thus represent individual connections of all pins 110 of the Unit chassis 100 via cables 133 to the corresponding elements of the following described test device. Similar individual connections run from the upper ones Tubular sock clamps 111 over the multiple plugs 135 and the cables attached to them 136. A contact spring 137 connected to a lead wire 138 rests on the metal frame 101 of the pluggable unit chassis 100 to check for short circuits between one of the network elements and the frame as well as short circuits between the network nodes to enable yourself.

The terminals 139 of the lower connector 127 are connected to wires 140, which run down inside the cabinet 117 and complete the combination, Via which the receiving frame 119 test connections to all connecting terminals of the Chassis 100 and the frame 101 forms. All lines originating from frame 119 are led to the stationary contact plate 141 (FIG. 4) of a switch box 142.

From the fixed contact plate 141, those combined in the cable 143 lead Wires to various relays housed in box 144 and below in connection with the circuit diagram (Fig. 10, 11, 12). Another one Cable 145 forms permanent connections from the fixed contact plate 141, which also will be described later.

The control box 142 also includes a detachable control panel 146, which in a known manner by a pivotable frame 147 in the cooperation is held with the fixed contact plate 141. The electrical connection between the fixed contact plate 141 and the switchboard 146 is in the Fig. 5 shown. The fixed contact plate 141 consists of an insulating plate 148, in which a plurality of spring contact fingers 149 is inserted, their number is sufficient for individual connections to all of the lines emanating from the container 119 and with all the wires of the cables 143 and 145. The removable control panel 146 consists of an insulating plate 150 in which a plurality of pin sockets 151 is used, the tapered extensions 152 for the production of individual electrical contacts with the spring fingers 149 are used. The sockets 151 are multiple sockets, so that multiple connections can be made to them. Flexible switch cords 153 are provided with end pins 154 which are inserted into the sockets 151 can to make optional connections between the tank wiring and the corresponding internal wiring of the test device to establish it via the spring fingers 149.

If a number of the same networks are to be checked, then in practice a switchboard 146 is made with the appropriate connections. Similarly, if other types of networks are to be tested, a switchboard will be used 146 switched for each type. So if several of the same networks are to be tested, only the corresponding upstream control panel 146 needs to be used, to set the test device in the appropriate combination.

The control panel 118 (Fig. 8) has a near its leading edge elongated window under which four electromagnetically controlled step switches S1, 52, S3 and S4 are attached with five steps each. Because such switches in themselves are known, a detailed description can be dispensed with.

The ratchet wheel 155 (Fig. 7) the step switch is a spring operated one Pawl 156 associated with only one clockwise rotation of the ratchet wheel allowed.

A pivot arm 157 carries a drive pawl 158, which is also shown in the ratchet 155 engages. The swing arm connected to the core 161 of a solenoid 162 157 is normally held against a stop 160 by a spring 159, and with energization of the solenoid 162, the arm 157 becomes counterclockwise pivoted and the spring 159 is tensioned, so that when the solenoid is switched off the spring pulls the swivel arm back and, through the pawl 158, the ratchet wheel 155 rotated clockwise by one tooth. A contact arm attached to ratchet 155 163 comes into contact with the concentric contact points one after the other "1" "22v," 3 "etc., the number of which corresponds to the number of teeth on the ratchet wheel Successive excitation of the solenoid 162 loops the contact arm 163 all contact points of the switch one after the other and stops after a full turn of the ratchet again on contact point "1". To simplify the circuit diagram 10, 11 and 12C are the contact points of the various step switches shown arranged in semicircular or straight lines. Your activity takes place in each case only in the one direction shown in FIG. 7, so that the contact arms at the completion of one revolution from the last contact point get back to the first point.

The circuit combination of the invention is divided into two main parts, of which the first comprises the actual test circuits and the second the means, through which the successive test circuits in an automatic cycle to be erected. Although in FIGS. 12 A, 12 B and 12 C, the two switching sections are effectively linked, their explanation is best done separately below Consideration of the test and circulation functions according to FIGS. 10 and 11. In the Fig. 10 is the establishment of the test circuits under the steering the step switches 51 to 54 are shown. According to the embodiment of Invention, these switches each contain 52 contact points on levels L 1, L2, L3, L4 and L5, of which, however, since the functions of all points are the same, only the Contact points "1" to "4" and "52" are shown. There are also the first three step switches 51, 52 and 53 have the same test function, only this first switch 51 is shown.

The step switch S4 is shown, however, because it works with each of the other step switches 51 to 53 can cooperate to test network nodes with more than five steps or connecting electrodes as below is yet to be explained.

