DE843322C - Procedure for the electrical filling of conductive markings - Google Patents

Description

In addition to punched cards, other registration documents are also used in the technology of business machines used in which the individual operations by strokes with conductive ink or Graphite are set. The evaluation of such recordings usually takes place in that the conductive marker closes a circuit passing through a pair of sensing brushes.

The material of the recording medium is generally paper, which under normal conditions has a low negligible conductivity. It is well known that when the humidity is higher Paper absorbs moisture and reduces its electrical resistance. This creates between the sensing brushes over the carrier material unwanted leakage currents, which an exact Question the evaluation of the records.

In the worst case, the paper resistance drops under the influence of air humidity Values that are in the order of magnitude of the resistance of the conductive markings. this has As a result, the evaluation organs of the sensing circles also in the places free of conductive records speak to.

The invention now avoids the disadvantages described in that the sensitivity of the sensing corresponds to the conductivity of the recording medium is changed. So if the conductivity of the recording medium increases, then becomes the sensitivity of the sensing, i.e. H. of the circuit causing the evaluation, accordingly degraded. A tube circuit is advantageously used to carry out this process, as an exemplary embodiment based on the illustration

application is described in more detail. Advantageous developments of the invention emerge from this description emerged.

On the carrier S, which is, for example, in the form of a band or sheet, electrically conductive markings D are applied in columns and lines or in any other arrangement according to a special key. The conductive records D are sensed by the brushes BE and BC. Let the recording sheet move from bottom to top in the direction of the arrow. Two brushes BE and a middle brush BC each represent a brush group for sensing one character column. There are therefore as many brush groups as there are columns to be sensed. The outer brushes BE of all groups are on a line 10 which is connected to point 1 of a resistor R. This resistor R is connected to the positive pole of an 11 o volt direct current source. The connections of the middle brushes BC are each designated by 11. Each brush BC to be put into operation is connected by means of a line 12 to a connection 13 which, via resistors R ₁ and 7? _{4 is connected} to the negative pole of a 40 volt power source. So there are just as many brushes BC with the connections 11 and 13 as there are marking gaps on the carrier. The control grid G of an amplifier tube A is located at the junction of the resistors R ₁ and R _i . A connection leads from the anode of this tube to the magnet M and further via switching elements (not shown) to the positive side of the 110-volt power source. Different tubes A and magnets M are provided corresponding to the different brushes BC and the respective sensing gaps.

When the recording sheet moves in the direction of the arrow, the individual markings pass line by line one after the other under the sensing brushes. As soon as a conductive marking is opposite a group of brushes, a sensing circuit is closed by the brushes BE and BC of the group in question. The current then runs from the positive pole of the 110 volt power source via the resistor R, point 1, line 10, over both outer brushes BE of the respective sensing group, then in parallel through the conductive recording to the central brush BC, from there over, 12, 13 and over the resistors R ₁ and R _t to the minus side of the 40 volt power source. This current raises the potential of the grid C of the tube A concerned, so that its negative grid bias voltage drops, current flows through the tube and the magnet M located in the anode circuit is excited, which in turn records the presence of a recording by a switching process.

IXt current flow in the sensing circuit now depends on the voltage prevailing at the brushes and on the resistance between the outer and inner brushes. The resistance values of the .Vbfühlkreises are to be chosen so that, for a given normal voltage on the line 10, the sense circuit always influences the grid of the tube A in the sense described if the resistance between the brushes when a conductive recording is being sensed is not greater than one certain normal value. The resistance of the carrier material free of recordings between the brushes BE and BC of a group must therefore be greater than the resistance of a conductive line so that the circuit running over the magnet M cannot be closed when the unmarked points are sensed. This is also the case under normal circumstances.

However, if the conductivity of the carrier material increases as a result of moisture or for some other reason and the resistance at unwritten areas of the carrier falls to a value that is equal to or less than the normal resistance of a conductive marking, then a circuit is closed when sensing and the magnet M is energized even when there is no conductive record under the brushes.

