BE518793A - - Google Patents

Description

       

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  PERFECTED DEVICE ALLOWING THE RECORDING OF THE READINGS OF AN INSTRUMENT
OR A GROUP OF INSTRUMENTS.



   The present invention relates to the recording of readings or data of an instrument or a group of instruments. It does not apply to point or leader line records on a graph, but allows data to be printed by "typing" on a record sheet. With this recording, one obtains columns of figures, with or without signs, "stamped" in appropriate places of the recording sheet.



   The device by which the record is printed may be a modified typewriter. Such an organization offers the advantage that it is possible, by ordinary manual control of the keys, to add typed information to the record sheet at will.



  The gist of the printing device is that it contains a number of character control means; each of these means prints one or more numbers or signs and is placed under electro-mechanical control in combination with a carriage carrying the recording sheet and a means serving to produce the relative displacement between the sheet and the character, that is that is, to move the sheet where the character is typed step by step (space movement).



   The electro-mechanical control device can consist of an electromagnet whose armature is fixed to the lever of the character; so as to attract the latter downwards when the electromagnet is excited, which gives an effect equivalent to the action of the finger on the key.



   The apparatus also has a multi-directional switch (or group of switches) set for each of the data to be recorded.



  Once the setting has been determined, the printing device begins printing the data on the record sheet.

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   The term "readings or data" is used herein to indicate a value to which an instrument (or a group of instruments) is brought either by hand or in some other way. It is possible that the instrument may be such that a visual indication is given so that an actual reading can be taken. However, in many cases this will not be so and this is not necessary for the practice of the invention.



   In the aforementioned main patent an apparatus of this type has been described. The present invention relates to a modified and improved embodiment of such an apparatus, the object of which is to increase the speed of operation and to reduce the manual control required.



   An example of a recording to which the inversion which is described in the aforementioned application could be applied is the testing of the groups of wires (quads) of a telephone cable for unbalance capacities and mutual capacities. As is known, this requires for each group of conductors the taking of a certain number of data or readings made in an appropriate order representing the capacities for imbalance and the mutual capacities between the different elements of the group and between such elements and other parts of the cable. For each group there may, for example, be eleven readings or readings, each consisting of a sign followed by one or more digits.

   Readings or readings are obtained by adjusting a capacitor, or groups of capacitors, to achieve equilibrium in a bridge; the adjustment can be made either on the plus side or on the minus side with respect to zero. When recording, the digits are arranged in columns (which may be eleven in number) following a row on a sheet of paper. At the beginning of each line, a symbol or sign is "struck" indicating the identity of the group of conductors, during the test, then come the inscriptions of the tests. In such a case, as each setting of the switch or group of multi-directional switches is made, the recording apparatus is set in motion and the appropriate reading is "punched" or "tapped" on the sheet. record in the appropriate column.

   The present invention relates in particular to this type of recording apparatus.



   According to the description of said main patent application, the circuit connections are established by the multi-direction switch (or by the group of switches) for one or more columns of digits, with or without signs, and these connections cooperate with other connections made by a position switch actuated by the carriage spacing mechanism relative to the character of the printing device.



  In this way, a circuit is established for each pair of associated positions of the multi-direction switch and the position switch for the actuation of an appropriate character for printing a part of the statement or given to the correct place on the record sheet. This organization ensures that each statement or data is printed in the appropriate column of the sheet.



   In the method of operation set forth in the aforementioned application, the printing control circuit includes both the multi-direction switch and the position switch, so that the former must remain in the set position as the result of a reading or reading during the time when this reading is being recorded on the sheet.



  The next test cannot start until this recording is finished. Thus, in the apparatus described above, the operations of adjusting the readings and their printing depended on each other over time; the adjuster and the printing device could not work simultaneously. By means of the present invention, this interconnection in time relation is eliminated and it is made possible to prepare a reading to be taken while printing is continuing. By this means, the time required to perform a complete series of tests is greatly shortened.



   This result is achieved by the use of a recording relay system which will be called hereinafter "storage relay", some of which

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 are brought into the operative position by the multi-direction switch for each reading and are retained in this position, independently of the multi-directional switch, and in combination with the position switch establish the necessary printing circuits. Immediately after obtaining a multi-directional switch setting, following a test, the appropriate storage relays are energized and latched, after which the multi-directional switch is free to perform the test. next.

   Latch circuits are provided to ensure that the independent but related operations of the multi-directional switch, and the storage relays take place properly. Thanks to these interlockings, if the actuation of the character by the storage relays to allow the printing of the test result is for example not carried out within the time taken by the test apparatus to set the multi-direction switch to take the next test, the setting is held in the multi-direction switch until printing is complete and the storage relays can be energized for the next reading.



   Since each print line on the record sheet relates to a series of tests applied to a particular group of yarns, it is necessary to apply an identification mark to each line. This can be done by printing a number in the first column of each row. By virtue of the present invention and in accordance with the system of independent but related operations mentioned above, this identification number can be printed in its proper position while the first test is in progress.

   This can be done by a counter mechanism used to number the lines in numerical order, this mechanism controlling the characters by their control electromagnets controlled by interlocking devices (similar to those referred to above). above), which prevent the storage relays from energizing the print electromagnets to print the first try report before the ID number is printed. When each printing of this number takes place, the counter adjusts itself and is ready for printing the next number, which occurs when the position switch provided on the typing device returns to the position it was in. found next to the first column of the sheet.

   This can be done by hand or by actuating a relay through the position switch when the carriage reaches the end of a line to force it to come to the beginning of the next line.



   According to the invention, another automatic control is obtained by interconnecting the test sequential combiner and the position switch provided on the "strike" device and by making the operation of the sequential combiner automatic. This test sequential combiner can be, for example, a rotary switch having a number of rows of contacts which in each angular position of the switch make the appropriate connections for a particular test.

   This switch may have an additional row of contacts interconnected with the printing device position switch contacts, so that the circuits necessary to ensure the correct location of the carriage for each test are jointly established by the combiner. sequential test and the position switch. It is also possible to provide for the omission of certain tests, for example in the case where these tests are unnecessary in the case of a certain type of cables. This can be achieved by manual control of keys which establish new connections of the position switch and the test sequential combiner so that they pass through certain normally operative positions without performing the appropriate tests there.



   The invention is further described with reference to an apparatus according to the invention for automatically recording tests made on "quads" of a telephone cable. The apparatus shown in the appended drawing in which: FIG. 1 is a diagram showing by blocks the main constituent parts of the apparatus and their operating relationship;

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 figs. 2 to 6 together constitute a detailed diagram; fig. 7 combines the parts of Figures 4 and 5 which it is desirable to consider as a whole.