The contact arm 163 of the stage L 1 of the step switch 51 and the Corresponding L1 arms 164 of the step switch 54 are connected via a line 165 connected to earth 115, with which the points "1" of levels L2, L3, L4 and L5 of switch 51 are connected by lines 166, 167, 168 and 169. The L 2-contact arm 170 of switch 51 is at contact point "1" of the second stage L2 of the switch 54 connected, the contact arm 171 via a line 172 with connected to one end of the winding of a relay M2. The other end of the relay winding is connected to one side of a 6.3 volt transformer winding 173, whose other side is connected to earth 115.

Similarly, contact arms 174, 175 and 176 are the steps L3, L4 and L5 of the step switch 51 with the contact points "1" of the corresponding Stages of the switch 54 connected, the corresponding contact arms 177, 178 and 179 is connected to relays M3, M4 and M5 connected to transformer 173 are. As long as the contact arms of both stepping switches 51 and 54 are on their contact points "1" rest (Fig. 10), relays M2 to M4 are energized, which have two contacts each control, one of which, e.g. B. M2-1, normally open and the other, e.g. B, M2-2, is closed.

If the device is used to test the network of a unit 100 in the is set in the manner described, the contact points are "2" of the five levels of step switch 51 via control panel 142 and receptacle contacts connected to the network connection electrodes X 1, X2, X3, X4 and X5, which form the X group or a node according to FIG. 9. The contact points are similar "3" of the step switch 51 with the electrodes Y1, Y2, Y3, Y4 and Y5 of the Y group and the contact points "4" of the step switch 51 with the electrodes Z1, Z2, Z3, Z4 or Z5 of the Z node connected. In this case, however, the Z-node has thirteen connected connection electrodes, while the switch 51 has only five stages is. These additional connection points are checked using the step switch 54, whose contact points "2" and "3" of level L 1 for this purpose with the Z5 electrode connected by connecting cords 153. The points "2" and "3" of level L2 des Step switches 54 are connected to the connection electrodes Z6 and Z7, the L3 points »2« and »3« with electrodes Z8 and Z9, the L4 points »2« and »3« with the electrodes Z10 or

Z11 and the L5 points 22 "and" 3 "with the electrodes Z12 and Z13, respectively tied together. The contact points "4" of all stages of the step switch 54 are over the switchboard 142 is connected to the ground 115.

The Ll points "2", "3" and "4" of the step switch 51 are also via the same resistors R, RV and Rz through the common line 180 with the Resistor Rg connected to power source 114 and thence to ground 115 is connected, whereby the general short-circuit test arrangement according to the Fig. 9 is formed. The grid 181 is also attached to the common line 180 Ntakuumröhre 182 connected, in whose anode circuit a relay M1 is connected. The relay M1 controls two normally open contacts Ml-1 and M1-2, which together with the contacts of relays M2 to M4 for various signal and control operations are used, which are later used in connection with the circuit diagram according to FIGS. 12A to 12C.

At the beginning of an exam, the contact arms of all step switches are at rest at their contact points "1" so that when the working current is applied to the System address relays M2 to M5. The step switch is activated during the first test 51 moved one step further, so that his contact types score with the KontaM "2" come into contact. This will bring the network connection electrode X1 over the EontakE arm 163 connected to earth 115 and a circuit across the resistors Rz and R2 (Fig. 9) closed.

If there is no short circuit between electrode X1 and one of the Y or Z groups, the voltage drop V, across the resistor Ru, takes the value of equation (2), and the grid of tube 182 is given by the potential of common line 180 influenced accordingly. The tube 182 <Fig. 12A) is biased so that it does not conduct when the voltage drop Vg equals the value of the equation (2), but becomes conductive when the voltage drop equals the value of equation (3) accepts. Therefore, if a short circuit between electrode X 1 and either the Y- or the Z-node, the tube 182 becomes conductive and that in the anode circuit lying relay M1 energized, soft now the contacts Ml-l and M1-2 closes to night to trigger the signals and controls described above.

