DE1101026B - High-speed automatic printing machine - Google Patents

Description

The main patent 1 081 701 relates to a high-speed automatic printing machine for the implementation of information received as electrical signals in printing types with a uniform rotating type roller, which for each printing position along a pressure cell with a set of all printable Types and with a pressure chamber arranged in each printing position of the printing line, the signals derived from the joint control of pressure control circuits and from a memory which receives the information signals is actuatable. The invention relates to a development of the subject matter of the main patent with the The aim is to increase the operational safety of such a high-speed printing press. Achieved this the invention in that in a high-speed automatic printing machine according to the main patent each pressure control circuit in addition to a thyratron for controlling the pressure hammer actuating Solenoid contains a test thyratron, which is ignited by a pulse from the associated comparator is, provided that the Scheicher department in question contains information that announces that the assigned Print hammer must be actuated in the print phase and that the print thyratron through the Ignition of the test thyratron is prepared so that it is triggered by a signal from the associated comparator can be ignited as soon as the information stored in the relevant memory division the print type corresponds to the type roller that is just entering the actuation area of the print hammer.

An embodiment of the invention is shown in the drawing. It shows

Fig. 1 is a block diagram according to the invention,

2 shows the arrangement of the characters on a type wheel according to the prior art,

Fig. 3 is an illustration of the mutual relationship between character wheel, ribbon, paper and Print hammer,

Fig. 4 is a developed view of the type wheel in a longitudinal arrangement next to the signals through the Code generator can be generated in different positions of the type wheel,

5 shows a circuit diagram of the comparison device and its associated circuits,

6 shows a circuit diagram of the pressure circuits in connection with the associated power supply,

7 is a diagram showing the arrangement of the print hammers, anchors, solenoids, their supports, etc.,

8 shows a further diagram of the arrangement of the print hammers, armatures, solenoids and their carriers,

Fig. 9 is a diagram of the support members for the print hammer and the members, the discs and the Keep type wheels at a distance from each other,

Fast workers
automatic printing machine

Addendum to patent 1,081,701

Applicant:

ίο Sperry Rand Corporation,

New York, N.Y. (V. St. A.)

Representative: Dipl.-Ing. E. Weintraud, patent attorney,
Frankfurt / M., Mainzer Landstr. 134-146

Claimed priority:
V. St. v. America June 13, 1955

John Presper Eckert Jr., Philadelphia, Pa.,

and Earl Edgar Masterson, Brvn Mawr, Pa. (V. St. A.),

have been named as inventors

10 is a circuit diagram of the devices for clearing the memory,

Fig. 11 is a partially sectional view of the type wheel and

FIG. 12 shows a section through the type wheel along the line 12-12 in FIG. 11.

It is known in the art of electronic calculating machines that the result at the output the calculating machine can be printed by means of a machine of the type in which a rotating Type wheel is used. In such a system, the output result, i.e. H. the edition the calculating machine is usually stored or recorded in a memory. After the store is filled, it contains all the information needed to print a horizontal line on the paper. This information is then fed to the print hammers while the type wheel rotates. To one complete revolution of the type wheel, a complete horizontal line is printed, and then the memory is empty. The memory is then again with information for the next horizontal one Line filled. Following this replenishment, the type wheel makes another complete revolution, during which time the second horizontal one Line is printed on the paper. This operation is repeated indefinitely in order to

109 52 & Z385

_t5 . _: _; ; 1 10 1 tM.

Additional horizontal lines on the paper - horizontal rows of gas tubes and ten vertical prints. "" "-. '" right columns "provided on the type wheel

However, the invention does not relate to "'actually tubes in the store 102 are of the type in which the particular organs for refilling the one tube once terminated remain ionized until the store teaches moving the paper and the like rather" 5 Memory is erased (in that the anode potentials available on the tubes, such as the information from the memory, are reduced).
after the check by the automatic aforementioned These gas tubes store the binary information

Test device accepted and at least one in the following form:

single horizontal line of information without first a different binary code for

Errors and miscommunication can be printed. Thus, every character to be printed is selected. If the binary Code "1001" to represent the letter A can be used in connection with the present invention for devices available to those skilled in the art is turned, this letter would be in for the movement of the paper, for the movement of the inking the upper horizontal row of the store through tape and to refill the storage tank, ignite the first and fourth tubes in the row and save a detailed explanation of these 15 and would the second and third tubes Devices are omitted below. left unignited. This process is through the

1 is a block diagram of the invention illustrating the symbol of a lowercase "0" which is driven adjacent and a rotating character wheel 100 set by each of the unfired tubes and engine 101. A memory 102 has the symbol of a small "1", which is placed next to each filled state that is used to print one level of the ignited tubes. It goes without saying that the right information line is the necessary "information". that other forms of storage and. Save If the type wheel rotates, it controls a code that can replace the embodiment shown here. Generator 103, which sends out the movement of the bookings of the type wheel 100 on its various After the memory has been filled and the output line signals at different angle type wheel is ready. To begin the shaft 25 rod A in the printing position, the type wheel 100 generates a binary signal with the code generator 103, the code generator 103
be connected in any known manner. It is the binary signals and their relationship and assignment

usually connected to it by means of a shaft; Information on the characters to be printed are shown in FIG. 4, however, a gear G application can be shown if necessary. Find in terms of turning speed. The relative positions of the characters on the 30 of the type wheel 100 and the delay, the Be type wheel and the signals generated by the code generator of the printing hammer until it is touched are shown in FIG. With the paper, it is necessary to use the

In Fig. 4, the character wheel 100 is already drawn surface with the developed printing of each character emitted signals. As shown, ten should be allowed to occur before the point in time when the right column of characters is present and five printed characters actually reach the printing division. End of the desk characters A to E inclusive. If you want to do that, you have to take into account that the code generator already prints entire alphabets, so 26 print characters can generally begin generating the relevant binary signal around the type wheel in the same way, if the type wheel is still in one of my ways be arranged as it is located for the five angular position which is shown slightly in front of the angle symbol in FIG. If, in addition to 40, there is a position in which the character to be printed arrives in the 26 letters of the alphabet also numbers and / actual printing position. For example, or if punctuation marks are to be printed, the first row of characters in FIG. 4 represents the book can represent additional characters on the type wheel A, and the letter begins to be printed. In an actual execution-representing binary signal already in one form of the invention there was a total number of 51 45 angular positions of the type wheel, which lies before the arrival characters at corresponding mutual distances of the letter A in the printing position,
provided around the character wheel. In this particular, the binary signals shown in Fig. 4 appear

their embodiment of the invention were a hundred output lines 104, 105, 106 and 107 of Fig.l thirty vertical columns instead of ten vertical columns and are changed each time a new one Columns present. It goes without saying that 50 characters are approaching the printing position. A verdict to simplify the explanation, only a few equalizing devices 108 (in the with dashed lines vertical columns and a few "printed characters indicated frame of Fig. 1) each has one Fig. 4 were shown; it "is easy to find the individual comparison unit or a comparison work for principles disclosed to the use of each vertical column to be printed. With others any reasonable number of print characters 55 words is a single comparative work for each of the and expand vertical columns. horizontal rows of gas pipes in storage 102

The number of tubes in the memory is provided in. These comparative works all agree with one definite relationship and one definite match one another, and one of these works is in one-assignment both for the number of characters and for individual characters are shown in FIG. The first work 109 z. B. the number of vertical printing columns, as compared to the 60 in the upper horizontal row of the are applied to the type wheel. It is required- stored binary signal with the binary memory borrowed so much information in the memory 102 about signals generated by the code generator save how to print a full one. Every time there is a match ■ horizontal line is required. The information between the binary stored signal of the is stored in the memory in the form of binary signals 55 memory and that of the code generator 103, notices sent binary signal, it transmits one

The memory contains e.g. B. a horizontal control pulse via line 110 to the element Series of 111 called "gas tubes" for short, which are a regulating and checking control organ for gas-filled tubes (thyratron tubes) for each lowering pressure. The details of this last righteous column to be printed. According to FIG. 1, ten elements named 70 are shown in FIG.

