DE2336614B2 - Device for counting documents - Google Patents

Description

The invention relates to a device for counting documents by the detection of a Gap with at least a minimal duration between

neighboring documents that are in a first direction and advanced at intervals, with the gaps to facilitate the Serving counting the documents and by the trailing edge of a document as well as the leading edge of the next document are defined with a one side of the path of movement of the spaced documents light source, with arranged on the opposite side of the movement path light-sensitive devices for Receiving light of maximum intensity from the light source when the trailing edge of a document the light source and the photosensitive devices passed, and num reception of light with less Intensity when a document is between the light source and the photosensitive devices located, with threshold value setting devices for establishing a predetermined threshold value level, and with comparator devices for comparing the output level of the light-sensitive devices with the output level of the threshold setting means for generating a signal with a first Level if the output of the light-sensitive devices is at least equal to the threshold level and at a second level if the threshold level is greater than the output level, the first Level represents the presence of a gap

In a known device of this type (US Patent 36 60 670) to be filmed documents are counted by the presence between two successive documents with the aid of a lighting device and a photodetector is detected. The detector circuit used here is designed so that when the Output level of the photodetector due to the presence of dust or a reduction in the brightness of the Illumination source provides automatic compensation. However, such a device is not for Counting documents at high speed is not particularly suitable if these documents have different colors and light transmittances as well as deliberate breakthroughs such as B. with punch cards, or have tears or damage. Such documents must in many cases be included transported and counted at high speeds, with no counting errors due to tears or perforations in the documents may occur and in spite of the high speeds no disruptions to the transport may occur.

The invention is based on the object of providing a device as described in the preamble of claim 1 called type to provide the counting of documents at high speed and high Security and reliability made possible without a miscounting due to slight damage or Cuts out in the document.

According to the invention, this object is achieved by that the counters delay devices which respond to the beginning of the gap level to to initiate a delay period with a predefined mi interval, first logic gates that act on the delay devices and the Address change in the output signal of the comparator from the gap level to the remaining level to one Generate counting pulse, and second link- ■ * ■ to prevent generation of the count pulse if the delay interval after the elimination of the gap level ends in order to ensure that gap intervals that are shorter than the specified interval are not mistakenly interpreted as a valid counting pulse.

In this way, short pulses are suppressed that are generated due to a small perforation or cut-out in a document or that are generated as Result of radio frequency interference generated by a motor or other electronic parts be evoked.

Further advantageous refinements and developments of the invention are set out in the subclaims specified.

Exemplary embodiments of the invention are described below with reference to the drawing.

Show in it:

F i g. 1 shows a simplified side view of a device of a device for feeding, sorting, counting and stacking documents and the like,

La is a side view of a device for taking statistical samples from the transported Documents,

F i g. 2 shows a plan view of the individual transport devices in the device according to FIG. 1,

3 shows a circuit diagram of an embodiment of the light-sensitive device and the lighting device,

F i g. 4a to 4f are circuit diagrams of the control device for the device according to FIGS. 1 to 3,

5a to 5c graphical representations of voltage curves for explaining the control circuits according to Figures 3 and 4a to 4f.

The device 10 according to FIGS. 1, la and 2 has a Housing 11 with a bottom part 12 for placing the device 10 on any surface, for example on a table or the like.

The housing 11 is provided at the upper end with an end face 13, attached to the monitoring devices or provided in some other way can be included in the controls for starting and stopping the machine, which are included in the following are to be described in more detail, so that a statistical sampling or an intermediate count, etc. can be carried out, with also Visual display means are provided for determining the number of documents processed by the device.