When the contact arms 170, 174, 175 and 176 of the second to fifth Steps L2 to L5 of the step switch 51 are resting on the contact points "2" they are no longer directly connected to earth 115, as is the case when touching the contact points S. " the case is. With the proviso that between the electrode X1 and the Electrodes of the remaining nodes of this group no line interruption is present, the contact arms 170, 174, 175 and 176 are therefore interconnected and connected to ground 115 via contact arm 163 of stage L 1, so that the relays M2 to M5 remain energized. However, it is a line interruption or a »Open circuit state ¢, e.g. B. between electrodes X1 and X2, then disconnects contact arms 170 and 174 to 176 from earth g &, and relays M2 to M5 drop. If there is an interruption between electrodes X3 and X4, then the relays M2 and M3 remain energized, and the relays M4 and M5 are de-energized while if an error occurs between points X4 and X5, only relay M5 drops out. It follows that from dropping one or more relays M2 to M5 both indicates the presence as well as the location of the fault in the checked node state.

If the first or X-node has short circuits and open circuits is checked, the step switch 51 is switched to the contact point "3" and causes the Y-node to be checked in the same way. The contact poor of the step switch are, as shown in FIG. 7, designed so that they are advancing from one contact point to the next, already in contact with the latter contact point before they leave the former contact point. This prevents the relays M2 to M5 drop out and thus false displays of open circuits give poor contacts while forwarding. The contact arms associate however, both contact points with each other for a moment while it is being forwarded, and to prevent the incorrect display of a short circuit by relay M1, a contact T 1 located in the excitation circuit of the relay M1 is opened and the relay M1 is switched off while the switch is switched on.

In continuation of the test process, the contact arms of the step switch 51 advanced gradually and connected to the successive contact points Checked nodes in the manner described. Although only three nodes X, Y and Z shown can in practice use the step switch with the required Number of contact points to be provided. In the embodiment described here each step switch has 52 contact points in each step, so that the ones shown Contact points 2 «,» 3.r and "4vW all contact points between points 1 and 52 illustrate. These last two contact points are used for control of the automatic workflow described in connection with FIG. ii will. Each step switch means there are 50 contact arm positions for testing available from network nodes, d. H. the switches 51, 52 and 53 have together a capacity of 150 nodes in a single network.

For the described test of nodes with no more than five connection electrodes are sufficient for the five steps of a single step switch, to be able to test all five connection electrodes. However, many networks contain Nodes with more electrodes and the available switch levels are sufficient not from. So has z. B. the Z group of thirteen electrodes shown in FIG. 10, the fourth step switch 54 must also be used to test them. However, no resistors R ", Rv, etc. are directly associated with this switch. If the contact arms of the switch 51 have completed their full rotation and back on the contact points 2 "rest, the electrodes Z 1, Z 2, Z3, Z4 and Z5 are already checked. The contact points y2 «and y3 (of the stage L 1 of the switch 54 are as already mentioned by the connecting cords 153 connected to the electrode Z5, and if therefore the L1 contact arm 164 of the switch 54 moves further to the contact point "2", he grounds the Z-node again. At the same time, the contact points »2« of stages L2, L3, L4 and L5 the electrodes Z6, Z8, Z10 and connected to them Z12 checked, and the relays M2 to M5 remain energized, if no undesired open circuit between one of these four connection points and point Z5 consists. Similarly, if the step switch 54 is moved further to the contact point , 3 «the connected connection electrodes Z7, Z9, Z11 and Z 13 are checked and completed thus the test of the Z-node. How hot is the mode of operation of the step switch 51, causes any open circuit between the connection points of the node the corresponding relay M drops out.

It has already been mentioned that the contact points,> 4 of the switch 54 do not have any connections to the unit 100 under test, but rather are grounded through the control panel 142. This shows that the stepping combination, intended for testing networks of various sizes and intricacies usually has more contacts than the network being tested requires. The surplus Contact points are therefore earthed to prevent the relay M from dropping incorrectly during to prevent automatic circulation, which is then used in conjunction with the Fig. 11 will be described.

The step switches 51 to 54 are controlled by the solenoids 515 to 545. To generate the required working voltage, which is -330 Voft to earth 115 is assumed, a power generator 183 of known type is provided, which is connected to an AC power supply line 184. The middle contact spring 185 of a starting changeover switch 186 is connected to the -330 volt voltage source and normally acts with contact 187 connected to line 188 together.

The L1 contact point "1" of the step switch 51 is via a line 189 connected to one end of the winding of a changeover switch relay H 1, its the other end of the winding is connected directly to line 188. At the Ll contact point "1" of switch 52 is connected to a similar changeover switch relay H2, in however, its connection to line 188 is a normally open contact C 2-1 a relay C 2 is switched on, the coil between the line 188 and the last Ll contact point "52" of the step switch 52 is switched. A second normally open contact C2 of relay C2 is closed when it is energized, to create a hold circuit for relay C2 as described below will. The relay H2 can therefore only when the contact C 2-1 of the relay closes C 2 are excited, which again only via the L 1 contact point "52" of the step switch 52 can be excited.