The comparison unit 112 compares those stored in the second horizontal row of the memory binary signals with the binary signals sent out by the code generator 103; whenever it finds a match, it sends a current over the line 113 to the element 114, the forms a checking and the printing process triggering control element. The comparison unit 115 compares in a corresponding way one in the third

finds when the code generator 103 generates the binary signals embodying the letter B, the Unit 129. This unit or this comparative work then signals such a coincidence with the Control element 130 which prints the character B when it has reached the printing position.

The type wheel continues to rotate and the letter C approaches the print position. The letter C is in the fifth and seventh horizontal

transmitted signals; every time it finds a match it sends a signal to that Element 116, which represents the associated control and monitoring body.

In the embodiment of the invention shown in Figure 1, there are ten horizontal rows of gas tubes provided, each correspondingly and correspondingly assigned to one of the ten comparative works

right column is printed on the paper.

It should be noted that the characters on the type wheel are arranged offset from one another in a checkerboard manner are; the reason for this arrangement is explained below. In connection with Fig. 4 it can be seen that the letter C was printed in the fifth and seventh vertical columns of the paper, and that the letter A is in the intervening

horizontal row of memory stored io row of memory stored. Approaching the binary signal with the code generator 103 letter C of the print position, the binary

Signals 404 and 405 (FIG. 4) generated by the code generator 103 and then fed to each of the ten comparison units of the comparison device 108; but only two of these comparison works, namely 119 and 123, show a correspondence with the information stored in the memory 102. As a result, only two of the comparison units, namely 119 and 123, generate output pulses, and these excite the two control units (which are all designed in the same way as the units 120 and 124 such that the letter C is now 109, 112 and 115). These ten comparative works are at the same time in the fifth and seventh valley, each in the same way, corresponding to one each
of the ten elements connected, the controlling and
make testing controllers for printing and
are also all equal to one another.

The comparison works compare the binary code
of the memory with the code of the generator 103 and
generate an output pulse on the relevant
Connection line to the associated control unit
every time the binary signal of the code generator with the binary in the upper horizontal was printed. If the characters on the type wheel in the right-hand row of the memory had matched the signal stored according to the prior art arrangement. If the code generator 103 generates a voltage shown in FIG. 2, the letter would have been any other signal than the one stored in the relevant memory printed previously in the A in the sixth vertical column, so the result would have been 35 and would already be in There is no output pulse on the associated control hand at the time in which the series of C characters enters the line. When the two horizontal rows get out of print position. That would mean that there are still Α-characters of the type wheel 100, one C-character on each side of the printing position (both on the approach, all Α-characters in this right and on the left side) of the letter become two complete horizontal rows occur, 40 A would have to be printed in the sixth column. Thus printed before any other characters have been printed two print hammers can become the two at the same time. In the illustration shown, the C character is to be found in the columns on both sides of the letter A in the first, sixth and ninth letter A. In doing so, they would store the paper in the horizontal row of the memory 102. press against the ribbon and therefore the ribbon As soon as the letter A approaches the printing position, press 45 indirectly against the type wheel very firmly, the binary signals 400 and 401 of FIG Letter A, as far as the sixth vertical column firmly against the paper code generator 103 comes into consideration. The binary signals (from pressing if the ribbon also code generator 103 outgoing) would appear pressed against the letter C in the sixth vertical, which embody the letter A, on the 50 column. This would result in an intermingling line 104 to 107 which are connected to one side of each formation of the letter A which the comparison units of the comparison device 108 has previously printed in this column. Thus, all three show comparative because the color on the letter A is still damp works 109, 121 and 127 is complete at the same time. However, if the staggered arrangement of the characters, coincidence and, the controls 111, 55, as best seen in FIG. 4, are used, 122 and 128 are energized simultaneously. According to the usual, this evil cannot occur (accidentally).

caused by the movement of the print hammer, etc. Delays, the characters A are in the printing position and are being printed.

The letter B then approaches the printing position, and at this point the from change binary signals coming to the code generators and now generate signals 402 and 403 (see Fig. 4) on lines 105 and 106 (see Fig. 1). If z. B. the letter A in the sixth vertical Column has been printed and there should then be a letter C in the fifth and seventh verticals Column, there is no type embodying the letter C in the sixth vertical column available.

In other words: in the case of the invention Arrangement becomes the letter C in the fifth and

The appropriate binary signal is matched by the individual types in each of the 65 seventh vertical columns horizontal rows of memory stored 450 and 451 (Fig. 4) while the letter A is printed in the sixth vertical column by the single type 452. Since the C sign is 453

binary signal compared. Assume that the bottom horizontal row of memory is the letter B is stored, the only

is offset for the sixth vertical column, that can

the same thing, that a correct match 70 hitting the print hammers against the characters 450

νιοι οία

7 8

and 451 the ribbon is not against the sign 453 of the type wheel 120 °, the potentials are at the

move. Lines 104 and 107 -9OVoIt, the potentials on

To use this staggered arrangement in conjunction with lines 105 and 106 +213 volts, etc.

To make fast printing operations efficiently, it is Anodes of the Sp Eicher Rohr en 500-503 einnotwendig, the operation of the controls in the absence 5, finally, are connected to the lines 104 to 107 for

to enlarge alternating vertical columns, binary signals in each case via resistors 509 to 516

namely the control organs 114, 118, 122, 126 and 130. including mutatis mutandis. This cons

This delay is made possible by the center taps 517 to 520, respectively

including each of the means described in connection with FIG. These each establish the connections. i ° to the cathodes of rectifiers 521 to 524 a

As shown in FIGS. 1 and 4, before each and finally to the anodes of the rectifier 525 pressure circuit, a memory search or test pulse, up to and including 528 , is produced. PM is the potential at the Ander hereinafter referred to as, to 524 normally code generator 103 is sent through the barren the rectifier 521 and passes through the positive by a current source 529 to + 85VoIt comparator 108 and is held at different locations of 15, namely via a high-resistance device. At the end of the pressure cycle, a 530 is generated, with a limitation by the limiter memory erase pulse, hereinafter referred to as CM , consisting of a rectifier 531 and a positive, being formed by the code generator 103 to the memory current source 532 . The thus limited 102 sent and causes a reduction in the voltage is sent through a line 533 of the central anode potential on all gas tubes in the tap between the primary winding parts 534 ^ 4 memory in such a way that the memory is cleared and fed to and 5345 of a transformer, the one Rerun is made available. While secondary has 536 . The potential at the cathode of the space between the memory erase pulse of the rectifiers 525 to 528 is below the CM and the memory test pulse PM is sufficiently influenced by a current source 540, which is --475 volts time to refill the memory and to its 25, endeavors to to become negative. This negative preparation for the next pressure cycle is made available by a limiter. For experts in calculating machines, which consists of a rectifier 537 and a technique, it is clear that this process consists almost instantaneously of a positive current source 538 , which, for example, is going on and consequently can have the means for through-voltage of 107 volts. A series management of this process does not need to be considered equal to the primary winding part 5345 . Richter 539 has a potential that is determined by the potential

Fig. 5 illustrates more in detail tial at the cathode of the rectifier 537 as well as through

and operation of the comparison unit 109; even the negative current source 540, the resistors 541

Understandably, the other comparison works and 542, a rectifier 543, a positive current

112, 115, 117, 119, 121, 123, 125, 127 and 129 with 35 quelle544 and the potential of the line 533 is

the comparison work 109 corresponds to the gas tubes 500, is correct.