   The apparatus comprises a number of relays which are designated by reference letters and the switches which they control are represented by the same letters accompanied by a number. A number of electromagnets have also been provided to perform the mechanical controls and these have two reference letters, M being the first letter.



   All moving parts of the device are shown in their normal condition, i.e. the condition of the device when it is set to perform the first test in a series and before the operator does. press the necessary switches to initiate the test operation.



  All relays and electromagnets are energized by connecting one side to ground, the other side being permanently connected to a direct current source. A triangle has been shown at the free end of a line to indicate the source of direct current, and the grounded terminal of a circuit is represented by the conventional ground sign. In fig. 1 where double lines have been shown leading to the parts of the apparatus, it is understood that they conventionally represent a large number of suitable conductors for the cooperation of the two parts of the apparatus.

   The blocks of FIG. 1 which are shown in detail in the other figures are: an SR group of storage relays, a group of TAM character control electromagnets, the SRC contacts of the storage relays, the AC "quads" counter, the multi-directional MS switch, the PS position switch, the TSS test sequence combiner, and the SS tap selector switch.



   The object of the apparatus is to measure the capacitance conditions existing between the four wires of a "fourth" telephone cable and between these conductors and the conductors of a neighboring "fourth". The conductors of the "quads" to be tested are connected by hand in the correct order to a number of taps and the "quad" is made to be connected to the test apparatus by a tap selector switch. SS. Four "quads" SZ, SA, SB and SC have been shown connected to a junction box 1 from which appropriate connections lead to the socket switch SS. The SS switch makes it possible to obtain a series of eight connections culminating in a TSS rotary sequential test combiner comprising a certain number of rows of contacts of which only one (TSSII) is indicated in fig 1.

   The TSS Sequential Test combiner has twelve positions and allows connections to be made for a series of eleven tests. Each of the eleven tests is carried out by a bridge 2 which balances itself automatically. The rows of switches that provide the necessary connections between the conductors from the SS tap selector, bridge 2, and an oscillator 3 are found in the TSS1 switch assembly.

   Another TSS2 switch assembly contains the rows of contacts necessary to make the interconnection between these conductors and an automatic insulation controller 4. Bridge 2 and the apparatus associated with it, as well as the insulation monitor do not. part of the present invention, as they are protected by the patent applications filed in England by the applicant under No. 8961/52 of and 13147/52 of
The SS tap selector switch and the TSS test sequential combiner are automatically controlled by organizations described below.

   The tests are recorded by a modified typewriter, the carriage of which moves two wipers PSWI and PSW2 which circulate on two contact units PSBI and PSB2 provided in the position switch PS mounted on the typewriter. The organization is, in general, similar to that described and represented in the main patent. As in this application, in addition to being manually controlled by the keys, the characters for printing the digits 0 to 9 and the + and - signs can be controlled by the TAM character control electromagnets. Recording the test for each "fourth" requires twelve columns.

   In the first column, we print the identification number of the "quarte" and, dam

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 Each of the other columns, a test report is printed consisting of a sign followed by a number of one, two or three digits. The contacts of the two units PSBI and PSB2 of the position switch are thus divided into twelve sets. In the PSBI unit, each set contains five contacts numbered from 1 to
5. In the PSB2 unit, each set consists of a short contact in the same position as contact 1 of the PSBI unit and a long contact covering all positions 2 to 5 in that row.



    Some of the contacts of the COLI group of the PSB1 unit are associated with the "quadruple" counter QC which comprises a certain number of uni-selectors provided with means to allow the return to the starting position required to number the first of a series. "quads", for example those forming a layer in a cable.



   A multi-directional switch MS is associated with the adjustable differential capacitor 27 provided in the bridge 2. The adjustable element 5 of the capacitor 27 is driven by a reversible motor drive such as that described in the aforementioned British application No. 8961/52. and is connected to the multi-directional switch MS by a speed reducer.



   The contact units of the multi-direction switch provide three columns of numbers and the two + and - signs. The switch MS can come to rest in any position corresponding to a reading and is locked in each of these positions by a pawl 36 engaging in one of two notches 35 formed in a disc 34 carried by the switch. Lock-out is determined automatically upon completion of the test, i.e. once a bridge 2 equilibrium is achieved. The multi-directional switch MS establishes the circuits of the storage relay group SR, which consists of the storage relays A to Z. These storage relays are automatically latched by means of switches A1 to W1, Y5 and Z5.

   TAM group of character control electromagnets has MO to M9, M- and M + series and also MA spacer solenoid which controls typewriter spacer bar, spacer solenoid MC tabulator and an MB electromagnet for return of the carriage. Appropriate switches are controlled by the storage relays and the QG "shift" counter to select the appropriate electromagnets to print the "quarter" ID number and the bridge reading. These elements will now be described in more detail along with the interconnection circuits.



   The SS outlet selector switch has five units 6-10.



  Units 6 to 9 each have four fixed contacts and three wipers.



  The fixed contacts are connected to the "quads" by the interconnection box 1. The wipers of the five units are controlled by a common drive shaft 11, by means of: a rotary control 'screen by notch.12.



   The control 12 comprises a rotary drive element 13 and an axis 14 which can rotate by one turn when an electromagnet MM is energized and which can cooperate and rotate a notched disc 15 by 90.



  The notched disc 15 is fixed to the axis 11. From the SS tap selector switch leave eight conductors forming two groups 16 and 17. The tap selector switch has the role of connecting the cores of one of the "quarters" to the group 16; another "fourth" to group 17 and a "fourth" to ground, the fourth "fourth" not being connected. The fourth "fourth" represents a "fourth" which has been tested and replaced by a new "fourth". The TSS test sequential combiner is driven by a rotating element 18 carrying an axis 19 and capable of making a full revolution when The electromagnet M1 is ordered The axis 19 engages in one of the twelve notches of the driven disc 20 fixed to the common shaft 21 to which all the rubbers of the TSS test sequence combiner are attached.

   The sequential test combiner TSS is thus moved by a twelfth of a turn on each command of the electromagnet ML.



   The test sequential combiner units inside the TSSL switch assembly provide the appropriate connections between conductor groups 16 and 17 and bridge 2. The bridge elements have two fixed capacitors 22 and 23, two inductors 24 and 25, a "receiver" coil 26, and the variable differential capacitor 27.

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 two fixed blades and a rotating blade 5. Five conductors leave this bridge network to end at the TSS1 switch assembly and the switching enables the bridge to be connected capacitively or inductively, depending on the desired test. An oscillator 3 is also connected by the TSSI switch assembly to appropriate points of the circuit.