The control panel 13 forms part of the front of the housing 11, which is also provided with an input magazine 14, consisting of a plate 15 for stacking sheets or other documents S. This stack S rests with part of its weight on the rear plate part: 15a of the plate 15 with the leading edges of the sheets resting against a plate 16a. The input stacker 14 is inclined in such a way that the sheets of the stack are held in the loading magazine by their own weight, so that it is not necessary to load the stack with a supporting weight, and at the same time the feeding of the documents from the loading magazine is facilitated, as is described in more detail in the above-mentioned patent application, which does not need to be discussed in more detail here

A gripping wheel 19 which can be rotated about a gripping wheel shaft 20 has one or raised part 19a, which is formed by a gripping wheel in the plate part 15a provided suitable opening protrudes and on the lowermost sheet in the stack attack and can move this sheet against a drive wheel 23, which is used to perform rotary movements in the direction indicated by the arrow 26

is mounted on a shaft 24. Above the drive wheel, a stripping wheel 52 can be rotated on a shaft 47 stored and resiliently arranged to carry out a stripping process. The stripping wheel 52 rotates in the Direction indicated by arrow 54 and serves to follow all other documents than just the bottom sheet to promote rear, so that between the drive wheel 23 and the stripping wheel 52 only one document in the direction an accelerator wheel assembly to be described below can pass forward.

The coefficient of friction of the material on the periphery of the drive wheel 23 is higher than the coefficient of friction of the material on the circumference of the stripping wheel 52, so that the drive wheel 23 when a single sheet passes through between these wheels (be it as a result of a stripping process or because only a single sheet is fed was) exerts the main influence on the conveying movement of this sheet, whereby it is achieved that the Sheet is brought forward to an acceleration wheel 60, which rotates in the direction of the Arrow 62 is mounted on a shaft 61. The acceleration wheel 60 operates with idle rollers 64 together, which are rotatably mounted on a shaft 66. The acceleration wheel 60 rotates at a higher rate Rotational speed than the drive wheel 23, so that between the acceleration wheel 60 and the idle Roller 64 conveyed sheets a higher feed speed in the direction of a stacking point is issued than the sheet located between the drive wheel 23 and the stripping wheel 52. This process has with the result that between the rear edge of the between the acceleration wheel 60 and the roller 64 located sheet and the leading edge of the next following document, which of the drive wheel 23 and the Stripping wheel 52 is promoted in the direction of the acceleration wheel 60, forms a small gap. To enable One perception of this void is one with a photosensitive device in the form of a Transistor 72 or cooperating with some other suitable light-sensitive device Light source 65 provided so that a counting pulse is generated when in the area between the Light source 65 and transistor 72 a gap appears. In the plates 15a and 16a are natural Corresponding openings (not shown) are provided to allow light to pass between the light source 65 and to enable transistor 72 when the mentioned gap is in this area.

The sheets fed by the accelerator wheel 60 are ejected into a stacker mechanism, which comprises a tray 81 and an ejector wheel 84 which rotates in the direction of the arrow 91 is mounted on a shaft 85, so that the counted sheets are neatly stacked in the stacker device can be. The storage plate 81 is supported by suitable loading means, as indicated by the arrow 97 Direction loaded As the number of sheets in the stacker increases, the tray 81 is loaded by the Weight of the sheets pressed against the force of the loading means in the direction of arrow 98, so that the Sheets are held firmly in the stacker.

In Figure 2, the drive devices for the actuation of the individual, in the above based on Fi g. 1, a motor M is provided for the device, which has an output shaft 129 which extends through a machine structure F to which the motor Λ / is fixedly attached. A pulley is attached to the output shaft 129

130 keyed, of which the shaft 61 of the acceleration wheel 60 is driven by a pulley 63 which is wound around the pulley 130 and around one of the Shaft 61 of the acceleration wheel 60 carried pulley 62 is guided around. On the other Pulleys 133 and 134 are provided at the end of the shaft 61. The pulley 133 is on the shaft 61 wedged and drives the shaft 85 of the ejector wheel 84 over a round belt 132, which around the pulley

ίο is led around 133 and a keyed onto the shaft 85 pulley 89 Reimen 132 is an elastic round belt and is guided in a roller line, so that the shaft 85 opposite to the shaft 61 rotates at a start-up of the motor M thus rotate in in each case the shafts 61 and 85, which are directly coupled to the motor.
A coupling device is also located on the shaft 61