501, 502 and 503 of the upper horizontal row so-- As shown in FIG. 4, each binary signal, like all other gas tubes of the memory 102, is composed of a series of two pulses each, although they are of any type known per se a larger number were used where a 40 denier tube could be ionized. For example, the binary signal for an ionized state remains until the anode - the symbol A composed of two pulses - voltage is greatly reduced. In the event that the grid 400 on line 107 and two similar pulses ter this tube correctly during the storage 401 on line 1Q4. If the potential at the Leiperiode was excited, the anode potential of device 544 changes in accordance with the changes 213 volts, as shown, to make the tube ioni- 45 of the binary signals. When the binary pulses are 400 ; it then remains ionized until the memory erase and 401 are at +213 volts, so the potential at pulse CM arrives and the voltage of the anode line 544 +71 volts. When the binary pulses voltage generator drops from 213 to 55VoIt. 400 and 401 are -90 volts, while any given tube is ionized, the potential on line 544 is +103 volts. In the same way, the current flowing through it is considerable, and therefore the potential on the line 544 drops, a large voltage drop occurs at the respective + 71VoIt every time the potential of the input resistance 504 to 507 of the complementary pulses 402, 403, 404, 405 etc. to +213 volts connection. If, however, the tubes are not ionized, it will rise; it rises to + 103VoIt every time, then the full potential of the pulses 402, 403, 404, 405 is at the anodes of this tube when the anode potential drops from 213 volts (minus the voltage-55 etc. to -9OVoIt In other words, the voltage drop across the anode resistance means that the potential on line 544 is +71 volts when it is 60 volts, when lines 104 to 109 each of the binary signals is +213 volts because it is -5OVoIt). and otherwise it is + 103 volts.

The binary signals from the code generator appear.

nen on lines 104 to 107 inclusive. The 60 deten resistors can be chosen as follows:

^O oTw ^l £ S «vf ₊ ^er _AÄ ^ ^eitUng ^ 7 ^αη ΪΗ \ 7 *,? ^wa 504 to 507 inclusive .... 39,000 ohms

90 to +213 volts. B. the angular position _{509 5U 513 515 22} ' _{Qm Qhm}

of the character wheel is 0 ° (see Fig. 4) then the potential is _51Q ^ ^ _{51Q 1QQQ Q}

on each of the four lines 104 to 107 inclusive ^ ₃₀ 850 000Oh

- 90 volts. If a binary "1" signal is on the line 55 ~ λ \ SSOOf) O Oh " ¹

lines 104 to 107 , as is the case for an angle -40 'cn'nnn ην, " ¹

of approximately 30 ° (see FIG. 4), then * t α mn nh increases

the potential on these two lines to +213 volts ^{% IW Uüm}

while the potential on lines 105 and FIG. 4 shows A, on a larger scale schematically

106 remains at -90 volts. If the angular position 70 the relationship between the pulse train 400 and

ίο

As explained in connection with FIG. 4A, the potential at terminal 544 fluctuates between +71 and + 103VoIt. During the intervals in which the terminal 544 is at +103 volts, the 5 potentials in all four lines 104 to 107, inclusive, are at -90VoIt; this causes the potential on line 533 to drop below +71 volts, for reasons given below, and consequently rectifier 539 is blocked.

Its cathode is connected via line 544 to + 10'3VoIt, and its anode is maintained at less than + 85 volts, due to the low potential on lines 517-520, inclusive. This means that no current flows through the primary winding

Potential on line 544 to be 103 volts, as shown at 483.

The operation of the comparison works is described below:

Assume that the binary signal A is generated by the code generator and appears on lines 104 to 107 at the same point in time as the upper horizontal row of S ρ ei rather roar

the potential on line 544. It is clear that,
if a binary "1" signal is on line 107 ,
an alternating current occurs between -90 and
+213 volts fluctuates. In Fig. 4 only two periods of such an alternating current are shown, the
each of the binary signals 400 to 405 inclusive
should embody. It is clear, however, that each of these
binary signals can consist of a larger number of periods. For example, in Fig. 4, A is a
Signal 400 · represented by five periods that go into io
Have positive going half waves 480 and negative half waves 482 . Every time the signal 400,
as with 48Oj goes on the positive side, that falls
Potential on line 544 to +71 volts, as at
481 shown, and each time the signal 400 15 averaging part 5345. During those periods in the negative side, passes over as at 482, the increases which the potential at the terminal 544 at +71 volts

is, current flows through the primary winding 5345 if it is assumed that there is a match (coincidence) between the code generator and the first horizontal row of the memory - all as explained above. Thus, in response to any correspondence between the code generator and the top horizontal row of the memory, a series of pulses will flow therethrough

501 to 503 the letter A corresponding to its 25 the primary winding part 534 B, which contains an output binary code, the control process is how power is generated in the secondary winding 536 , as follows: The tubes 501 and 502 are deionized, it is now assumed that none accordance

while tubes 500 and 503 are ionized. Further, between the binary, stored in the memory, lines 104 and 107 are on signals and the binary, on lines 104 to + 213 volts, while lines 105 and 106 are 30 107 including given signals, so they are at -90VoIt . The above information does not result in an output current at the secondary winding from the description given above. ment 536. In order to explain this, it is assumed that on the basis of the preceding assumption, the character wheel has been moved until the Zei tube 500 ionizes and consequently the potential at surface B arrives in the printing position. In this case its anode is lowered just below 85 volts. 35 the potentials on the lines 104 remain and consequently a current flows from the line 104 107 at -90 volts, while the potentials at the lines through the resistors 510 and 509 to the anode of the lines 105 and 106 rise to +213 volts, since now gas pipe 500. As a result, the potential at which the character A in the upper horizontal row of the line 517 remains stored on a memory between +85 and +107 volts, the tubes 501 and the horizontal size are lowered. The potential on line 40 502 is not ionized and the potentials are at their

105 , on the other hand, is -90 volts; but since the gas tube anodes are thus close to +213 volts. This 501 is not ionized, causes the full potential of increase potentials in connection with the potentials 213 volts, which is applied to resistor 505 , a current on lines 105 and 106, the potentials of the lines through resistors 511 and 512 . On these lines 518 and 519 to +213 volts, so in a way the potential of the line 518 goes to a potential which is greater than the potential at the amount between +85 and +107 \ ^r olt ground the rectifier 522 and 523; thus, these are higher. Rectifier locked.