The step switches 53 and 54 are similarly relays H3 and H4 assigned their excitation under the control of the contact points at the Ll »52« of the relays C3 or C4 connected to the corresponding switch takes place. To the Output line 191 of a current source 190 for emitting direct current pulses is the middle contact spring 192 of the changeover switch controlled by relay H1 connected, its normally closed contact Hl-l with the winding of the solenoid 515 of the step switch 51 is connected. The normally open one Contact 111-2 is via line 193 with the middle contact spring 194 of the dem Relay H2 associated contact pair connected, its normally closed Contact 1121 is connected to the solenoid 525 of the second step switch 52. Similarly, the normally open contact 112-2 is with the middle one Contact spring 195 of the relay contact 113-1 and with the solenoid 535 of the step switch 53 connected, while the normally open contact 113-2 via the normally closed contact 114-1 of the relay H4 connected to the fourth switch solenoid 545 is. The solenoids 525, 535 and 545 are connected to the common return line 196, through the normally closed contact 197 of the starter switch 186 and a line 198 is connected to the pulse source 190. The return of the solenoid 515 runs through the normally open contact A 1 of a relay A to the line 198

Relay A, which can be called the main relay, is between normally closed contact 114-3 of the relay connected to ground H4 and the normally open contact 199 of the starter switch 186 switched, when it closes, relay A is connected to the - 300 volt voltage source and is energized and has a holding circuit through contact A 2 over the line 200 manufactures.

After connecting the generator 183 and the track current pulse source 190 to the AC power grid 184 is the automatically running operation the actuation of the start switch 186 initiated and the relay A energized, which is keeps energized via its holding contact A 2. At the same time the contact breaks 187 of Start switch connects to line 188 so that all relays H and C are de-energized that may have been excited and held in a previous test cycle.

Since the contact HI is now closed, the solenoid 515 receives DC pulses via contact A 1 of relay A and switches the contact arms of the switch 51 to establish the successive test connections. Once the indexing has begun, the starter switch 186 can be released and since the contact arm 163 has already left its contact point "1", the relay H1 remains de-energized and its contact Hl-l closed, so that the solenoid 515 the successive switching of the switch 51 continues.

When the contact arm 163 of the step switch 51 its full revolution ends and reaches the contact point> 1 «again, it closes its circuit via relay 111. Relay H1 closes contact 111-2 when it is energized and thus the pulse circuit via contact 112-1 and solenoid 525, during the relay H2 remains switched off because of the open contact C2-1. As a result of the Now open contact Hl-l of the relay H1, the switch 51 is in the initial position stopped while the solenoid 525 continues to deflate the step switch 52. As soon the L1 contact arm 201 of this step switch reaches its last contact point 752 «, the relay C2 is energized, which is kept energized via the holding contact C 2-2 and contact C 2-1 closes. Then when the contact arm 201 finishes its full revolution and again reaches its contact point, the relay H2 is energized to its contacts 112-1 and 112-2 to switch and the pulse circuit via the solenoid 525 to interrupt and to switch via the solenoid 535 which controls the switch 53.

When the step switch 53 completes its rotation, the relays will be C3 and H3 energize and switch the pulse circuit to solenoid 545, whereby the fourth step switch cycles to end the test. As soon When the L1 contact arm 164 reaches contact point "52", relay C4 is energized and its contact C4-1 closed, so that when the contact arm rests again 164 on, the contact point »1 the relay H4 is energized. By opening the contact 114-1 the pulse circuit is interrupted by the solenoid 545 and the step switch 54 stopped in its basic position, while by opening the contact 114-2 the main relay A is de-energized. At the same time, the now also closed one is being built Contact 114-3 of relay H4 connects to ground to complete the test to signal, as will be described in connection with FIG. 12B. At the end of the automatic cycle, all step switches are in their basic position, and all relays H and C are energized.

Like the operations of the previously separately described test and actuation cycles combined and together with the associated signaling or manual control devices become effective, is then on the basis of FIGS. 12 A to 12 C in conjunction with of Fig. 8 is described. As FIG. 8 shows, the main switch is on the switchboard 118 202, a signal lamp 203, two fuses 204 and 205, a buzzer switch 206, a reset switch 207, a double-pole switch 208 with three switch positions, a signal lamp 209 indicating the end of the test, the starter switch 186, is on Engine switch 210, a voltage indicator lamp 211, a short-term indicator lamp 212 and four switch stage indicator lamps 213, 214, 215 and 216 are provided.