   By means of the units of the second switch assembly TSS2, the conductors are tested for insulation continuity by the insulation tester 4 connected to an appropriate voltage source 27 through a switch AZ5. The AZ5 switch is closed by the AZ relay and the cores are automatically tried in order. If all souls pass this test satisfactorily, a
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 BF relay is energized, which depletes the operations necessary to balance the bridge.



  Once put into operation, the bridge equilibrates automatically. The "receiver" coil 26 powers an appropriate amplifier and a balance indicator 28. The output of this indicator 28 is taken at the coil 29 of a polarized relay AB which can cut off the drive of the moving element 5 of the capacitor. differential 27 when an equilibrium condition is reached. At the end of this operation, the appropriate storage relays of the SR group have been activated and locked. The position of the multi-directional MS switch when the bridge is balanced lets you know which storage relay has been ordered. The multiple MS switch
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 directions has five switch units ES1 through MS5.

   Each of these units has a rotating wiper arm 30 movable in a circular row.
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 of fixed contacts. The arms 30 of the BEI and MS2 wiper units are driven by a common shaft 31 connected to the shaft 32 by which the differential capacitor 27 is driven through a speed reducer 33, so that the shaft 31 makes a complete revolution during a unit variation of capacitance of capacitor 27. For example, this unit variation can be 100 pf, the total range being 1 2,500 pf
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  The Zist and i'.52 multi-directional switch units are dual units, one for negative readings, and one for positive readings.



  - 2. ':.' v; -----:. = =: = ± - l.- = .. 1: '. The two switch units H31 and MS2 'have ten fixed contacts numbered 0-9 miter clockwise in the YS2 unit and counterclockwise in the MSI unit. Contacts with the same significant digit are joined together and each pair thus joined is permanently connected to one of a group of ten A-J storage relays. Fixed contacts
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 switch units M! 31 and ME2 correspond to the tens digit of the reading. The next unit MS3 of the multi-directional switches has a central 0 contact and two semi-circular groups of twenty-four contacts extending on either side of the 0 contact.

   During its movement in the clockwise direction, the wiper 30 sweeps the positive unit and, during its movement in the counterclockwise direction, it sweeps the negative unit; these are the contacts of the hundreds. Contacts representing the same significant digit are brought together and each set is linked to one of the appropriate groups of K-T storage relays respectively. The multi-directional switch MS4 unit has a zero center contact spanning the -9 to +9 range of the contacts of the MS3 unit. At the ends of this central contact are two further contacts extending respectively in the range -10 to -19 and +10 to +19 of the contacts of the MS3 unit.

   These contacts are again followed by two additional contacts corresponding to -20 to -24 and +20 to +24 of the contacts of the MS3 unit.



  This is the group of a thousand. The central contact of the MS4 unit is connected to the storage relay U; the following contacts corresponding to the significant digit 1 are connected together and to the storage relay V; finally, the remaining contacts corresponding to the significant digit 2 are connected together and to the storage relay W. The final unit MS5 of multi-directional switches relates to the sign of the reading and has two substantially semicircular contacts extending on either side. from the central position of the friction arm 30, the positive contact on the right and the negative contact on the left. The negative contact is connected to the storage relay Y and the positive contact is connected to the storage relay Z.

   We see that when the device

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 is operating, either of the Y and Z storage relays will be controlled, depending on the sign of the reading and this will close the appropriate switch Y6 or Z6 to choose either the positive or negative unit of the MS1 and MS2 tens contact units The organization is such that the friction arms of MS3 and MS4 move @@ from one of the contacts to the next while the friction arms of the MS1 and NE2 units move from contact 9 to contact 0, in either direction. This requires that the central contact
0 of the MS3 unit is twice as wide as the remaining contacts of that unit.

   In the MS5 unit the friction arm is set to move from the positive contact to the negative contact when the switch arms of the MS1 and MS2 units move from 0 to -la.
To the shaft 31 is fixed the previously mentioned disc 34 having ten equally spaced notches 35 on its periphery. A pawl 36, articulated at one of its ends. and having a protrusion at the other end is normally held with this protrusion engaged in one of the notches by a spring 37. This locks the differential capacitor 27 and all groups of the multi-directional switch against rotation. This locking ends while the bridge is being balanced by energizing an unlocking MK electromagnet.

   The differential capacitor 27 can be controlled manually if necessary and is provided with dials to allow visual reading. When the bridge is balanced, the MK electromagnet circuit is open and the MS multi-direction switch is locked in position, with the storage relay circuits established to print the differential capacitor reading.



  The circuits of the storage relays leaving from the multi-directional switch MS are connected to ground by the switch MK3 when the unlocking relay MK is not energized and by the switches X2 and AR1 which are normally closed. The storage relays close their own holding switches A1 to Z1, Y5 and Z5 respectively and these establish a new circuit through a relay X and a switch A01. Relay X is a slow acting relay to ensure full control of the storage relays before switch X2 is opened; when this occurs, the position of the storage relays becomes independent of the movement of the multi-directional MS switch and this can then be taken advantage of when performing the next test.

   The energization of relay X closes a switch X1 which establishes a circuit for the electromagnet ML which, in turn, actuates the test sequence combiner TSS by forcing it to come to the next position. When the storage relays are latched, they selectively close one or more of the A5 - Z5 switch groups which choose the appropriate character control electromagnets to print the test result.



   Position switch unit PSB1 contains twelve sets of contacts indicated by COLI to COL12. There are five contacts in each set, that is, one contact for each possible print position on the record sheet. As a result, the PSWI wiper is on one of these contacts for each of the possible positions of the typewriter carriage.



  The COL1 contact set is used to print the identification number of the "quarter" and each of the other sets is used to print a test result. The contacts in each set are numbered 1, 2, 3; 4 and 5. Only a few of the contacts are shown in fig 1, but they are all shown in the other drawings.



   In the position switch unit PSB2, the snap-play contacts consist of a short contact in the first position and a long contact covering positions 2, 3, 4 and 5. All long contacts come out. connected together and are earthed during operation of the device by means of switch AJ1 or AA7. Each of the short contacts of the PSB2 unit is connected either directly or by switching to one of the twelve contacts which constitute the TSS11 unit of the test sequential combiner.

   The TSS11 slider arm is permanently grounded.