131 is provided which, when actuated, causes the belt pulley 134 carried by the coupling device 31 rotates in the non-actuated state enables the coupling device 31 to freewheel the pulley 134 with respect to the shaft 61. Um the pulley 134 and around a pulley 136 keyed onto one end of the drive wheel shaft 24 a belt 135 passed around At the other end, the drive wheel shaft 24 carries two pulleys 25 and 138, which are also keyed onto the shaft. Around the rime disk 25 and around one on the gripping wheel shaft 20 On the keyed pulley 21, a belt 142 is passed around. A belt 140 is around the pulley 138 and guided around a belt pulley 42 keyed onto an intermediate shaft 39. The shaft 39 is used to drive the stripping wheels 52 and 53 in a rotational movement via a belt 45 which is guided around pulleys 44 and 38, which are keyed onto the intermediate shaft 39 and onto a shaft 31, respectively. The rotary movement is then carried out by means of a belt 50 via a second pulley part of the belt pulley 38 is transmitted to a pulley 51 carried by the shaft 47 of the scraper wheels. This clearance device for the stripping wheels 52 and 53 enables these wheels to be driven with free movement of the Stripping wheel arrangement 30 above the drive wheels 23 to 23c

The pulleys 133 and 89 have semicircular grooves on the circumference into which the round belt 132 is included All other pulleys are gear-like on the circumference so that they are in the Can mesh teeth provided on the belts that engage these pulleys and commonly referred to as timing belts. In Fig. 2 are all straps with broken lines only indicated to facilitate and simplify the overview.

An electromagnetic brake 137 is attached to the machine structure F, which is selectively used for engaging at one end 20a of the gripping wheel shaft 20 can be actuated. When pressed, the electromagnetic Brake 137 the hand wheel shaft 20 abruptly

h ° to a standstill. In the inconsistent state the electromagnetic brake 137 free rotational movements of the gripping wheel shaft 20 to.

In operation, the shafts 61 and 85 are constantly driven to rotate as long as the motor M

"" 'works The coupling device 131 enables a selective disengagement of the drive wheel shaft 24, the intermediate shaft 39 and the gripping wheel shaft 20 from the Drive connection with the motor M, if this

is working. The clutch device 131 and the electromagnetic brake 137 are actuated practically at the same time, so that the shafts 24, 39 and 20 of the drive connection even when the motor is working can be disengaged and brought to an abrupt stop.

The advantageous features of the drive and control devices provided for the document processing device can best be appreciated in the course of the description of the Leitanord- ι ο tion 200 shown in FIG 201 engages, which is rigidly connected to a shaft 202. At least at one end of the shaft 202, which extends to the one side wall of the machine structure (not shown for reasons of clarity), a lever arm 203 is provided which is rigidly attached to the shaft. The armature 204a of a relay 204 is connected to this lever arm 203, and when the relay is de-energized, it holds the flap 201 in the position shown in solid lines. By energizing the relay it can be effected that the flap and the arm move against the force of a tension spring (not shown) into the position 201 'indicated in broken lines.

It is assumed that a large number of sheets are to be counted, with only statistical samples to be retained from the sheets to be counted (for example, perhaps every most obstructive sheet). The flap is held in the position shown in broken lines, so that the sheets are conveyed by the acceleration wheels 60 and passed over the flap 201 in order to be grasped thereupon by belts 207 and 208 which move around pairs of rollers 209-210 and 211- 212 are shown around. The sheets are conveyed by the rhymes 207 and 208 in the direction of the arrow 213, whereupon the counted sheets are deflected through a curved plate 214 into a paper basket or into another suitable tray 215. When the trailing edge of the 99th sheet has passed flap 201 and between the belts

207 and 208 is reached, the relay 204 is de-energized and moves the flap into the position shown in solid lines, so that the 100th sheet is fed to the stacker 80. If the hundredth sheet leaves the flap 201 behind, the relay 204 is energized, whereupon the next sheet zv / ischen the rhymes 207 and