In FIGS. 12 A to 12 C, certain relay contacts are used for control purposes the circuits are not shown directly next to their respective relay magnets, in order to avoid unnecessary line laying and line crossings. The same also applies to the poles of the two-pole switches. In each of these cases are the relays and contacts that belong together as well as the parts of the two-pole switches identified by the same designations.

When the main switch 202 (Fig. 12A) is closed, an isolating transformer becomes 223 via lines 221 and 222 and the two fuses 204 and 205 to the 1 10-volt alternating current network 184 connected. The secondary winding of the transformer 223 is through a line 224 to the internal earth 115 of the device and to the Line 225 connected to which relay A is a rectifier via contact A 1 226 (Fig. 12b) is connected, which is part of the shown in FIG DC pulse source 190 is. The pulses are triggered by a single pole changeover switch 227 (Fig. 12 A) initiated under the control of a driven by a motor 229 four-lobed cam 228 is actuated four times per second. The middle movable Contact spring 230 of switch 227 is connected to earth 115, and the normally open contact 231 is via a line 232 to one end of the winding one Relay T connected, the other end of which via line 233 and a resistor 267 is connected to the 330 volt output of the voltage source 183. The relay T associated normally open contact T2 (Fig. 12A) represents when energized of the relay a connection from the earth 115 via the line 234 and the on one of the two contact points 236 or 237 adjusted contact spring 235 of the hand switch 208 to line 191. As already described, this line is interconnected of the contact Hl-l of the relay H1 (Fig. 19B) the stepping solenoid 515 is connected, which, on the other hand, is connected to the rectifier 226 by a line 238. So when the relay T (Fig. 12A) is operated four times per second under the control of the cam actuated Switch 227 is energized by the successive closing of the contact T2 four direct current pulses for actuating the described in connection with FIG Step switch cycle triggered.

The relay T opens its normally closed when energized Contact T1 to energize the short-circuit fixed relay M1 while advancing to prevent the step switch contact arms from one contact point to the other, as has also already been described in connection with FIG.

A line 239 (Fig. 12A) connects one end of the excitation winding a break relay B to contact 231 of cam-controlled switch 227 or when it closes with the earth 115, while the other end of the winding over the line 240 and a resistor 241 are connected to a line 242, when closing one of the parallel-connected contacts Ml-1, M2-1, M3-1, M4-1 and M5-1 of relays M1 to M4 (Fig. 10) via line 243 and the normally closed contact 207-1 of reset switch 207 to the 330 volt power source is connected. The relay B closes the contact B 1 when energized to one Establish holding circuit for itself and via line 239 for relay T, which is maintained as long as contact B 1 is closed.

The second contact B2 of the relay B closes when it is energized Circuit from the 6.3 volt source through a buzzer 244 and the normally closed Contact 206-1 of buzzer switch 206 to earth 115.

As mentioned earlier, provided that the tested network does not contain any interruptions or short circuits, the relay M2 up to M5 energized during the entire test cycle and relay M 1 de-energized. Under In these circumstances the contacts: 1, M2-1, M3-1, M4-1 and M5-1 (Fig. 12A) open and prevent the excitation of relay B. If, however, during the test cycle a short circuit or a false interruption in the test network the excitation of relay M1 or one or more of the relays M2 to 3 ¢ 5 to drop out, prepare their contacts 311-1 to 315-1 the circuit via the relay B, the by the next closing of contact 231 of cam-controlled switch 227 is closed. The relays B and T is kept energized, and contact T2 can power the pulse circuit over the line Do not open 191 to the now effective stepping dialer solenoid (Fig. T2B). This Solenoid therefore remains energized, and there the indexing of the contact arms of the step switch can only take place when the excitation circuit is interrupted, the corresponding one remains Step switch contact arm on the contact point at which the fault was detected has been.

The timer 227 (FIG. 12 A) is connected to a second contact 245 provided, from which a line 246 via the contacts .kl1-2, M2-2, 313-2 314-2 and 315-2 of the relays M1 to M5 and the signal lamps 212, 213, 214, 215 and 216, respectively leads to a line 247, which by the line 248 (Fig. 12 B) with the not AC line 255 connected to ground. Therefore, if as a result of an established Error in the network the relay M1 responds and one of the relays M2 to M5 drops out, to interrupt the Profumlauf, you can close one or more of the corresponding contacts 311-2 to 315-2 that of the switch contact 245 Pulse circuit passed through the corresponding signal lamps, causing them to the frequency of the pulses light up. Since the relay M1 as a result of a short circuit responds, the lighting of the signal lamp 212 shows the presence of the short circuit at.