In the same way, the potential on the line The potentials on the lines 104 and 107 are

106 -90Volt; However, since the gas tube 502 is not ionic at -90VoIt, and the potential is sated, the full potential of 213 volts, the 5 <> anodes of the gas tubes 500 and 503 are located at the resistor 506 , increases the potential the voltage below +85 volts, because these tubes are ionized, tapping 519 to between +85 and +107 volts. The line 107 is very low on the lines 517 and 520 , z. B. + 213 volts; but since the gas tube 503 is conductive, + 30VoIt is. This causes a current to flow from the potential at the lower end of resistor 507 to 55 positive terminal 529, which is at +475 volts, over just below +85 volts, and the potential to resistor 530 and rectifier 521 and line 520 becomes is lowered to an amount between +85 and 524 relative to the lower potential Lei- + 107 volts. The potential lines 517 and 520. This current brings the line 533 through the limiter 531, 532 533 to approximately +30 volts. Maintaining the potential of at +85 volts, and since the potentials at the ⁶ ° +213 volts, which including occurs on lines 518 and 519 cathode of the rectifier 521 to 524 increases the potential on the line 599 over more than this amount are , this rectifying the potential of the terminal 538, which ensures ter blocked, and the line 533 is at +85 volts. becomes that line 599 always stays above +107 volts. At this point in time, the lower side of the primary However, the potential of the line 599 through the winding part 5345 through the limiter 543, 544 65 limiter 595, 596 is limited to + 157VoIt. In addition held +71 volts. Thus, the upper end of the sequence rises the potential of the line 599

+ 157VoIt on. The potential of the line 599 has a greater influence on the potential of the line 598 than the negative potential of the current source 540, 70 because of the sizes of the resistors 541 and

109 528/385

of the primary winding part 5345 to +85 volts, and the lower end is at +71 volts, so that a current flows through this winding part and induces a pulse in the secondary winding 536.

110-026

11 12

542; therefore the potential of the cathode potential at the cathode of the rectifier 539 is raised

of rectifier 539 well above J00 volts-ge = - the potential of terminal 544, i.e. at + 71 volts,

lifted. As a result, the potential at "the cathode" flows, starting from the line 533

of rectifier 539 positive and the potential at +85 volts, a current to line 598 at +71 volts,

its anode (ie the potential of line 533, which causes 5 This current every time during the period

+ 30VoIt was) lower than the 'at the Ka- of a given binary signal that the terminal

method. Thus, the rectifier "539" does not conduct and voltage at 544 drops to +71 volts

.If there is no output power at the secondary, a potential is induced in the output winding 536,

winding 536. "Correspondence between one in a gas pipe

First it is assumed that the character C reaches the signal stored ίο and one on one of the lines printing position, while the character A still 104 to 107 occurring signal is stored on two verin the memory. In this case fleeing species enter. If you take z. For example, the gas tubes, as shown in FIG. 4, pulses 404 and 405 tube 500 and the line 104, so the line can always remain in correspondence via the lines 107 and 105 , if the gas tube 500 lines 104 and 106, however to -90 volts. Under these 15 is conductive, so that it is a low anode potential conditions, the gas tube 500 is conductive and is possessed, while at the same time the potential on the thus the potential at its anode under +85 volts line 104 is high. But it can also be lowered while the potential on the line 104 tuning occurs when the potential is on the -9OVoIt. Thus, the potential at the line 104 falls low and the potential at the anode device517 falls below + 85VoIt. The potential at the line of the gas tube due to its deionization is high. In tion 518 rises to approximately + 213 volts, ie in both cases there is a high potential at one potential of the line 105 , and the tube 501 is end of the circuit and a low potential is not ionized. at the other end, so that line 517 that starts with

Since or as soon as the correspondence between the intermediate part of the circuit and the fourth binary signal is linked to both the code 25, there is an intermediate potential. Both the generator and the storage unit are present, if both the potential at the anode of the gas lines 519, 520 tends to stay above +85 volts and the potential at the line 104 remains high. However, since line 517 is at less, the potential on line 517 will be higher than +85 volts, diode 524 will conduct and will be. It follows from this that the potential at the Leitun potential of the line 533 is increased to an amount substantially below 30 compared to 599 and 598 , and the rectifier 539 is reduced above +71 volts. Furthermore, we conduct its cathode blocked and its current flow is prevented by the gene of the high potential on the line 518 of the primary winding part 534U. This rectifier 526, which shows a rise in potential that causes no true match to be present on line 599 to +157 volts; their- was. There may also be a lack of agreement on the other hand, the line 598 will then be at a potential of 35 (coincidence) when both the potential is raised more than +71 volts. Therefore, the potential at the line 104 and the potential at the more positive anode of the gas tube at the cathode of the rectifier 539 is low. In this case, it drops at the anode and therefore the rectifier does not conduct the potential on line 517 to about +30. Thus there is no current flow through the pri-volt, so that the current now flows from the terminal 529 to the secondary winding 5345. It follows that no output power flows to the line 517 at the 40 secondary winding 536 through the resistor 530 and the rectifier 524. This is how it occurs. Potential of the line 533 and + 71 volts are lowered, and from the above description it follows that no current can therefore flow through the rectifier that an output power at the secondary winding 539 and there is no output power. 536 only occurs when the binary code gene 45 Fig. 6 shows the interconnection of the comparator generates a signal which the same binary display with the control and test units. The Auschen embodied like the one that would appear on the first of the comparison unit 109 is fed to the control unit's horizontal row of gas pipes in the storage unit 102 111. The output of the comparison unit 112 is stored. ■ - - ■ wind supplied to the control unit 114. Similarly, the control operation in the comparator 5 °, each of the comparison works 115, etc. combined with the 5 can of FIG as to be written follows loading each associated control unit 116 etc. are connected. When the binary, from the code as both is shown in Fig. 1 as well as in Fig. 6. The signals coming from the generator correspond to the binary signals from the control units 111, 114, 116, 118, 120, 122, 124, signals of the memory, then the 126, 128 and 130 all correspond to each other, including potentials on the lines 517 and 520 so that the description of one of these units is between +85 and +107 volts, and thus sufficient.

The rectifiers 521 and 524 are included. Each of the control units has a test tube 600

locked. This means that line 533 is on +85 and a pressure tube 601, these tubes are Thyra-

VoIt is due to the limiting tron tubes, the essentially positive potentials

device 531, 532. The terminal 544 lies during 60 on both grids for ignition; do you have

according to the short intervals of correspondence (once ignited, they remain ionized as long as

the fact that correspondence is only present while there is sufficient anode potential for them

to keep the positive amplitudes of the impulses of the signals in the ionized state,

the lines 104 to 107 inclusive occur the first grids of these two thyratron tubes

can) to +71 volts. Under these circumstances, over-65 will be passed through the output transformer winding

winds the terminal voltage at 544 which energizes its control 536. The second grid of the test thyratron tube

Action by rectifier 543 on line 600 is given by two of the code generator

exercises, the influence of all other circuits is controlled impulse groups coming. It will be first

(e.g. 540, 541) who strive to control the potential through the "ignition pulse" FC , which (as in

tial of line 598 to change. Thus, the 70 (Fig. 4 shown) is shortly after the start of the pressure cycle

1 IUl
13 14

the device occurs. At a later point in time is complementarily assigned, has ignited, the pressure circuit will charge this second grid controlled by the capacitor via the assigned solenoid entailing a plurality of "test (a) pulses". In the case of the first perpendicular to print as shown in FIG. The second grid of the printing column is the capacitor 607 via the thyratron tube 601 is discharged via a capacitor 602 5 solenoid 603 (equal to 308 of FIG Code- Druckthyratron 601 becomes conductive. This controls the generator, which occurs accordingly, as shown in Fig. 4 armature 307 (Fig. 3) attracted and moves the pressure. This second grid is also hammer 303 in the stop position against the paper, through the cathode potential of the Prüthyratronröhre Assuming that the upper horizontal row