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 In order to cooperate with the contacts of the PSB1 unit, a motor driven cam 45 operates a pulse switch IS continuously, at an appropriate speed, to imprint one character in pulses, for example six pulses. per second - This IS switch consists of a contact arm 2 carrying a contact which can oscillate between a fixed left contact 1 and a fixed right contact 3 When in the left position, it establishes a circuit passing through relay AM, switch AJ5 being closed, and unit FSB2 of the position switch, assuming that the contactor PSW2 is on a grounded contact.

   When
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 relay AN is energized, it closes its hold switch AH5 and also switch AMI * Via this last switch AI1 .., a circuit is established starting from right contact 3 of pulse switch IS to end at the PSW1 slider provided on the other # <Link of the position switch. When the IS pulse switch is in the right position, bringing contacts 2 and 3 together, it sends a current pulse through any established circuit connected to a contact of the PSB2 unit. of the position switch on which the PSW2 slider rests.
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  Contact 1 of the first set COL1 of unit PSB1 and contact 5 of all sets, except the last of this unit, are permanently connected to the spacing electromagnet MA which, with each command, moves the cart of a space without operating the character. Contacts 2, 3, and 4 of the first set COL1 are connected, via the "quarte" counter QC, to the character control electromagnets and to the spacing electromagnet MA. Contacts 1,2, 3 and 4 of all sets except the first of this unit are connected by the contacts of the storage relays to the character control electromagnets and the MA spacer electromagnet.

   It can be seen that when the PSW2 wiper is on a grounded contact and the PSW1 wiper is on a contact other than 1contact 5 of the last set, a pulse can be sent, via the quad counter or via the contacts of the storage relays, to a character electromagnet or to the MA spacer electromagnet. The movement of the carriage can thus occur following the actuation of a character or not.



   The group of uni-selectors comprising the QC quarter counter is provided with devices allowing the return to the position in which a circuit is established by means of the control electromagnet M1
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 characters when the PSW1 curler bears against the contact, of the first set COL1. This makes it possible to obtain the condition for starting the numbering of a set of quads, for example those forming a layer in a cable. Under this condition, for each of positions 2 and 3 of the position switch, the QC shift counter establishes a connection passing through
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 the HA spacer electrD-magnet.

   The actuation of the electromagnet M of character at the location of contact 4 of the COLI set is followed by the automatic displacement of the shift counter QC to prepare a circuit for the electromagnet of character M2 when the carriage of the position switch is
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 close to position 4 of the COL1 set. This counting and printing procedure can continue up to number 999.



   A slow-acting AO relay is interposed between the contacts of the storage relays and each of the number 4 contacts, except the first
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 of the PSB1 unit of the position switch. These number 4 contacts allowed the entry of the last digit in any test result and, accordingly, when a pulse reaches the appropriate character control electromagnet, through the contacts of the storage relays, in In this position, relay AO is actuated and opens switch A01. This interrupts the circuits leading to an X relay and the storage relays, so that they are released together with their contacts and are put into a condition to be reset by the multi-directional switch MS.

   The slow action of the AO relay ensures the release of all storage relays,
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 that is, it holds switch A01 open long enough for the various holding contacts of the relays to open. Releasing the relay

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 X forces switch X2 to close to prepare for another actuation of the storage relays when switch MK3 returns to the position shown upon completion of a multi-directional switch MS set. To the first small contact of the twelfth set of the unit PSB2 of the position switch PS is connected an AR relay and this is actuated when the movable arm of the unit TS11 of the test sequential combiner cooperates with the twelfth contact.

   The AR relay is the test completion relay and when so energized; it closes the switch AR5 to establish the circuit of the electromagnet MM which moves the tap selector SS one step forward to cause the next quad to cooperate with the test sequential combiner. While this is happening; the switch AR1 (fig. 7) cuts the circuit leading to the switch MS in several directions and constitutes a safety against the entry into play of the storage relays under the action of this. MS switch
In addition to the contacts already described of the switch PSB2 unit
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 of positioim, there is an additional contact 46 on the far left of the first set COL1. in a position six spaces away from contact 1 of this game.

   This contact 46 is only operative when a third wiper PSW3 cooperates with it in the initial test position.



   The operations that take place when the typewriter carriage moves over a complete row of the record sheet are as follows:
The SS outlet selector has just moved to bring the quar-
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 te; appropriate under the test condition and the wiper of the TSSU unit of the test sequential combiner is on the first cojtact. The QC quad meter is in the off position and power from an appropriate source has been fed to the device. The PSW2 wiper is in contact with one of the contacts of the set COL1 of the PSB2 unit. A circuit is established from the mass by the wiper arm of the TSS11 unit, contact 1 of
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 In this row, switches KC2 and KD15, contact 1 of the COLI set of unit PSB2, wiper PSW2 and relay AN which operates.

   Contact 2 of the pulse switch IS is also earthed. This closes the in-
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 switch AN1 between contact 1 of set COL1 and contact 37 mentioned above and allows a circuit to be established through the return contactor
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 FSW3 to lead to the MG electromagnet of the keys. The keys' electromagnet releases a; verro'Ll. "Which allows the operator to close the KAI switch with one hand. It should be noted that this switch therefore cannot be closed as long as the typewriter carriage has not returned to the correct starting position A second switch KL1 is connected in series to switch KA1 to allow it to be pressed by the operator, who must thus use both hands to operate the device.

   These two switches establish, with switch AJ6, a circuit leading to relay AZ. This closes the AZ5 switch applying
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 the test voltage "" to the insulation tester 4. When the cores have been successfully tested, the relay BF is energized and this establishes a circuit to the relay AJ which closes its own hold switch AJ2.



   The AJ relay produces the following operations: It opens the AJ6 switch to disconnect the AZ insulation test relay. It closes switch AJ1 to connect the long contacts of the PSB2 unit to ground and to establish the circuit intended for the capacitance test passing through the interrupt.
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 tor AR1. It also closes AJ5 leading to contact 1 of the IS pulse interrupteU 'and energizes the AM relay which triggers the printing of the identification number of @A quad. It also opens the quiescent circuit leading to the electromagnet ML driving the test sequential combiner at AJ6.



   The AM relay is locked in position by closing the in-
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 switch AM5a The switch AMI is also closed so that a pulse can be sent from the pulse switch IS to the switch FsWl of the position switch unit PSB1. When placed on the pre-
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 mier contact of the set COL1. this establishes the circuit to the MA spacer solenoid and the carriage moves one step forward. This brings the PSW2 wiper of the PSB2 unit in the vicinity of the long contact which maintains

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 holds the ground connection leading to this wiper through switch AJ1, The wiper PSWI is also brought to the second contact of the set COL1 of the unit PSB1 and the typewriter begins to "type" the appropriate number determined by the position of the quad counter.