208 is introduced. The process is repeated so that the receipt processing device determines the total number of sheets and only keeps every hundredth sheet as a statistical sample in the stacker 80. The remaining sheets in the bin 215 can be disposed of or used for other desired purposes. ⁵ ^

It is of course clear that any desired statistical sample can be taken by means of a correspondingly adjustable switching device, which will be explained in more detail below in connection with the electronic control circuit. Every time the gap between the separate sheets is sensed by the transistor 72, increased the count of the counter provided in the electronic control unit described below increases by one. The count accumulated in the counter is compared with the setting for the desired statistical sample, whereupon the relay 204 is energized so that only the copies for the statistical sample are collected in the stacker 80, whereas the remaining sheets are ejected into the bin 215 will. The clutch and brake devices described above are selectively actuated by an "N-1" signal and an "N + 1" signal, thereby ensuring that between each sheet that precedes the sheet with the count "M" and the one immediately following the Sheet with the count value "M" following sheet a gap G of sufficient length appears to have a sufficient amount of time for the execution of the mechanical movement of the flap 201 available. A decoding circuit provided as part of the electronic switching means generates a signal "N- 1" when the trailing edge of the sheet preceding the sheet with the count value "M" passes transistor 72, so that the drive, stripping and gripping wheels are also out of the drive connection disengaged from the motor and brought to an abrupt standstill as a result of the actuation of the electromagnetic brake 137, as a result of which the receipt with the count "N" is slowed down. The flap 201 is moved to the position 20Γ indicated in broken lines and the braking and coupling devices are then released, whereupon the feeding process is continued. If the trailing edge of the sheet is perceived with the count "M", the above sequence is repeated in the opposite sense and the flap is brought into the position 201 'shown in broken lines. Production is resumed until the next sample for the statistical sample approaches transistor 72. The routing arrangement described above can also be used for mapping. For example, it may be desirable to stack each odd-numbered sheet (namely the original) in one pile and each even-numbered blue (the carbon paper copy of the respective original sheet) in a separate pile. This can be achieved in that the flap is operated in the above manner after each sheet is fed into the device. If desired, it is also possible, for example, to collect the original sheets in the stacker and, for example, to allow five copies of each original sheet to reach the tray 215 for further assignment or processing.

The document processing device of FIG. 1 and 2 can also be used for processing in batches. For example, the task could be to pile up a large number of sheets in separate stacks, with the same, predetermined number of sheets to be present in each stack. For example, it may be necessary to arrange a large number of dollar bills (paper money) in piles of one hundred one-dollar bills each. The paper money can be stacked in the input magazine 14, and it can be any number of banknotes up to the maximum capacity of the input magazine. A start key is depressed and the device begins to count the bills. If the most obstructed bank note is passed past the transistor 72, the counter compares its count value with the corresponding count value which is set on the electronic control device, whereupon a signal is generated after the passage of the hundredth bank note, by which the electromagnetic brake 137 is excited and the Coupling device 31 is put out of operation, so that the gripping, stripping and driving wheels suddenly come to a standstill while the acceleration

The gearing and ejecting wheels continue to turn, resulting in perfect stacking of the hundredth banknotes is guaranteed within the stacker 80. The machine then switches off automatically and in that Forklifts 80 are now exactly one hundred one-dollar bills stacked neatly. The operating process can go through Depressing the start button can be repeated to move to the next group of one hundred one dollar bills count and stack.

Assume that the start key has been pressed and that the receipt processing apparatus 10 is up to seventy one dollar bills counts and stacks, whereupon the supply located in the input magazine 14 of the counting banknotes is exhausted. The stripping, driving, gripping, accelerating and ejecting wheels Although they continue to rotate, the counter provided in the electronic control means cannot continue counting and the count value for the banknotes that have already been counted and stacked therefore remains unchanged. The operator now only needs a new stack of one dollar bills in the input magazine 14 to insert, whereupon the counting process is continued in the manner described.