600 controlled. The output flow of the pressure thyratron- io from gas tubes in the memory contains the letter A, the tube energizes the solenoid 603, which in turn attracts the control action of the pressure hammer 604 used in this way . This provides the means for printing this character, which effects printing in the first vertical column with particular reference to Figs. The solenoid 603 bears the reference number is:
308 in FIGS. 3, 7 and 8. 15 As already explained, the capacitors 607,

It is of interest here to explain how the 608 , etc. has been charged while the character wheel has power to control the solenoids, e.g. B. at 60S, approaches the zero angle shown in FIG. What is made available without arriving at the next step is to overload the memory test power supply line. The pulse PM is generated by the code generator, mains alternating current is fed to a rectifier, 20 which has two consequences: First, it controls the thyratron 620 which generates an output voltage of approximately 650 volts in order to switch off the thyratron 609 , and this charges a capacitor 606 on. and further charging the capacitor 607. This capacitor can be quite large; prevent in case; second, it is simultaneously examining the memory of a machine with 130 vertical columns such as 102. This latter process is best mentioned at the outset, the capacitance of this 25 would be illustrated by Figure 5, which shows that the capacitor is approximately 2000 microfarads. Memory test pulse PM enters the line at The same capacitor size could also be used then by resistor 597, the rectifier, if the number of vertical columns 570 and finally by the primary winding part were less. Because this capacitor will flow at 534 ^ 4 of transformer 535 at all times. The potential of the direct current source 605 is, it is charged during a 30 tial of the storage test line PM is normaganzen pressure circuit. However, it is currently at a base value of +33 volts, and we see that the pressure capacitors 607, 608 etc. are only supplied with current during the entire pressure cycle, with a limited time, such as a short time in an early stage of the following is explained. Pressure circuit, in which the potential to +85

The memory erase pulse CM goes through a brief 35 volt rise (see Fig. 4). If it is at +33 delay line 671 to a thyratron 609 and volts, practically no current flows through the primary power of this conductive. The charge stored in the capacitor 606 winding part 534 A, since the middle tap 533, can now never fall far below this potential through resistors 610. 611 etc., rectifiers 612, 613 etc. to the pressure when all four gas tubes 500 to 503rd in the time capacitors 607, 608 flow. These capacitors 40 are point deionized, in which case the memory test will have a capacitance of approximately 1 microfarad. pulse PM arrives at resistor 597 , after these capacitors have been sufficiently charged the secondary winding 536 no potential has been induced, the thyratron 609 is switched off. The reason for this is that when all four take place as follows: Gas tubes 500 to 503 are deionized, their anode

The PM pulse 45 potential coming from the code generator 103 is all high and consequently the line ignites a thyratron 620 and thereby lowers the 533 to its limit value of + 85VoIt. Since this potential at its anode is practically ground potential. Since this anode is connected to the memory test pulse PM ₁ via a capacitor 621 , no current flows through the anode of the thyratron 609 and there is a resistor 597, the rectifier 570 and the inductance 622 with the anode of the latter 5 ° primary winding part 534 A. Likewise, the thyratron is in series, the sudden at this point brings the terminal 544 to +103 volts potential drop at the anode of the thyratron 620 (see Fig. 4). Therefore, the cathode of the direct-lowering potential of the anode of the thyratron converter 539 has a higher potential than its anode and 609 with it and keeps this for a sufficiently long time no current flows through the primary winding part at a potential that is low enough to 55 5345.

to clear this thyratron. The Thyratron 620 , however, if any of the four gas tubes 500 to

by the counter- 503 occurring at the inductance 622 at the point in time. the arrival of the memory test voltage cleared. After restoration of the pulse PM is ionized, there is an output potential induced in the normal anode potential at the thyratron 609 of this secondary winding 53.6 , cannot be made conductive again until a new 60 For illustration it is assumed that the gas CM pulse is with it arrives. Thus, once the pressure tube 500 has started to cycle at the time of the arrival of a pulse and the capacitors PM is ionized. Correspondingly, if their anode 607, 608 etc. have been charged, they can be at low potential. The lines are not charged again 104 to 107 until a CM including located in the arrival time of the pulse from the code generator forth at the end of the pressure 65 of the PM-pulse all -90 'volts (s. Fig. 4 ). circuit matters. In other words: the con The low potential at the anode of the gas pipes

Sators 607, 608 etc. can only be charged once during 500 brings in cooperation with the negative of each pressure circuit. If during the potential of the line 104, the line 517 at a rend of such a pressure circuit, the thyratron, value in the vicinity of +33 volts, as explained earlier, the capacitor 607 or 608, if applicable, was 70. Since the memory test pulse is at +85 volts

15 16

The beginning of the pressure cycle rises, it is therefore, trons 601. During the course of this shock wave ¹ when it is at +85 volts, a current flow appears through which, starting from the code generator, a resistor 597, the rectifier 570, the primary Another impulse on the line "pressure (a) ", which is also called winding part 534 ^ 4, the line 533 and the equal- with 630 , and flows through the condenser

. Direct 524 to line 617 , which on +30 5 sator 602 to the second grid of the thyratron 601.

Volt lies. Thus there is a current through the Thus the thyratron now has all three potentials, Primary winding part 534 ^ 4, which has a potential in which the necessary to ignite it, namely one of

Output winding 536 induced. the secondary winding 536 coming potential

Since the memory test pulse PM with all its first grid, also an associated pre- equalization units 109, 112, 115, 117 . .. 131 connected io voltage on its second grid, which results from the fact that an output voltage occurs from, that the thyratron 600 is conductive and thus that this comparison works is increased according to the series potential of its cathode, and a third, from Gas tubes are present where one or more tubes resulting from the pulse on line 630 are ionized. On the other hand there is no potential. As a result, the thyratron 601 will ignite and output voltage on the secondary sides of those 15 will cause one of the capacitor 607 generated by the comparator in which none of the gas solenoid 603 and thyratron 601 tubes flowing to earth have been ionized. Current. As a result, the print hammer 604 is counteracted