   This automatically forces the position switch to move through positions 2, 3 and 4 to reach position 5 of the COL1 set where the MA spacer solenoid is again controlled, causing the wiper PSW1 is now on contact 1 of the second set COL2. At the same time, the slider PSW2 of unit PSB2 reaches the short contact of the second set COL2.



   The entry into position and entering the identification number of the fourth is carried out as follows: The QC quarter counter has three stages of uni-selectors: QCU, QCT and QCH. Each of these adages has two groups, one of which determines the number to be printed by the position of its wipers and the other of which controls the drive electromagnets of this group. The first mentioned group has floors 38, 39 and 40.



  The stages of the other group are: stages 41 and 42 associated with stage 38 of the QCU uni-selector; stage 43 associated with stage 39 of the QCT uni-selector; finally, stage 44 associated with stage 40 of the QCH uni-selector. The QCU uni-selector determines the units chuffre, the QCT uni-selector determines the tens digit, and the QCH uni-selector determines the hundreds digit. The drive solenoid and the QCU uni-selector is the MF solenoid, that of the QCT uni-selector is the ME solenoid, and that of the QCH uni-selector is l 'electromagnet MD. The uni-selectors of the quarter counter are advantageously of the usual telephone type containing 25 contacts in the arc and up to six stages.

   In the QCU uni-selector, all six stages are used, and in the other two uni-selectors, only four stages are used. In order to be able to use them as ten point units, the opposite ends of the alternate wipers which are normally double ended, are removed, and the contacts are "multiplied" by wiring quintuple over two stages. Thus, for example, the two wipers of stage 38 of the QCU uni-selector behave like a single wiper sweeping fifty contacts, one of the wipers being in contact, while the other is out of contact. These uni-selectors are all of the type which switches to the next contact when the drive electromagnet releases.



   The AM relay operates the first time that the contacts 1 and 2 of the pulse switch contact each other. The switch AM5 locking the relay closes and the contact 3 of the pulse switch IS is connected to the contactor PSW1 and to the switch AM1. Thanks to this arrangement, when the contacts 2 and 3 of the pulse switch IS cooperate, a full pulse is sent to the spacer electromagnet MA. When the contacts 2 and 3 of the pulse switch open, the MA spacer solenoid becomes inoperative, but the ground is maintained on the -PSW2 wiper. so that AM remains operational.

   When the contacts 2 and 3 of the pulse switch cooperate again, a pulse passes over the second contact of the set COL1 of PSB1 to reach the wiper of the stage 40 of the quarter counter which is located on contact 0 and this contact. This is directly connected to the spacer solenoid MA, so that the position switch PS moves forward to the next contact.



  The same thing happens when a pulse comes out of the pulse switch again, the spacing electromagnet MA being connected to the third contact by the wiper of the stage 39 of the quarter counter cooperating with the 0 contact. In the fourth position, the character control electromagnet M1 is controlled by the connection between one of the wipers on stage 38 and contact 1. -When this circuit is established, an AK relay is also energized , which closes the AK1 ibreaker to excite the MF electromagnet.

   When the typewriter prints the number one in the fourth position, it moves one step forward, so the circuit through AK is interrupted, the AK1 switch is open, the electro -Magnet MF is de-energized and the stages of the QCU uni-selector of the quarter counter advance one position to position the counter for printing the

 <Desc / Clms Page number 11>

 figure 2 at the start of the next series of tests. The next pulse from the IS pulse switch is transmitted, through the contact
5 and switches KD9 and KC3 (in the position shown), to the spacing electromagnet MA thanks to the connection between this electromagnet and the fifth contacts of all the sets COLS and COL11.



   The identification numbers of quads greater than unity are printed as follows. After printing the second identification number of the quarter, the QCU uni-selector advances on contact 0 and two circuits are established in parallel by the wiper of stage 42, these circuits leading to a relay AG and to the control electromagnet ME of the QCT uni-selector. The AG relay (figo 6) is a delayed relay which is used to open the circuit leading to the electromagnet ME in AGI. When the ME electromagnet is de-energized, it forces the QCT uni-selector to move to contact 1.



   The circuit is now prepared to print the identification number
10 of the fourth. Thus, a circuit is established on the third contact of the PSB1 unit (figo 3) passing through the first contact of the stage 39 of the QCT one-selector to end in the electromagnet M1 (fig. 4), On the fourth contact, a circuit is established leading to the electromagnet MO controlling the characters by the contact of the wiper of stage 38 (fig. 3) of the QCU uni-selector with contact 0, a similar operating mode is used to print a significant digit in the second position of the position switch PS (fig. 4). In this case, an AF delayed relay (fig.

   6) opens the switch AF1 to interrupt the circuit leading to the electromagnet MD which is the control device of the uni-selector QCH.



  In addition, when the wiper of stage 44 of the uhi-selector QCH passes deco to the first contact, the relay AH controls the switch AH5 (fig. 4) and connects the contact 0 of stage 39 of the uni. - QCT selector to the MO character control electromagnet, so that a zero follows the significant digit in the hundreds position of the fourth identification number when necessary. This condition only occurs on this floor.



   While the quad ID number is being printed in COL1, the first capacity test is in progress. A ground circuit has been established by switches AJ1, AR1 (fig. 4), M2 (fig. 5) and AU1 (fig. 2) to control the AT relay (fig. 2). This closes the switch AT6 to control the electromagnet MK for unlocking the capacitor.



  While the capacitor is being unlocked, the AG relay (fig.



  5) is controlled by closing switch MK1 (fig. 5). The AC6 switch (fig. 5) is closed to lock the AC relay after the MK3 switch (figo 5) has changed position. Switch MK3 has now closed the circuit to electromagnet MJ by means of switch BB6 to counterclockwise drive the differential capacitor 27 and the multi-position switch associated with it. When the AT6 switch is closed (fig. 2), an SMK relay is also controlled and controls a SMK5 switch to connect the coil 29 of the polarized relay AB to the balancing indicator 28.



   Depending on the unbalance state of bridge 2 (fig. 2), one of the two states is established in the polarized relay AB. If capacitor 27 moves to reach equilibrium, contacts AB2 and AB1 will form, but to no avail. When the capacitor 27 has passed through the equilibrium position, the output of the balancing indicator 28 will have the effect of forcing the contacts AB2 and AB3 to close in order to control the relay BA. This gives rise to the following operations: switch BA5 closes to control relay AU, switch AU6 closes to control relay BB, finally, switch BBI closes to lock the two relays AU and BB (figo 2 ).