It will now be described the electronic control means that ensure the reliable and proper operation of the document processing device. In Fig. 3, the receipt detector 300 is shown which includes a photosensitive transistor 72. The emitter is activated when the gap between separate documents is detected. The collector of transistor 72 is connected to a DC voltage source + V, while the emitter electrode via a resistor Rl to a ground bus 30! is set, the emitter of which is connected by a line 302 also to the base of a transistor 303 whose collector is connected to the DC voltage source + V via a resistor Λ 2 The emitter electrode of the transistor 303 is a via a capacitor C 1 to the ground bus 301 and Resistor R 3 is connected to one input terminal 304b of a comparator 304 .

The resistor R 3 is also connected to the ground bus line 301 via a resistor R 4. Furthermore, the emitter electrode of the photosensitive transistor 72 is connected to the other input terminal 304a of the comparator 304 .

In the quiescent state, ie when no gap is detected, the transistor 72 is in the non-conductive state, so that its emitter electrode has ground potential, as a result of which the ground potential is also applied to the base of the transistor 303. From the emitter of transistor 303, the ground potential is thus also applied to input 304a of comparator 304. This transistor is kept in the non-conductive state by the ground potential appearing at the base electrode of transistor 303.

The resistors A3 and A4 form a voltage divider, the output of which appears at a terminal 305 which is common to both the resistor R 4 has a considerably high resistance value of about 100 kilo-ohms, with this value preferably across the resistor by about 100 kilo-ohms, which value is preferably above the resistance value of resistor A3

Before the mode of operation of the document detector 300 is explained, let us first look at the peculiarities of FIG Circuit and the problems to be solved by this circuit were briefly discussed.

In the case of document processing carried out at high speed, the rapid Movement of the papers or receipts, of course, not inconsiderable amounts of dust. These dust particles over time are reflected on the individual components of the document processing device, so inter alia. also on the light source 65 and on the photosensitive surface of the transistor 72. The dust piles up gradually on and after a longer period of time that

ίο amount to days or weeks, for example can, the amount of light emitted by the light source 65 as well as the amount of light that is still the able to penetrate dust deposited on the photosensitive surface of the transistor 72, considerably degraded. The threshold remains above which a pulse emitted by transistor 72 remains indicates the existence of a funding gap and below which an output pulse does not yet exist Delivery gap signals, unchanged during a longer period of operation, so this therefore leads to False information. The threshold chosen is a compromise between the maximum output level of the photosensitive transistor and such an output level of the photosensitive transistor as it appears as a result of the passage of light through the documents, which are not transparent, but at least are translucent and therefore also allow a certain proportion of the light from the light source 65 to pass through. Of the The threshold value is consequently set taking into account the light transmission behavior of the device 10 the F i g. 1 documents or sheets to be processed are specified accordingly.

Further physical conditions which have an influence on the sensitivity of the detector arrangement can result from the effects of heat and general aging of the switching elements. This physical process affects the sensitivity of the detector gradually decreases until after a period of

* o if the duration is sufficient, a reduction in responsiveness of the photosensitive transistor in conjunction with the maintenance of an absolutely constant The result of the threshold value is that the detector delivers a false output

⁴ S is essentially about creating a detector arrangement with self-compensation, in which the threshold value can be shifted accordingly in order to take account of such gradual changes in the sensitivity of the detector.

It is assumed that the receipt detector 300 of FIG. 3 initially works under ideal conditions, as the light source 65 and the light-sensitive transistor 72 are completely free of dust and dirt particles, the light source 65 being operated at its maximum brightness to emit light. The incident of the light on the light-sensitive emitter of the transistor 72 causes the transistor to conduct, creating a current path between the positive voltage source -f V and the earth bus-

device 301 is established. There is therefore a voltage drop across the resistor R i, which has a voltage level E _w (see FIG. 5a). It is assumed that the voltage of the voltage source + V amounts to 5 volts DC and that the voltage drop across the transistor 72 in the conductive state is so small that it can be neglected. The voltage drop between the connections of the resistor R 1 is therefore 5 volts, which is the maximum

of the bright state E _w corresponds

A level + 5VoIt appearing at the emitter of transistor 72 is thus fed to the base electrode of transistor 303, whereupon the transistor changes to the conductive state, so that capacitor C1 is charged very quickly. The DC voltage level + 5 volts (Ew) also appears at the input terminal 304a of the comparator 304 for comparison with the threshold value, as will be explained in more detail below.