When studying the device, it should be noted that the paper moves and prints the letter A. The memory test pulse generates an output voltage during the remainder of the period of one revolution, hereinafter referred to as the shock wave proceeds from the secondary winding 536. This 601 is assigned, no other sign printed "shock wave" or overvoltage sets itself up for a be. If another sign were printed, it would indicate a significant period of time in which it would appear in the circuits above the letter A, existing inductance and capacitance continue, and before and this is not permitted. Other characters can this Stroßwelle occurs, starting from the 25 during the remainder of rotation of the type wheel code generator Zündprüfimpuls FC termination (s. Fig. 4) will not be printed, because the capacitor 607 entauf formed by the rectifier 623, line 670 , has been charged and cannot be charged again. Capacitor 625 to the second grid of the thyratron can flow until the end of the pressure circuit reaches 600 . The aforementioned of the secondary winding is where the pulse CM ignites the thyratron 609. 536 outgoing shock wave is the first grid 30 of the thyratron If ignites 601, the thyratron 600 approaches supplied. Thus, the two potentials of its anode, the earth potential with the grid of this thyratron, are excited simultaneously, and it is successful that the potential of the anode of the thyratron now flows current from the current source 625 through the 600 also with respect to its cathode potential resistor 626 to the anode of the thyratron 600, then through the capacitor 631 is brought far into the negative through the cathode resistors 627, rectifier 35, so that the thyratron 600 deionized 694, voltage source 695 to earth. The thyratron will. At the end of the printing process, the capacitor 600 is now conductive and remains in this state, the capacitor 607 is essentially discharged, and therefore the tube 601 is also extinguished until its anode potential is reduced by an amount,
sufficient to erase the tube. Before assuming that the second horizontal row, the thyratron 600, was ionized, no current flowed 4 ° from the tubes of the memory 102, the letter E, through the resistor 627 and the second grid was held, it is printed as follows: As in the case of the thyratron 601 practically at the voltage of the letter A, the code generator generates the source (-100 volts) and could therefore not be ignited at the beginning of the pressure circuit, the memory test pulse. Now, however, after the test tube 600 overall PM, which -is, in turn, been a shock wave in all Primärzündet, the potential of the second winding portions 45, z. B. 534: A, the comparative works her grid of the thyratron 601 increases considerably and thus calls out that with. the ionized tubes of the type the pressure thyratron 601 are connected for ignition for the case 5823. It therefore generates such a preparedness that two phenomena occur at the same time - shock wave also occur in the corresponding primary winding; Firstly, that its first grid is one of the comparison unit 112 with the result that an appropriate excitation is supplied, and secondly, 5 ° output voltage from the secondary winding 546 that its second grid emits a further excitation via comparison unit 112 . This output surge the capacitor 602 receives. In other words: the wave superimposes the ignition test pulse FC, which comes from the mere increase in potential of the second grid of the code generator, and thus the test thyratron 601, which is ionized from the ignition of the thyra thyratron 640 , since it is already the Ignition test trons 600 results, alone is sufficient to ignite the Thyra 55 received pulse, which by rectifier 641 and trons 601 is not sufficient even if its first capacitor 642 has been appropriately energized to the second grid of this Thyra grid. trons goes, and now also those from the secondary

The next event in the course of the process treatment 546 that the shock wave reaches its first grid is that the type wheel maintains the printing position. Thus, the approach for the character A through resistor 644 increases. If this position is reached 60 flowing current, and consequently the pre or approximately reached, then binary signals 400 voltage on the second grid of the printing thyratron 645 and 401 (see Fig. 4) to the comparison device, and reduced. What happens further in relation to printing is assumed that the character A in the top of this character is temporarily nothing until the type wheel is stored in the horizontal row of the memory, so that the character E results in a additional shock wave, which approaches or arrives at the pressure position as before. Step upright described is generated. If this shock wave occurs in this case, the code generated by the code generator by a current flow in the primary winding part 103 becomes the code generated in the second horizontal 534 B. This additional shock wave appears in the right-hand row of the memory characters secondary winding 536 and energized the first grid coincide, and in this case both the test tube O00 and the pressure thyra 70 coincidence pulse arises in the secondary winding 546;

17 18

this impulse excites the first grid of the pressure thyra waves in those transformer secondary wicktrons. Since this comparison pulse has a considerable duration, which corresponds to the comparison series, it is superimposed on the "pressure (b) pulse", which contains binary signals other than 0000, occurs on line 646 and ignites these shock waves via the condensate the thyratron tubes corresponding to those rows of the sator 647 to the second grid of the thyratron 645 ge 5 memory, which reaches. As a result, the thyratron 645 is ignited, it contains binary signals other than 0000. As far as those control units 111, 114, 116 etc. are concerned, since all three potentials are on its grids, which are necessary for the ignition. It then flows in the respect of the printing operation to thereby flow from the capacitor 608 by the pressing solenoid due to the fact that in the associated memory 687 and there is nothing stored by the thyratron 645. io, are at rest, so the loading

It should be noted that the pressure pulses (a) and striking test tube do not ionize. If z. B. the (b) are offset against each other in the same way first word to be printed is AB and then a like the characters on the type wheel. This means that the space and then the word CD follows, if the pressure (&) - pulses are generated temporally in relation to the memory ^{test pulse / 5} M shock waves pressure (a) pulses are delayed in such a way that they are the 15th in the secondary windings 536, 546, 548 and 549, allowing print wheel, is becoming deer to the angular path to but not 547 in the secondary winding Thus, lying between the character strings (which excites in the Prüfröhren 600 and 640, the Prüfröhder representation according to FIG 4 but not a path of 30 ° Ren 650. Furthermore, the test tubes in would) before the printing process takes place. levels 118 and 120 excited. Since the test tube 650

For the second explanation of the fact that in the previous sentence Ge 20 is not excited by the memory test pulse PM , it is assumed that in each of the ten scales in the third vertical column a printable row of the memory cannot take place, even if in something is stored in one. When the type wheel comes up to a later period of the printing circuit, a noise and the letter D is ready to be printed, or a hum would occur, which all ten comparison units of the 25 thyratron tubes 650 and 651 generate on the grid, equals device 108 an output shock wave, which as soon as the letter A is in the first vertical

occurs on the grids of all ten pressure thyratrons. Column has been printed. the test tube will be 600. However, the thyratron tubes of the first, third, will go out. As soon as the letter B has been printed in the second, fifth, seventh and ninth vertical columns, the test tube 640 is ignited first, since they are all connected to the line 630 and extinguish. In the same way are bound are. After this thyratron has been ignited - after the letters C and D have been printed in the tube, the type wheel rotates a further 30 ° through the fifth and sixth vertical columns of the Prüfröh - (if one applies the ratios shown in FIG. 4 for these columns So in the end, reasons have to be laid) before a pressure pulse on the line of the pressure circuit all test tubes go out because 646 occurs. The shock waves coming from the secondary windings of 35 where a printing process takes place, the test tube comparison device or are initially switched on, but then later overvoltages will be deleted again at this point in time, and because where there is no printing process there will be a separate one For every comparison that takes place, the test tube is not at all included in the series of types of the type wheel.

as shown in Fig. 4; 40 If any test tube remains at the end of a store the signal running on line 646 , pressure circuit ignited, it may be that a and then the letter D has occurred by means of the secondary error. The "all-off" detector 652 winds for the second, fourth, sixth, eighth and is designed to determine whether all of the test tubes have printed the tenth vertical column. are deleted at the end of a pressure cycle. Is by

In this connection it should be noted that the 45 end of a pressure circuit any of the test earliest of the two pulses 400 and the first of the two ren still ignited, so a current flows through its pulse 401 each a shock wave in the secondary cathode resistor. This resistance current caused by the cathode winding (e.g. 536) of the comparator works continues until the next one arrives at the gate 629 via the memory erase pulse CM, the pressure and test pulses 480 or 481. The second of the two pulses 400 and 50 If a current flows through a cathode resistor to the second of the two pulses 401 superimposed on the pressure and test pulses 482 and 483 CM, the same with the occurrence of a memory erase pulse, the gate 629 opens and allows a current

The operation of the test thyratron will flow to the solenoid 653 of the relay, which will be described in detail below. The memory test device is switched off and an error signal 656 pulse PM excites the primary winding part (e.g. 55 is switched. The operation of the gate 629 and 534 ^ i) only when any tube of the horizontal its associated parts is shown below in the individual right-hand row of the memory, which explains a comparison.