   The switch BB6 (fig. 5) turns counterclockwise to release the electromagnet MJ and turns clockwise to control the electromagnet MI, so that the capacitor 27 now returns again to the balanced position.



  Switch AU1 (figo 2) has been opened but without releasing relay AT which is locked by switch AT1. Switch AU5 has also been closed in the circuit leading to relay AV. When the capacitor 27

 <Desc / Clms Page number 12>

 returns to the equilibrium position, the contacts AB1 and AB2 of the sensitive relay AB bear against each other and the relay AV is activated. This changes the position of switch AV1 to close a circuit in parallel with switch AT6 and open the circuit leading to the delay relay AT.



  When the AT relay releases, an AT6 switch opens. When the capacitor 27 reaches the equilibrium position, the contact AB2 of the polarized relay AB moves to come into the central position, which terminates its connection with the contact AB1. The AV relay is thus released, so that the AV1 switch returns to its initial position and, since AT6 opens when the AT relay is released, the circuit leading to the electromagnet MK is cut. The multi-directional MS switch (fig. 5) is therefore locked at the desired reading. At the same time, the MK3 switch returns to the normal position to interrupt the circuit leading to the electricity.
 EMI12.1
 tro-magnets BU and MJ which control the rotation of the differential capacitor 27.



   The MK3 switch (fig. 5) together with the AC5, X2 and EV1 switches establish the circuits leading to the wipers of all the units of the multi-directional switch MS. One of the two circuits leads to the MS1 or MS2 units, depending on whether the reading is positive or negative. Switch Y6 is in one of these circuits and switch Z6 in the other circuit, both of which are controlled by recording relays Y and
 EMI12.2
 Z. The choice of the appropriate unit ME1 or HS2 is determined by the position of the wiper of the sign unit 14fS5, If this is on the right contact, the positive relay Z is commanded to open, at the 'place of switch Z3, the circuit leading to the negative relay Y and close, at the
 EMI12.3
 right side of switch Z6, the circuit leading to the lSZ unit.

   More. of these sign relays, three other recording relays are controlled during
 EMI12.4
 the closing of the switch MK3, one being connected to one of the MS1 or NS2 units and the other connected to each of the I'S3 and ES4 units. These relays close the appropriate locking contacts and energize the holding relay X in the manner already mentioned. At the same time, relays A to W close the
 EMI12.5
 appropriate circuits from the PSB1 unit (end. 3, 4 and 7) of the position switch to the character control electromagnets MO to M9 and relay Y or Z (fig. 5) closes switch Y5 or the switch
 EMI12.6
 Z5 leading to the N- or N + electromagnet.

   Relay A, in effect, ": latched the readings of the multi-directional switch MS in recording relays A to W and this switch can now be released to perform the next test.



   When relay X (fig. 5) operates, the circuits passing through the recording relays via the multi-directional switch MS are all opened by opening the switch X2. The TSS test sequence combiner is moved forward by the process of first exchanging
 EMI12.7
 remove the ML electromagnet (fig. 2) by closing switch 21 and then closing switch AI2 after the delay relay AI has operated, which is switched on when X3 closes. The test sequence combiner TSS is thus brought to the next contact and grounds the first contact of the second set COL2 of the position switch unit PSB2.

   This energizes the relay
 EMI12.8
 AM (fig. 3) controlling the pulses in the manner already explained and prints in the second column the statement of the test already carried out, the printing operation being carried out in a manner similar to that already described for printing the number identification of the fourth. A printing circuit s (
 EMI12.9
 blit from the first contact to end either in the IF + electromagnet or in the M- electromagnet (fig. 4) chosen by closing switches Z5 or Y5 (fig. 4). From the second contact, the circuit leads to one or the other of the electromagnets M2 or M1 depending on the position of V5 or of W5.

   From the third
 EMI12.10
 contact, the circuit leads to one of the electromagnets R4D to X9 (fig. 4) depending on the position of one of the switches K5 to T5 and, of the fourth contact,
 EMI12.11
 the circuit leads to one of the electromagnets IKti to M3 depending on the position of one of the switches A5 to J5. Finally, the MA spacer electromagnet is controlled by the fifth contact. It is obvious that the recording relays locked by relay X can be released when the ten digit

 <Desc / Clms Page number 13>

 born is printed. This is done by the release relay AO provided in the printing circuit from the fourth contact. When this AO relay operates, it opens the AO1 switch to interrupt the circuits leading to the X relay and the recording relays.

   The AO relay (fig. 4) is slow to release, which ensures complete release of the storage relays.



   During the advance of the TSS test sequence combiner by the ML electromagnet (fig, 2), the ML2 switch (fig 5) is opened and closed, which momentarily removes the connection to the earth of the circuits of the relays associated with the polarized relay AB of the balance detection circuit, so that the "holds" on these relays are released before the next test.



   As in the case of the apparatus described in the aforementioned main patent, provision is made for cooperation between the switches of the recording relays and the position switch unit PSB1 to ensure, in the recording, proof that the apparatus Recorder functioned effectively over the full range of the three digit record digits when a significant digit appeared in the last or last two digits only. This is achieved, as in the previous case, by moving the sign from the first to the last position. The circuits controlled by the contacts of the multi-position switch Ms are set up so that the desired result is obtained by means of additional relays.



   In the case of a statement with two significant digits, the sign is printed in the second position instead of in the first. Relay U (fig. 5) is controlled from the central contact of the thousand unit Ms4 of the position switch MS and the relay K is inoperative, since the wiper 30 of the hundreds unit MS3 does not work. is not on the central contact. The impulse coming from contact 1 is thus sent, by switch U6 to the spacing electromagnet MA The impulse coming from contact 2 is sent by switch K2 (fig. 4) in its normal position and switch U5, with the electromagnet of sign M- or M passing through the appropriate switch Y5 or Z5. The operations on the remaining contacts 3, 4 and 5 are those already described.

   When the second and third digits of the reading are not significant, the slider 30 of the Hundreds MS3 unit will also be on the center contact, so that the recorder relay K is actuated and the switch K2 is closed. The pulse leaving contact 2 will thus be diverted to the spacing electromagnet MA (fig. 4) by switches K2 and U6. The pulse from contact 3 is deflected to one of the sign electromagnets through switches K5 and U5. The operations carried out on contacts 4 and 5 are not changed.



   If the quad ID number is printed before the first capacity test is performed, the PSW2 wiper will make the first contact of the PSB2 unit COL2 set due to the position switch before it has been grounded by advancing the wiper in the TSS11 unit of the test sequential combiner. The typewriter thus waits for the test to be completed. The same case occurs between printing the results of successive tests.