The lighting up of one or more of the lamps 213, 214, 215, 216 shows an open connection in the tested network, and there each lamp through her corresponding relay M is assigned to a certain stage of the step switch (Fig. 12C), the stages in the network node between which the interruption is indicated by the corresponding lamp or lamps lighting up.

At the same time, the contact point of the relevant step switch, in which the error was detected, on the dials 217, 218, 219 or 220 (Fig. 8j. A lamp provided under the circuit board 118 249 (FIG. 12A) is used to facilitate observation of the dials.

Therefore, if due to an error in the network under test the test process is interrupted, the operator immediately receives the information, through which the location and type of the fault can be determined.

For each type of network, a terminal test connection diagram is provided prepared when the main switchboard 146 is initially switched. For example, occurs a fault causes the lamp 212 to light up and the dial 218 of the Step switch 52 stops at contact point 537 ", the operator makes a note Short circuit, switch 2, point 37O, and on the basis of this information can immediately be on the Plan and thus the short-circuited node in the network unit being found. Lights up when an error occurs e.g. B. the lamp 215, while the dial 217 on contact point 41 «stops, then the note» open circuit, Counter 1, level 4 «, the exact plan information for the location of the interruption.

If an error has been found and needs to be repaired, the timer motor 229 is switched off by the switch 210 (FIGS. 8, 12A). The second contact 210 a of the switch 210 interrupts the line 180 in the current path from the resistors Rx, Ev, R, etc.

(Fig. 12B) via the contact A3 of the energized held relay A and the tube control resistor R, (Fig. 12A) to the -330 volt source, which causes the Test voltage from the resistors Rz, R ,, usls., Their connected step switch contacts and taken away from the various network electrodes that are across the switchboard 142 and the receptacle 119 (Fig. 3, 4, 10) connected to the switch points are. It will be understood that one of the elements of the thus disconnected from the voltage The test unit is the chassis frame 101 itself, which is via the fault contact 137 and the switchboard 142 with any associated checkpoint in level 1 of FIG Switches 51, 52 or 53 can be connected as well as for the connection electrodes of the network has been described. With this arrangement, the chassis frame can as well how the effective network nodes for a possible short circuit to one of these nodes should be checked.

After the test voltage has been switched off from the unit 100, it can taken out of the container 119 and the fault repaired. Then the Unit 100 reinserted and connected to the container and the motor switch 210-210 a closed again.

During the repair, the step switches are in their last position remained, and therefore the solenoid of the last effective stepping switch is overturned the energization of relays B and T has also been kept energized.

This solenoid must first be used to restart stepping are de-energized, so that the associated Switching arms can be switched. This is done by turning over the contact spring 235 of switch 208 (Fig. 12 a) in the left "Weitererscilalt" position 250, so that the connection of the line 191 to the earth 115 interrupted and the kept energized Solenoid of the corresponding step switch is switched off and the associated Move the contact arms one step further to the next correspondence point. To resetting the switch 208 to its middle position and if nothing else There is a network interruption or a short circuit in connection with the contact points, on which the indexed contact arms of the step switch now rest DC pulses are again applied to the previously excited stepping solenoid, to continue the automatic test sequence.

If for any reason of a work flow the device is to be reset to the starting position, the reset switch contact 207-1 (Fig. T2A) can be opened to energize relay B and stop it to prevent resetting for any reason while the step switch continue their rotation to the starting position.

While the tester stopped to troubleshoot network errors the buzzer 244 can be activated by opening the contact 206-1 of the switch 206 (Fig. 8, 12A). However, to the possibility of accidental continuation switch off the rest of the test while the buzzer is switched off, is the buzzer switch 206-1 is provided with a second contact spring 206-2, which when Turning off buzzer 244 through contact 206-1 of line 191 via the contact point 251 connects to line 234.

As a result, the switch 208 is bypassed when its arm 235 is in the ^ Next switch position is turned to contact point 250, and the connection the line 234 to the line 191 cannot be disconnected to the DC circuit Interrupt via the step switch solenoid until the buzzer switch 206 again is returned to the normal position according to FIG. 12A.