werk (e.g. 109) , comes into operation. If there is no ionization of one of the gas tubes 601

z. B. certain horizontal rows are present, etc., so that through the cathode resistors 627 , etc., in which no binary signal is stored, no current flows 60, so the line 696 is no current through the primary winding part of the Trans- - 102VoIt held, namely by the negative formator of the complementary comparison mechanism and current source 693, which has a potential of -300VoIt, so there is no output current from the comparison mechanism in interaction with the resistor 692 mechanism. In other words, output currents arise, and the limiting device 690, 691. The source caused by the relevant memory test pulse, 65 690 is at -102 volts. If one of the pressure tubes, starting from the transformer secondary winding. B. 601, after the end of the pressure circuit results in 536, 546, 547, 548, 549 etc., only if remains excited, a current continues to flow through their comformation in the complementary horizontal row complementary cathode resistance, z. B. 627. This is stored in memory. On the other hand, current also flows via line 696 and that prompted by the memory test pulse PM, surge 70 resistor 692 to negative source 693 and effected

19 20

hence an increase in the potential of the line 696 other shock wave at the output of the secondary winding from the lower limit value of -102 volts, development 536 , which, in cooperation with that determined by the source 690 , will appear on the pulse on the line 670 of the test tube 600 an upper limit value of -100 volts that would switch through; this test tube would be switched on, the limitation device 604-695 is given. They stay 5 and operate the "all-out" detector, this voltage difference of 2 volts, which is at the input A further function of the test tube is

When the gate occurs, a going to the gate provides an indication that a Gedes signal is sufficient to open the gate when there is a noise signal on one of the channels and the arrival of the next memory erase pulse CM leads to no printing takes place. It -be z. B. assumed. In other words, the gate will be if it is agreed that the letters A and B are to be printed in the first two vertical columns of the input potential at the left input of the gate, but the third is - - 100 volts (and not - 102VoIt ) nothing can be printed in the th vertical column. At the time the memory clear pulse arrives , the test tube 650 through the memory CM will open and a current to the solenoid 653 of the test pulse PM will normally not be energized. It keeps relay flowing. As a result, an armature 654 is de-energized towards 15 until the disturbing noise signal occurs, a permanent magnet 655 is drawn and the connection to one of the circuits customary up to now could be achieved

ker locked in the lower position. In such a disruptive noise signal, it remains the pressure-locked state until it is released by hand. thyratron excite, and in this way a locked position is the armature is printed in its lower or ge characters in the third vertical column, then current flows from the power line 20. This is according to the invention by the test thyratron through the error light 656 and shows at that in the certainly prevented. The potential at the second device an error has occurred. The Netzzuleit- grid of the Druckthyratron 651 is not sufficient to lines X and Y, which lead to the rectifier 605, cause a printing process, as long as they are not also de-energized, so that a further test thyratron 650 is energized first; but the more verified printing cannot take place. 25 thyratron 650 cannot be used before the pressure thyratron 651

There are two ways in which the case can be excited when the pressure circuit can occur beyond the point where a test thyratron has advanced at the end of a point at which the pressure circuit remains ignited. If you take the ignition test pulse FC occurs (see Fig. 4). This follows from the previous state, in which A and B in the fact that the trigger pulses are printed on the second first and second vertical columns, respectively, the grid of the printing thyratron tubes at the same time as the opening and in the third column is not printed, trigger pulse on the second grids of the test thyratron and it is further assumed that the device in tubes as shown in Fig. 4 precedes, operates normally and the letter A is thus the only operation that the sound is printed, but that afterwards on the printing pulse on its arrival can cause the letter A to produce an unintended noise 35 a potential on the grid of the call thyratron 650 or a hum signal in the secondary winding 536 ; If this potential persists until a from occurs, the device will work as follows: Code generator generated signal on the line 670. This noise pulse cannot appear, the test tube 650 will ignite and excite directly without previously the test thyratron 600 to remain ignited at the end of the pressure cycle. In ignite because the test thyratron are switched on 40 at this point in time it will energize the gate 629 , which must before the second grid of the pressure thyratron in turn pulls the relay 653 , which has a sufficient bias voltage for ignition. The device switches off and the error signal The noise signal cannot cause the test thyratron 656 to light up. In order to ensure that rain, until another pulse by the code generation goal 629 rator by the fault light or error signal of is +5 energized together with the memory clear signal over line 670 to the second grid, the thyratron is transferred 600th If such a device arrives before the memory clear signal to the thyratron 609 via the line 670 , it ignites, together with ignites again, a very short delay noise, the test thyratron 600 again, device 671 in series with the grid of the thyratron 609 but the pressure thyratron can 601 do not switch on, be switched on.

because it has already ignited and its assigned 50 capacitor 607 has been discharged as an additional function of the test tube. This condensate, in the case of delivering a display and the Gesator can not be recharged until the complete device switch off, that a Ci ¥ pulse that is not next to pressure arrives at the thyratron 609 , so capable binary signal stored in the memory that the pressure thyratron 601 remains switched off, and is. If z. B. switched on in the first horizontal row of the Prüfthyratron 600 . Therefore, the binary signal Olli is stored in the memory 102. Its end of the pressure circuit should the test thyratron 600 turn on, then some error is evidently connected and causes a current to flow that makes it, since there is no similar binary through which "AlIes -off "detector 652 controls and the device code generator 103 is generated signal. When one switches off. such a non-printable signal in the memory

^{The working 6} ° of the arrival of a Pilf pulse as described in the previous paragraph appears, so it will be wise that this pulse would also be essentially the same if this pulse had an output voltage at the second case that a character would be printed which in the winding 536 and thereby the test wheel is arranged in such a way that it only ionizes against tube 600. Since the code generator 103 never ends the pressure circuit in the pressure position mais. can generate binary signal that comes with the. If z. B. to print the letter E would be ⁶ 5 sem stored in the memory the same or similar and the noise pulse is borrowed at an early point in time, then the coincidence circuit 109 would never occur one of the printing circuit would show the correspondence, and accordingly will the noise pulse causes another book printing tube 601 to never energize. It follows that rods, e.g. B. A, B or C, is printed, and if the test tube 600 is not deionized either and the type wheel reaches the letter E, a 7 <> would therefore reflect so long a current through its cathodes.

21 22

level 627 flows until a CM pulse arrives; The gate 629 switches to the capacitors 608 and so on for a short time thereafter, remaining charged for the entire setup period. During this time, the error signal 656 could turn on. If the capacitors 608 etc. have such a high return

In other words, if the capacitors 607 apply voltage to the rectifier 613 etc., that 608 etc. are charged by the capacitor 606 and these are a leakage current into the capacitor 607 , the flowing current lowers the potential to send it would be charged so far, the anode of the tube 609 suddenly turns off and lowers that it prepares the pressure thyratron for a further ignition at the same time as the potential at the control grid of the process. It is unlikely that this will erase tube 672. At the end of this situation, any leakage current from the io processing of this possibility becomes the complete switch-off-charging period, but the tube 672 in front of capacitors 607, 608 , etc., which can be seen by the same that during the pressure circuit judges 612, 613 etc. flows, via the tube 672, from a low resistance conduction path from the Samda through its cathode resistance and to the cathode line 673 to earth. During the source of -150VoIt is conducted. The current flowing through the conduction period of the capacitor 607, 608 , etc., increases the cathode resistance, the grid of the tube 672 is blocked so that there is no denpotential in the positive direction above -150 ¹ volts, shunting to the charged capacitors, but is not strong enough to prevent the bias. Fig. 3 shows schematically the cooperation of

from + 75A ⁷ OIt to make ineffective on the type wheel and print hammer. The type wheel 100 is located on the control grid. This bias, provided with respect to a ribbon 301 , which is the same positive on the cathode potential, ensures that it can have the width of the character wheel and, on the type, that the tube dissipates any leakage current that passes by the wheel at a suitable speed; that the capacitors 607, 608 etc. through their associated paper 302 is also flowed to the character wheel 100 with gerigen rectifiers 612, 613, etc. The group of suitable speed moves past and preferred line 673 is thereby essentially held at ground level by one or two spaces or line spaces. 25 advanced after each line is printed. That