  If no test is completed before the previous printing operation is completed, printing will take place as soon as the PSW2 wiper cooperates with the first contact in the appropriate column, since this contact will have been set to mass by advancing the TSS test sequential combiner.



  In the event that no test is performed before the result of the previous test has been completely saved, the MS multi-direction switch remains in the locked condition until the release of relay X closes the switch. switch X2 (fig. 5) to establish the earth connection leading to the control circuits of the storage relays. In the final position of the test sequential combiner, the slider of the TSS11 unit is on the twelfth cohtact to provide a mass for printing the eleventh reading in the COL12 set of the record.



   When the final test is completely registered, the PSw1 slider moves to the fifth contact of the COL12 set and an impulse passes to the

 <Desc / Clms Page number 14>

 AQ feedback relay (fig. 4) which blocks the AQ2 switch and the CON1 truck switch to ground out of its normal position. Switch CON1 is a spring-loaded switch which is only open when the position switch PS is in the normal position for the start of a series of tests. Switch AQ1 (fig. 4) closes for control the MB carriage return electromagnet which returns the typewriter carriage to the normal position. Relay AJ is released by opening switch AQ6, thus opening switch AJ1.

   This releases the relays AU and BB (fig. 2) of the balancing indicator circuit and also the AC relay (fig. 5) which opens the switches AC5 and AC6. At the same time, switch AQ5 closes the circuit leading to the ML electromagnet which subsequently operates to bring the TSS test sequence combiner to a first test position in subsequent series. When the scrubber of the TSS11 unit of the test sequential collineur (fig. 2) moves to the twelfth contact, the completion relay AR (fig. 4) is activated.

   This opens switch AR1 to disconnect ground from the test circuits and closes switch AR5 to control the MM electromagnet (fig. 2) and move the SS tap selector halfway through a movement when the sequential test combiner comes to the next position, the circuit leading to the completion relay AR (fig. 4) is opened, releasing the switch AB5 (fig. 2) and the electromagnet MM so that the SS tap selector ends its movement. It can be seen that a new test cannot be started until the position switch has reached the normal position.



   At the end of a series of tests on a cable, it is necessary to return the QG shift counter to the initial position to begin a new series of readings. When the SS tap selector and / or the QCH uni-selector of the shift counter are not in their normal position, the AD rest relay operates and, when the QCT and / or QCU uni-selectors of the shift counter are not are not in their normal position, an AE rest relay operates. These relays close switches AD1 and AE1 which prepare parallel circuits to operate a rest relay AL.



  To return, a switch KF1 is manually closed which controls relay AL and locks it on AL2. This makes it possible to carry out the earthing of all the contacts of the drive stages 41, 43, 44 of the uni-selector ctors of the quarter counter, except the rest contacts 0 of stages 44 and 43 and the rest contact 1 of stage 41, This also makes it possible to connect the wipers of unit 10 of the tap selector SS and stages 41, 43 and 44 of the uni-selectors of the quarter counter as well as their electromagnets MM, MF, ME and MD, in series with their own switches MM1, MF1, Me1 and MD1, respectively, and these wipers operate by "self-interrupting". When each wiper reaches its rest contact, it stops and when the last switch has returned to its initial position,

   both AD and AE relays are released. This releases the idle relay AL and returns the quad counter circuits to their initial state to number the new series.



   If, for some reason, the multi-position switch M5 moves beyond its maximum range, its organization allows it to close the spring contacts constituting an additional value switch. The "excess" value switch EV2 closes to control an "excess" value AA relay and this closes the AA5 switch to turn on a pilot light LY. Grounding relay AJ is released by opening switch AA1 and switch AJ1 opens to stop operation. To prevent the advance of the sequential test combiner TSS, when AJ6 returns to its normal position, switch AA 2 opens in the circuit leading to the advancement electromagnet ML.



  The logging relays do not work because the MS3, MS4 and MS5 units of the multi-position switch are on open contacts, the MS1 and MS2 units are inoperative because none of the Y6 or Z6 switches are closed, and the relay X remains in its normal position.



  The position switch stops on the first contact of any. clearance that it reaches after printing the value of the last effective test.

 <Desc / Clms Page number 15>

 



  The operator now introduces additional capacitors into the bridge and moves two switches KK1 and KK2. The first switch KK1 energizes the locking electromagnet MK and the second switch KK2 interrupts the rest circuit leading to the electromagnet ML of the sequential test combiner which does not return to its position when the relay AA is released . The necessary test is now performed manually and the AA relay is released. The result can be "typed" manually. The TSS sequential test combiner must be manually advanced one notch, the added capacities must be removed and switches KK1 and KK2 returned to their normal position.

   Switches KAl and KL1 are now closed and the device will automatically test and print in the normal way.



   In certain circumstances, some of the tests provided in a row may be deleted. Assume that we must omit tests 1 and 2, 10 and 11. Several switches KC are locked and controlled.



  Among these, switch KC1 earths the third contact of the TSSIO stage of the test sequential combiner and switch KC7 earths the ML electromagnet of the test sequential combiner by its own switch ML1 The TSS sequential combiner advances until the TSS10 stage wiper is connected to ground by its third contact and controls the AX relay. This opens the switch AX5 and interrupts the circuit leading to the electromagnet ML, and the sequential combiner TSS stops in the third position. The switch KC2 changes position to connect to ground the first contact of the set COL1 of the unit PSB2 of the position switch by the third contact of the stage TSS11 of the sequential combiner.

   Switch KC4 opens to disconnect the long contacts of the PSB2 unit which are connected to the grounding switch AJ1. Switch KC6 connects the fifth contact of the COLIO set of unit PSB1 to relay AQ. A tabulator MC electromagnet is connected by switch KC3 to the fifth contact of the COLI set of the PSBI unit and the test completion relay AR is connected by the switch KC5 to the first contact of the COL10 set of the unit. PSB2. The identification number of the fourth is printed as before in the first position, but during this time the third measure takes place instead of the first.

   When the PSW1 wiper cooperates with the fifth contact of the PSB1 unit, the tabulator's MC electromagnet operates to move the position switch through the next two positions, so that the third result is printed while the fourth test is in progress. The test completion relay AR operates when the PSW2 wiper is on the first contact of the COL10 set of the PSB2 unit and the AQ relay is controlled by the fifth contact of the COL10 set of the PSB unit, thus terminating series of tests and returning the mechanism to its original position to start a new series of tests at the third position of the TSS test sequential combiner.