The capacitor C1 charges up rapidly and, thanks to its coupling with the emitter of the transistor 303, a voltage E _c builds up, so that it is charged up to a level of +5 volts DC. The voltage divider circuit consisting of the resistors A3 and R 4 causes a voltage E _{1 to} appear at the terminal 305 which represents the threshold value with which the output voltage level E _{w is} compared. In the example used here, this value is approximately 3 ½ a volt. The comparator 304 produces a positive output level whenever the voltage level at its input terminal 304a exceeds the voltage level at its input terminal 304f>. In the example shown, E _{w is} greater than E ₁ , so that a positive level appears at the output terminal 304c.

It should be mentioned that the resistors R3 and A4 can be adjustable so that the threshold value E can be selected accordingly. It is assumed, for example, that a sheet with a certain light permeability is passed between the light source 65 and the photosensitive transistor 72 (the sheet S ' in FIG. 3). A certain amount of light passes through the sheet 5 'so that the transistor 72 partially conducts, with the result that the output level at its emitter electrode assumes a value which is equal to or less than the value E _{1 determined during the previous delivery gap} This level is sufficient to control transistor 303 into the conductive state, so that capacitor C1 is charged and a threshold value is generated which is preferably higher than the level at the emitter of transistor 72, so that comparator 304 does not provide a positive output level can. It is therefore clear that the threshold value E, must be sufficiently greater than the level En in order to prevent the light transmitted by a translucent or partially translucent (ie translucent) document from giving the false impression that there is a gap between two documents.

The self-compensation behavior of the circuit is produced as follows:

As already mentioned, the resistors R3 and Ra have resistance values which are relatively high overall, so that the sum of these resistance values is kept at more than about 100,000 ohms, which requires a relatively high time constant for the discharge of the capacitor Cl, whereupon will be discussed in more detail below

The sheets processed by the document processing device 10 of FIGS. 1 and 2 are preferably transported at a speed of about 150 cm / sec and photosensitive transistor 72 requires a period of about 50 milliseconds. Referring to FIG. 5b it is assumed that the leading edge of a document S 'is pushed between the light source 65 and the light-sensitive transistor 72 at a point in time fo. At this point in time, the voltage output of the emitter electrode of transistor 72 is E _s \ (if the document is partially translucent, i.e. not opaque, so that a certain amount of light is transmitted). The output of the emitter electrode of the transistor 72 therefore has a value E _sU which also appears at the input terminal 304a of the comparator 304. Because of the slow discharge rate of capacitor C 1 (which will be discussed in more detail below), the level at terminal 305 of the voltage divider circuit is at E, and this value appears at input terminal 304i> of comparator 304, so that the output of the comparator has the basic level ( 0).

At the time / | leaves the trailing edge of the document S ' the area between the light source 65 and the light-sensitive transistor 72, so that the transistor 72 fully into the light-sensitive transistor 72, so that the transistor 72 completely changes to the conductive state and a voltage level E _{w at its emitter electrode} appears. At the same time, the voltage E _{w appears} at the emitter electrode of the transistor 303, so that the capacitor C1 charges quickly to approximately the level E _w. The voltage divider supplies the comparator with a threshold voltage value E ₁ . Since the value E _w exceeds the value E, the comparator generates a positive value, whereby the presence of a gap between the document 5 'and the next following document 5 "is determined. The level value £ Ή remains at the emitter electrode of the transistor 72 until The leading edge of the sheet S ″ moves at the line point I ₂ into the area between the light source 65 and the transistor 72, which results in a considerable reduction in the conductivity of the transistor 72, so that there is a drop to the level Eä and a slight discharge of the capacitor Cl begins. This level now remains until time f3, ie until the trailing edge of the document S ″ leaves the area between the light source 65 and the transistor 72 and before the leading edge of the next document (not shown for the sake of simplicity) enters this area