FIG. 10 shows the control process in the means paper can be advanced by means of devices known per se for erasing the memory according to FIG. 1. The purpose. The hammer 303 is from this device according to Fig. 1 for erasing the character wheel 100 by a preloaded spring 306 memory is normally a potential pulled away. A spring 321 pulls the armature 307 from +213 volts on the anode resistors of the tubes 30 to a stop 304. In response to the erreren of the memory. However, immediately after the solenoid 308 , the armature 307 bar must be moved forward quickly before the reservoir is refilled, until it deionises all gas tubes against a stop, so that they come into contact with each other in 305 . This is during this movement, the ungeeinem state in which it can optionally be re-mm ferry 1,27, the moment can be achieved beionisiert, namely in accordance with the 35 accelerated the hammer 303 to be introduced to such high Geschwinneuen in the memory information. In order to achieve this, a current source 1000, which has a potential of +213 volts at 0.77 mm of its orbit above the contact point, is moved out at a cone with the armature 307 and push-pull element 1001 against the usually an armature strikes the paper 302, he this under bias against the check in 1002 by a spring 1003 40 301 presses ribbon and the latter is situated opposite the type of the. Under normal conditions, this circuit keeps the print wheel 100 pressed. The spring 306 guides the hammer gene, the upper ends of the anode 504 resistors 303 mer at once from the contact position with a voltage, etc. to +213 volts. During a return to the paper. This arrangement ensures, at the end of each Druckkreis- that the hammer only once abuts short period of time the paper run excite the memory erase pulse CM a 45 and prevents minor collisions between the solenoid 1004, and moves the armature 1002 for hammer and the paper, which to Smearings to the mating contact 1005, which could lead to a suitable or smear of the type print. Resistance with a power source of +55 volts. The hammer strikes against the type wheel that is roughly tied. Preferably, the contacts 1001 and 1 millisecond after the point in time at which the 1005 is arranged so that the armature touches one of these 50 trigger signals supplied to that pressure thyratron before it leaves the other. which was specifically considered

The working solenoid is controlled throughout the pressure cycle. The potential supplied to the hammer and memory is therefore +213 volts. It takes about 8 milliseconds for the armature to return to its rest position, when the pressure cycle is complete, tial to +55 volts and remain at this level it is sufficient to secure a large number of anchors 307, springs 306 and to ensure that all gas tubes are deionized; and print hammers 303. The print hammers 303 are then fed back the potential to +213 volts through members 700 and 701 . The guide is brought so that the memory is ready for the replenishment 701 of the hammers are made of polyamide (nylon). 60 and are placed in their guide slots through

The operation of the tube 672 is held below projections 702 which explains a piece with a. If this tube were not present, form steel support member 703 . As Fig. 9 and 11 show, there is the possibility that under certain circumstances this is the character wheel composed of a series of disks for charging the capacitors 607, 608 , etc., each of which has one or more large reverse voltages on the selenium cells. Rectifier carries 65 type columns. If the individual disks tern 612, 613 , etc. would produce that they would only be pushed onto a shaft, other capacitors would possibly have to be charged, a thickness tolerance on the order of a clothing has already been discharged. Is z. B. the fraction of a centimeter must be adhered to, the letter A is printed first, so that the capacitor is immediately discharged to the correct 607 for the total length accuracy.

number of vertical columns is to be printed and this requires a large number of disks on one and the same type wheel. As previously mentioned, a total of 130 type columns are used in one embodiment of the invention, and this requires 130 disks. Instead of stacking the disks on the shaft 901 , this has a multiplicity of grooves 902 which are arranged at a precisely defined distance from one another and in each of which there is a spring washer. When assembling the type wheel, a spring washer is inserted into the first groove. The first washer is then placed against this first spring washer, followed by a resilient intermediate ring 903 and then a second washer 904. This aligns the surface of the previously placed second washer so that the second spring washer can be accommodated. The third disk 905 is now placed on, and it is followed by a further resilient intermediate ring 906 and then a fourth disk 907, which is followed by a further spring ring 908 . This process is repeated until the character wheel shaft is fully occupied. In FIG. 9, one of the hammers 900 is shown in the printing position, that is to say in the position which it assumes after it has been struck by its associated anchor. The resilient intermediate rings hold the washers in firm contact with their associated spring washers and thus ensure precise adjustment of the washers.

Various modifications can be made within the scope of the concept of the invention in the design and manner of the control. For example, the memory can be of any known type, e.g. B. also be magnetic. Moreover, it is not necessary that the information stored in the memory be printed on the paper in a single horizontal line. There may also be a device controlled by a plug field, which is arranged between the comparison device 108 and the control units 111, 114 and 116 etc., so that the operator can either, if desired, either all of the information stored in the memory at once in a single print horizontal line or place in several shorter horizontal lines, one above the other. In addition to these changes in the interconnection of the parts, as suggested above, the individual components of the system can be changed within wide limits without departing from the scope of the inventive concept.

Claims (5)

Patent claims: 1. High-speed automatic printing machine for converting information received as electrical signals into printing types with a uniformly rotating type roller, which is equipped with a set of all printable types for each printing position along a printing cell and with a print hammer arranged in each printing position of the printing cell , which can be actuated by the common control of pressure control circuits and signals derived from a memory receiving the information signals, according to patent 1081701, characterized in that each pressure control circuit, in addition to a thyratron (601) for controlling the solenoid (603) actuating the print hammer, has a test contains thyratron (600) , which is ignited by a pulse from the assigned comparator (109) , provided that the relevant storage department (500 to 503) contains information that indicates that the assigned print hammer must be actuated in the printing phase and that the push thyratron ( 601) is prepared by igniting the test thyratron (600) so that it can be ignited by a signal from the associated comparison unit as soon as the information stored in the relevant memory department corresponds to the printing type of the type roller that is currently entering the operating area of the printing hammer. 2. Printing machine according to claim 1, characterized in that the time of ignition of the Prüfthyratron (600) and the Druckthyratron (601) by a code generator (103 in Fig. 4) generated Absthnmimpulse (Fig. 4) depends. 3. Printing machine according to claim 1, characterized in that the type roller (100) carries several type rings corresponding to the number of printing positions, which contain the same plurality of types and of which type rings arranged next to one another are offset from one another by half the angular distance between two types, so that the same types are arranged in two adjacent axially parallel rows. 4. Printing machine according to claim 1, characterized in that each print hammer actuation circuit Devices for delaying the actuation of the print hammer adjacent to each other Contains type wreaths to indicate the time intervals between the arrival of the staggered ones Balance types of adjacent wreaths. 5. Printing machine according to claim 1, characterized in that each print hammer actuation circuit contains a capacitor (607, 608) and that all actuation circuits are guided via a common gate (609) , which the capacitors by applying DC voltage immediately before switching on the ignition of the printing thyratron to charge and with the start of the ignition of the pressure thyratron is able to prevent a further charge. Considered publications:
"Review of Input and Output Equipment used in Computing Systems", New York 1953 pp. 59, 61, 76, in particular pp. 95 to 97; "Transactions of the I. R. E., PGRTRC-2", November 1954, pp. 2 to 7. For this purpose 2 sheets of drawings © 109 528/385 2.61