The invention avoids this difficulty in that in such a case the potential of the line 10 or the external brushes BE of the brush group in question is reduced. This is because the potential on the brushes BE is one of the two factors that are important for the creation of the sensing circuit; the other factor is the resistance between BE and BC of a brush group. If the resistance of the unwritten carrier material changes for any reason, then, according to the invention, the potential applied to the brushes BE is changed in proportion to the decrease in the insulation resistance of the carrier material. For this purpose, the insulation resistance of the carrier material is continuously sensed by a special set of brushes not intended for scanning markings. If the resistance at an undescribed marking point then has the same or even a lower value than the standard resistance of a conductive marking, the creation of a sensing circuit must be prevented there by reducing the potential applied to the brushes BE. The reduction in the potential of the line io is proportional to the decrease in the insulation resistance. This measure does not prevent a conductive recording from being sensed because its resistance always remains lower than the insulation resistance; because the reduction in the insulation resistance of the carrier material also results in a corresponding reduction in the overall resistance of the conductive marking.

If E _{1 means} the potential of the line 10 and the outer brushes, E ₂ the potential of the connections ι ij ie the middle brushes, and R _x the resistance between these brushes of a group, then E ₂ = E ₁ - J · R _x .

With a constant Ii ₁ and with a low insulation resistance, the potential E ₂ rises to a value at which the tube A becomes conductive. But it is

Potential Ji ₁ variable and if this is also allowed to decrease with the assumption of the insulation resistance of the unl) cschriel> eneii carrier material, then Ii ₀ will also decrease and reach a value, once the tube A is blocked and thus the working magnet. 1 / remains ineffective. In this way, the responsiveness of the sensing device becomes smaller. The resistance of a marking is, however, l> a reduction in the

ίο Insulation resistance of the carrier material also lower; the decrease in R _x is then approximately proportional to the decrease in the potential /: ,, so that E ₀ IxHm sensing a conductive mark is essentially constant and has the value at which the tube becomes conductive. Thus, while the sensitivity of the sensing circuit to unrecorded material is reduced under the conditions described, the voltage of the sensing brushes remains constant as far as the conductive markings are concerned. The working magnet will therefore always be excited when a label is sensed, regardless of the change in the conductivity of the carrier material. On the other hand, if there is no marking under the sensing brushes, the potential /:., On line 11 and thereby the control grid potential of tube A is sufficiently reduced so that tube A becomes non-conductive despite the increase in the conductivity of the carrier material and magnet M does not respond.

The reduction in the control grid potential of tube A is now controlled by a group of brushes that only sense the insulating material and is not used for the actual evaluation of the conductive markings. When the conductivity of the carrier material is increased, this group of brushes generates a higher control grid potential, thereby increasing the current flow in its anode-cathode circuit and reducing the potential at point 1 and thus also that of line 10. This potential reduction prevents a potential from passing through the sensing circuit to the control grid of the tube ./ which, for example, makes this tube A conductive.

In order to change the potential on line 10, as already mentioned, any brush group | X'ii IiIi and IiC that is not used for evaluation is expediently used. The middle brush HC of the selected group is connected via its connection 1 by means of connection 14 to a connection 15. At this point 15, the grid G ₁ of tube C, which corresponds to tube A in its mode of operation, lies above resistor R _0.

The grid (/ ', is normally biased negative with respect to the cathode to about 45 volts with the aid of a 22Va-volt battery B. The positive pole of this battery is connected to the cathode resistor R ₅ via the filament of R (its C. / U ₅ has a value of about 50 ohms. The grid blocking voltage lxH only carries about 24 volts, so that if the grid voltage of approximately 45 volts, tube C remains blocked, j This state remains until the brushes resist the substrate is sensed, which is no greater than the normal resistance

was a conductive mark ¹ . If the material does not offer a greater resistance to the current than the normal resistance of a conductive marking with a reduced insulation resistance ₍ then a current flow from the plus side of the 110-volt power source is established via the resistor R, terminal 1, line 10, brushes BE, carrier material , central brush RC of the respective brush assembly, terminal 11, lead 14, terminal 15, resistors ^, R ₃ to the minus side of the Gittervorspannungsbatterie B in. the electrical circuit is closed ül> er the battery B and the 40-volt power source to the minus side of the 110 -Volt current source. This increases the potential of the grid G ₁ and conducts the tube C. The anode of this tube C is connected to point 1 behind the resistor R. Therefore, the tube draws current from point 1 when it becomes conductive of resistor R. As a result of the increase in the current flow through resistor R , the voltage drop across resistor R also increases and the potential at point 1 decreases the potential of the line 10 is also lower, and thus the sensitivity of the circuit sensing the marking falls, so that the sensing circuit between the brushes BE and BC is no longer closed solely by the carrier material. It is true that a reduction in the potential of the line 10 also causes the potential of the control brush group. This makes the tube C a little less conductive, and the potential of the line 10 rises again somewhat. However, a balance is eventually reached between the opposite effects, so that there is actually a steady potential which prevents the magnet M from responding when the sensing brushes sense the blank medium.