At the time fc, when the output level of the emitter electrode of the transistor 72 abruptly drops to the value E _s \ , the voltage resistance values of the resistors R 3 and R 4 and the capacitance value of the capacitor Cl cause the capacitor Cl to discharge very slowly. For example, in a preferred embodiment, these values for the capacitor C 1 and for the resistors R 3 and R 4 are chosen so that the capacitor C1 is completely discharged in the course of a time interval of about 500 milliseconds is about 50 milliseconds, the capacitor Cl discharges so that the voltage across its terminals is close to 90 percent of the voltage E ₁

It is now assumed that there is a gradual change in the maximum output level of the emitter electrode of the transistor 72 with the passage of time due to the accumulation of dust or the increase in temperature of the components with prolonged use. From Fig. 5b it can be seen that the value E _w gradually decreases, so that at a point in time U a value _{E 9} * appears at a

Time is a value E ₁ ^, at a time & a value E _w3 and so on. Each of these decreases in the output level of the emitter electrode of transistor 72 also results in a corresponding decrease in the voltage applied to the base electrode of transistor 303, so that the capacitor C1 charges to a correspondingly lower value, as a result of which the threshold value E also drops accordingly, as is illustrated by curve 306 in FIG. 3, the threshold value Et automatically shifts in accordance with the gradual changes in the output voltage level of the transistor 72. For the purposes of the illustration of FIG. It should be noted in FIG. 5b that curve 307 represents the course of a pulse train as it appears over a considerable period of time, that is to say perhaps over the course of days or weeks.

In Fig. 5c, a part of the curves 306 and 307 is shown greatly enlarged in order to explain in more detail the mode of operation of the capacitor C1 and the voltage divider circuit consisting of the resistors R 3 and R 4. It is assumed that the document conveyor is switched on. Since no documents have yet been entered into the unit at this point in time, the light source 65 causes the capacitor C1 to charge rapidly, as is shown by part 306a of curve 306. At the time fo, the first document enters the area between the light source 65 and the transistor 72, with the result that the output value of the emitter electrode of the transistor 72 drops to the voltage level E ₅ \. At this time, the capacitor C \ slowly discharges, as shown in part 306b of the curve, the voltage level of the capacitor C1 dropping to about 90 percent of the maximum voltage E. At time / 1, the rear edge of the document leaves the area between the light source 65 and the transistor 72, so that the output level of the transistor 72 assumes the value E _w. The capacitor C1 is now charged to its full value within a very short period of time, as can be seen from part 306c of curve 306. The state of full charging of the capacitor Cl continues and the level E remains maintained until the time t ₂ , namely until that time when the leading edge of the next document reaches the area between the components 65 and 72, whereupon the output level of the Emitter electrode of transistor 72 drops to the value E _5i. The capacitor now discharges again very slowly, as is shown by part 306d of curve 306. Each time a new gap is felt between the documents processed by the document processing device 10, this sequence is repeated continuously in the manner described above. When the sensitivity of the transistor 72 decreases due to the gradual accumulation of dust or due to the action of heat, the output level E _w gradually lowers, as described above, so that the capacitor Cl is reduced to one because of the reduced voltage supply to the base of the transistor 303 charges lower voltage value. The threshold value St is thus gradually reduced, but maintains a value which is proportional to the respective maximum output level E _w , E wf, E ^ _{2 etc. when the response sensitivity of} the transistor 72 is gradually reduced. From this it can therefore be seen that the detector of FIG. 3 is able to fully compensate for all gradual changes in the detector sensitivity.

The comparator 304 is constructed so that it during the time span of the passage of a document through the area between the components 65 and 72 An output value of zero volts delivers and it is capable of during the period of detection of a funding gap to provide a positive output level of about +5 volts.