Although failure of other parts of the device is quick to show would if by failure of tube 182 or associated elements of the short circuit test circuit the relay M1 does not respond correctly, a test cycle could be carried out without the determination from short circuits actually existing in the network under test. It is therefore desirable to be able to test this hold-open combination yourself, and for this purpose; the switch 208 is provided with a second contact arm 252, the line 234 (Fig. 12 A) over when adjusting to the contact point 253 two resistors 254 connected in parallel with the one connected to the common line 180 connected line 255 connects. The resistors 254 are the same as the test resistors Rx, Rv etc. so that the size of the resistance value of the resistors connected in parallel 254 is equal to the resistance value of the resistors R ″ and Rç connected in parallel is. Therefore, when switch 208 is in the right or> short circuit vr position (Fig. 12A) is set, the relay contact T2 is established when it closes for the first time a circuit from ground through resistors 254 to the common line 180, and so the same potential drop occurs across the resistor R, its value equation (3) indicates. There will therefore be a short circuit in one under test Faked network. When the tube 182, the relay M1 and the corresponding Parts are working correctly, a short-circuit display and the interruption of the automatic test sequence in the same way as if an actual network short-circuit would have been determined. This exam can take place at any time during the Operation of the device.

Referring to Fig. 12B, it is one indicating the completion of the test Lamp 209 between AC line 225 and the normally open contact 114-3 of relay 114 switched on. If relay H4 responds at the end of the test cycle, it opens its contact H4-2 to switch off the main relay A and closes the Contact H4-3 to connect lamp 209 to earth so that lamp 209 lights up and indicates the end of the cycle. When relay A drops out, the one that opens switches Contact A 3 (Figures 11, 12A) the test voltage from the container and the unit under test away.

The lamp 211 (Fig. 8, 12B), on the one hand via the holding contact A 2 of relay A to the 330 volt source and on the other hand via a suitable resistor 256 is connected to earth 115, shows this during the entire test cycle Presence of the correct test voltage. A second contact 206-2 of the reset switch 206 bridges the contact 185je87 of the starter switch 186 in order to switch off the Relays 11 and C prevent when the start switch 186 initiates a new one Test cycle before resetting the reset switch 206 to the »run setting is operated.

The process of a typical test procedure is brief in the following summarized. First of all, the Main switch 202 closed to the power generator 183 to the 110 volt alternating current network 184 in order to this and the tube 182 to heat. The unit to be tested 100 is inserted into the receptacle 119 in such a way that that they plug with the lower multiple plugs 127, the upper plugs 135 and the multiple plugs 128 and 129 cooperate in the position shown in FIG. Then the Motor switch 210 (Fig. 8, t2A) closed and the starter switch 186 pressed briefly, to ensure that all relays H and C are de-energized and to close relay A. irritate. Thereupon the automatic cycle begins and the relays H speak and C successively to the DC pulses to the next sequential step switch transferred to. If there is no error, the most recent one is used When relay H4 is excited, relay A is switched off by opening contact 114-2, and the signal lamp 209 lights up. Now the motor switch 210 and the voltage disconnect switch 210 a reopened to remove the tested unit from the container and to be able to use the next unit for the same exam.

If an error is detected during the test cycle, the The test is interrupted and the last effective step switch is stopped, it sounds the buzzer 244, and at the same time either the short-circuit indicator lamp 212 is lit. or one or more of the interrupt level indicator lights 213, 214, 215 and 216 with the frequency of the direct current impulses, i.e. four times a second. The operator now establishes the type and location of the error by observing the dials 217 to 220 the step switch and the lit lamp or lamps firmly opens then the motor switch 210, removes the network fault and continues the test by actuating the "Advance" switch 208 in the already described Away. If another error is found, this process is repeated, until the completion of the check is indicated by lamp 209.

After discovering an error, it is of course not necessary to to carry out the repair immediately, all that is needed is the location and type of the Error to be noted and continue checking the rest of the network connections can be initiated immediately with the »Weitererschalt.i switch 208 to start the test to finish quickly. Then the unit under test is taken out and everyone noted Errors can be corrected all at once. If desired, the repaired one can then be used Unit must be checked again in order to also verify the repairs that have been carried out check.

According to FIG. 11, the contact 111-2 is connected by a line 193 connected to the middle contact spring 194 of the contact pair controlled by relay H2, after energizing relay H1, the DC pulses to solenoid 525 of the second Step switch to transmit. However, it is advantageous to have this continuous line 193 to separate and the separation points with arranged on the control panel 146 (Fig. 5) Sockets 151 to be provided, which are connected by a switching cord 153 (Fig. 5, 12 B) can be connected to each other. Similar jumper cord connections can be found in the transmission circuits from relay contact 112-2 to contact spring 194 and from the relay contact 113-2 can be provided to contact 114-1. This arrangement allows the Testing of networks with so few nodes that the contact points of the Step switches S2 and 53 are not required, these step switches from the test cycle turned off. In this case, switch cords 153a and 153b are omitted and a direct circuit connection from contact 111-2 to contact 114-1 manufactured. Therefore, the solenoids S25 and 535 cannot pulse during the revolution received, and the step switches 52 and 53 are removed from the test cycle. After the contact switch 51 has fully rotated, the pulse transmission then takes place directly to step switch 54.