The positive potential that is applied to the grid G _{1 of} the control tube C via a specific group of individual brushes increases proportionally with the decrease in the resistance of the carrier material. Correspondingly, the conductivity of the tube C also increases, and the current flow through the resistor R also increases. Furthermore, the potential at point 1 decreases proportionally to the decrease in the resistance of the substrate. This reduces the sensitivity of the test brush groups, the lower the insulation resistance of the carrier material. If the resistance of the carrier material falls to or below a critical value in this way, the sensitivity of the sensing means to the unscrupulous material becomes lower, and this in proportion to the drop in resistance of the carrier material. As a result, the test brush group can only bring about a sensing circuit which reduces the grid bias of the relevant tube A if the marking is conductive.

Instead of an unused brush group for

Other sensing means can also be used to sense the conductivity of the unwritten substrate; so you can z. B. use an additional brush SB that works with the outside brush BE on the right. The connection 14 is then connected to terminal 16 of the additional brush SB. connected. Since in this case there is only one current path between SB and BC compared to the double path in the case of using a double brush BE, the circuit which influences the grid G _{1 of} the tube C must be set to a correspondingly different critical value of the carrier material, than is the case with an unused group with double brushes BE

¹ S was seen. This can be achieved by a lower value of the resistors R ₂ or or and R ₃ .

Claims (12)

PATENT CLAIMS: 20 1. A method for electrically sensing conductive markings on recording media, characterized in that the sensitivity of the sensing is changed when the conductivity of the carrier material (S) changes. 2. The method according to claim 1, characterized in • indicates that when the conductivity is increased of the substrate (-S ") the sensitivity of feeling decreased. 3. The method according to claims 1 and 2, characterized in that when the conductivity of the carrier material is increased, the sensitivity of the sensing is only reduced if free areas of the carrier (S) are sensed by conductive recordings, while conductive records are being sensed at the moment of the carrier (S) the sensing sensitivity is maintained practically undiminished. 4. The method according to claims 1 to 3, characterized in that when the conductivity of the carrier material is increased, the potential at the sensing elements (BE, SB) 'is reduced. 5. The method according to claim 4, characterized in that the potential reduction is effected by an increased voltage drop across a resistor (R). 6. Arrangement for carrying out the method according to claims 1 to 5, characterized by an electron tube (C), in the anode circuit of which there is a resistor (R) causing the voltage drop, so that this tube (C) in the event of an increase in the conductivity of the carrier material becomes conductive. 7. Arrangement for carrying out the method according to claims 1 to 5 and arrangement according to claim 6, characterized in that a fixed resistor (R) connected downstream and for sensing conductive records (P) serving sensing circuit for ongoing control of the insulation resistance of the carrier (S) set up sensing circuit is connected in parallel. 8. Arrangement according to claims 6 and 7, characterized in that the fixed resistor (R) downstream sensing circuit for sensing conductive records (D) in series with the sensing elements (BE, BC) a voltage divider (R ₁ and R ₄ ) for contains the control grid connection of a tube (A ) provided for triggering the switching or registration process (e.g. in M) , the control grid potential of which is dependent on the size of the contact resistance bridging the sensing brushes and the anode current of another tube connected in parallel to this sensing circuit ( C) controlled by a special sensing circuit that only senses the areas of the wearer (S) free of conductive records. 9. Arrangement according to claims 6 to 8, characterized in that when the insulation resistance of the carrier material decreases, the potential at the GUtCr (G ₁ ) of the tube (C) increases. 10. Arrangement according to claims 6 to 9, characterized in that when a conductive marking (D) is sensed, a magnet (M) is excited which triggers a switching or registration process. 11. The arrangement according to claim 10, characterized in that the magnet (M) lies in the anode circle of an electron tube (A) which becomes conductive when a conductive marking (D) is sensed by increasing the potential on its grid (G). 12. Arrangement according to claims 6 to 11, characterized in that brushes (SB) are used to determine the conductivity of the carrier material, which are not provided for sensing conductive markings and are arranged outside the actual marking fields. 1 sheet of drawings 5213 6.