   Another series of tests is carried out using several KD switches. Switch KD1 (fig. 7) joins the sixth contact of the TSS11 stage of the sequential combiner to contact 1 of the COLI set of the PSB2 unit; the switch KD2 earths the first contact of the set COL4 of this unit; switch KD3 isolates from ground, at AJ1, the long contacts of sets COL2 to COL6 of this unit, finally, switch KD5 connects to the test completion relay AR the first contact of set COL10 of the same unit. In the unit PBS1, the first contact of the set COL4 is connected to the solenoid MC of the tabulator by the switch KD4 and the fifth contact of the set COL10 is connected to the relay AQ (fig. 7) by the switch KD6.

   The sixth contact of the TSS10 stage of the sequential combiner is connected to ground through switch KD7, and switch KD8 (fig. 2) connects to ground the idle circuit of the test sequential combiner which now passes into the sixth position. The fifth contact of the set COL1 of the PSB1 unit is also connected to the solenoid MC of the tabulator by the switch KD9 (fig. 7). This now makes it possible to carry out the test and 1, recording the sixth to the tenth tests by a procedure similar to that which has just been described. The only difference is that the tab mechanism has two movements, one when the

 <Desc / Clms Page number 16>

 wiper PSW1 cooperates with the fifth contact of the set COL1 and the other when it cooperates with the first contact of the set COL4.



   The tests corresponding to a line can be repeated if necessary. When the unit is in the normal condition, the SS tap selector can be moved back by turning it one notch by hand and the QCU uni-selector of the quadruple counter can be moved forward to by means of switch KG1 (fig. 6) until it shows one digit less than before. The device is then started in the usual way. To satisfy various circumstances, the tens WCT and hundreds QCH uni-selectors can be moved by switches KHI and K12 respectively (Fig. 6).



   The device can be brought to the normal position at any time by the entry into play of a switch KE1 (fig. 2) which energizes a relay AY and this is locked by the switches AYI and AX2. Switch AY2 now connects the first contact of stage TSS10 of the sequential combiner to ground: switch AY5 establishes the circuit of electromagnet ML of the sequential combiner; the switch AY7 (fig.4) disconnects the test completion relay AR and the switch AY6 (fig. 7) controls the relay AQ resulting in the return of the carriage and the position switch to the normal position. The contacts CON1 (fig. 7) of the truck not in the normal position a'open, to release the relay AQ and open the switch AQ6 (fig. 2) to release the relay AJ. This opens AJ1 to stop testing and printing.

   The idle circuit of the TSS sequential combiner is established at AJ6 (fig. 2) and the latter returns to the first contact position. The AX relay works to open the AX2 switch and release the AY relay which, in turn, releases the AX relay by opening the AY2 switch. Circuits are now normal.



   Printing of the shift identification number can be interrupted by closing a self-locking button KB1 (fig. 4) which controls an AP relay. This establishes connections at AP1, AP2 and AP3 leading to the spacer solenoid MA and from the second, third and fourth contacts of the position switch unit PSB1.


    

Claims (1)

ABSTRACT. ------------- The present invention relates to the new industrial product that constitutes a device for printing a recording of the data or reading of an instrument or group of instruments in the form of one or more groups of digits in appropriate positions on a recording sheet, such a device being described in the main patent. The device described in this patent comprises: a typing device, such as a typewriter, with a number of electrically controlled character control devices; a carriage for the recording sheet allowing a relative movement notch by notch between the carriage and the character to move the typing position on the sheet, finally, suitable switches provided to establish the circuits for the recording. operation of the elements of the characters chosen automatically. The switches include a multi-directional switch or group of switches that can be positioned for each read or data and a position switch actuated by the carriage gapping motion. The circuit connections established by the multi-directional switch (s) cooperate with other connections provided on the position switch to establish, for each pair of associated positions multi-directional and position switches, a circuit enabling the actuation of the switch. 'an appropriate character to print the reading or data in the desired location (or position). The present invention relates to a modified and improved embodiment of such an apparatus for the purpose of increasing the speed of operation and reducing the manual control required. Consequently <Desc / Clms Page number 17> by virtue of the present invention a set of recording relays is provided, some of which are brought into the operative position by the multi-directional switch for each reading and are maintained in this position, independently of the multi-directional switch, to establish the circuits. printing required in conjunction with the position switch. With the logging relays in position, they are latched and isolated from the multi-directional switch which can then proceed to the next test. Interlock circuits ensuring the correct execution of independent but related operations of the multi-directional switch and recorder relays. Using these interlock circuits, if printing of the result of a test is not completed when the multi-directional switch has been set for the next test; Switch setting is held until the logging relays can be energized for the next reading or reading. An identification mark may be printed on each line of the record, preferably a number printed in the first column while the first test is in progress. This can be done by a counter mechanism which numbers successive lines in numerical order. The counter mechanism establishes the printing circuits by direct connection to the character controller, and the register relays cannot energize the character controller until the identification number has been printed. The counter is moved forward step by step, either manually or automatically, at the end of each printing operation of the identification number. The meter is preferably a relay controlled pad switch. When the instrument is one of those which are automatically adjusted according to the reading or reading, for example the variable element of an automatically balancing bridge network, the multi-directional switch which is mechanically coupled to it is maintained by a device. locking device when the reading (or reading) is put down and, during the reading installation or reading, the locking device is kept inoperative by interconnection with the varbable element, The variable element can, for example, control a relay which , in turn, controls the locking device and also the connection between the multi-directional switch and the recording relays. In the event that a series of circuits is to be tested in a certain order, they can be connected in order to the instrument by a sequential combiner which can be moved step by step, interconnected with the position switch. The step-by-step or step-by-step movement is determined by the position switch at the end of each reading or reading and the strike condition of each reading is determined by the sequential combiner once it is able to perform the reading. next test. The sequential combiner may be a rotary switch with several contact stages which establishes the appropriate connection by a particular test in each predetermined angular position. The contacts of one of the stages can be interconnected with the contacts of the position switch to ensure the establishment of the correct location of the carriage for each test, both by the sequential combiner and by the position switch. The apparatus can be set up to test a number of groups of circuits, each group giving a series of readings or readings on a line of the record. The test sequential combiner performs a full cycle of movement while recording each series of readings or readings and a step selector successively connects the groups of circuits to the tester. One step of the selector is automatically moved by the position switch at the end of each series of readings or readings. The carriage supporting the recording sheet can be returned automatically to its initial position after printing each series of readings and at the same time advances the recording sheet to prepare it to receive the next line of reading or reading. The <Desc / Clms Page number 18> Interlock connections between the position switches and the test sequential combiner are such that the device will not begin to operate until the position switch returns to its correct starting position and it will stop operating if, for some reason, the position switch is out of position.