The various resistors arranged in the circuits, e.g. B. 259 (Fig. 12B) are used to limit the voltage drop in the associated Relays, etc., and the various capacitor-resistor combinations, e.g. B. 260 (Fig. 12C), prevent the contacts from sparking when they open. These precautionary measures are known and are no longer explained.

As already mentioned, it is necessary to remove all unused contact points the effective stepping switch to ground to prevent false readings of open circuits to avoid. This ground is provided in the original panel wiring. If network units are to be checked that are not the full width of the container 119 occupy, a frame 257 (Fig. 6) is used in the remaining space, its Conductor plate 258 the remaining container contacts 130 electrically with one contact 130 a connects. This contact 130a is grounded through the switchboard and forms the ground for all other connected contacts, creating a large number additional panel wiring is avoided.

In the described embodiment of the invention, the frequency is the switching pulses are assumed to be four pulses per second, and since each of the four Step switch containing 52 contact points is when using all four step switches the time required to carry out the test of a network without errors is less than t minute, and this short time is further shortened if one or more the step switch is not needed. On the other hand, it must be used to test networks with a very large number of nodes and electrodes the device with the required number of step switches and the relays assigned to them H and C are provided.

The receptacle 119 can of course, although it is shown in the drawings is shown only to accommodate the network unit 100, so modified, to accommodate chassis networks of various shapes and types. Absolutely necessary is just that the connection points of the network for the contact elements of the container are accessible, which can be of any suitable type, such as. B. spring operated Pins or the like, as well as the illustrated spring fingers and socket pins.

Claims (4)

PATENT CLAIMS t. Electric automatic test device for detection of interruptions and insulation faults in the wiring of electrical apparatus parts Calculating and accounting machines, characterized in that after the onset of the to be tested apparatus part (100) in a correspondingly adapted receiving frame (119) of the test device (117) the individual lines of the test object in known Way with the help of an interchangeable Circuit board for certain test programs in Circuits are placed over the known electromagnetic control Step switch (S1 to 54) are passed one after the other test pulses, under which Control both a short circuit (by means of resistors R; z R ,,, Rz and relay M 1) between adjacent lines or between a line and the chassis frame (101) of the device under test as well as a line break (by means of relays M2 to M5) and the type and location of the fault with the help of the respective position the selector switch (e.g. by means of signal lamps 212, 213 to 216 and dials 217 to 220) is displayed and further testing (using relay B) is interrupted. 2. Arrangement according to claim 1, characterized in that accordingly multiple multi-stage step switches (S1 to 54) are provided, their step-by-step advancement under the control a cam-controlled timer (127) takes place in such a way that the advancement the contact arms of a step switch (e.g. S2) only begins after the contact arms (e.g. 163, 170, 174 to 176) of the previously effective step switch (e.g. B. S1) after its full rotation back into the basic position (on the contact point "1") have reached, and that at this point in time the pulse circuit is via this Step switch (S1) controlling solenoid (515) interrupted (by means of relays H1 and its contacts Hl-l, H1-2) and via the solenoid (525) of the following step switch is closed. 3. Arrangement according to claims 1 and 2, characterized in that that the resumption of the test and the advancement of the as a result of an established Error stopped step switch by manual actuation of a switch (208) takes place, when operated, the controlling solenoid is de-energized and the step switch is switched by one switching step. 4. Arrangement according to claim 1, characterized in that the individual Lines of the test object resistors (R ;, "R ,,, Rz, etc.) are assigned via the when moving the contact arms of the step switch (e.g. S1) to test Line interruptions at the same time a circuit for testing short circuits or insulation faults is closed, so that when such a fault occurs via at least two of these resistors, which are now connected in parallel (e.g. Rx and R ") and a further resistor (Rg) in series with them, a circuit produced and by the resulting increased voltage drop over the latter resistor (R) conducts a vacuum tube (182) and one in its anode circuit switched relay (M1) is energized in order to carry out the further test (via contact 311-1 and relay B) to interrupt and the error (through contact 311-2 and signal lamp 212). Documents considered: German Patent No. 726 304; U.S. Patent No. 2,622,130.