In order to increase the versatility of the document processing device 10, so that documents and / or sheets of any kind can be processed, it is of great importance that precenings are taken in order to prevent false indications of delivery gaps. For example, assume that the receipt processing device 10 is used to count punch cards. Some of the holes punched in the punch cards can be located in such a way that they pass in the direction of flight of the light source 65 and the transistor 72, so that an output pulse or needle-trip pulse such as the needle-shaped pulse 308 shown in FIG. 5c can be generated. Since this pulse reaches the value E _w , which is clearly above the threshold value E ₁ of curve 306 (cf. part 306c / of this voltage curve), comparator 304 generates an output level of + 5VoIt at this point in time, so that the presence of a » Gap «is displayed. Perforations, incisions, slits or tears, which are either intentionally provided in a document or accidentally caused by tearing or damage to the document in the course of processing, would also cause such a narrow pulse to be generated. It must therefore be prevented that these narrow pulses are interpreted as gaps between adjacent documents which have been separated from one another by the document processing device.

As stated above, the time elapsed between fi and to denotes the time from the entry of the front edge of a document into the area between the components 65 and 72 until the point in time when the rear edge of the document exits this area again. The circuit 310 provided to avoid misinterpretation of the narrow pulses as "gaps" between the documents is shown in FIG Counting pulses are received. A capacitor C2 and a resistor RS are connected in series between a terminal + 5VoIt direct voltage and ground, their connection point 312 being connected to the input line 311 via which the output of the comparator 304 is fed. The capacitor C2 and the resistor R 5 provide a filter effect against high-frequency noise, such as may arise from motors, etc., and which affects the input line 311 through magnetic or electrical coupling. The input line 311 is connected to one input of a NAND gate

313 connected. The output of the NAND gate 313 becomes the input terminal of an inverter

314 fed, the output of which is one input terminal of a NAND gate 315 and at the same time is also fed to one input terminal of a NOR gate 316. The NOT-OR element 316 and a further NOR element 317 are cross-coupled and form in this

Form a single step filter circuit (SS filter), the mode of operation will be described in more detail. The output of the NOR gate 316 appears at one input terminal of the NOR gate 317, while the output of the NOR gate 317 appears the other input terminal of the NOR gate 316 appears The output of the NOR gate 316 also appears at one input terminal of the NOT-UN D elements 315 and 318 and at the input terminal 319a of a monostable multivibrator 319. The other input terminal of the The NOR gate 317 is connected to one terminal of a capacitor Ci , the other terminal of which is grounded. A diode CR 1 and a resistor R 6 are connected in parallel between the output terminal of the NOT U N D gate 315 and the capacitor C 3 The output connection of the NAND element 318 is connected via a resistor R 7 to the DC voltage connection + V and at the same time via a resistor RS to a delivery inhibition s-delay circuit 320 and connected to a delay circuit 330 for preventing a delivery inhibition.

The delivery inhibition delay circuit 320 comprises a diode CR 2 and a capacitor CA and provides a rectified and filtered DC voltage level at the common terminal. A voltage divider, consisting of resistors R 9 and R 10, leads part of this voltage to the base of a transistor Q \ whose collector is connected to the DC voltage source + V via a resistor All and whose emitter is grounded. The collector is also connected to the input terminal of a Inverter 321 connected, the output terminal of which is connected to the other input terminal of the NAND gate 313.

The delay circuit 330 for preventing a delivery inhibition is constructed similarly to the delivery inhibition delay circuit 320 and comprises a diode CR 3 and a capacitor £ 75 for rectifying and filtering the input supplied. Two resistors R 12 and R 13 serve as a voltage divider, through which part of the output voltage appearing at the common connection between the diode CR 3 and the capacitor CS is fed to the base electrode of a transistor Q 2 , the emitter of which is grounded and its collector via a resistor R. 14 is applied to the DC voltage source + V.

During the time when no counting takes place, a portion of the DC voltage level is applied to the base of transistor Qi so that this transistor conducts. At this time the voltage at the collector of transistor Q 1 is low (practically zero volts) so that the output of inverter 321 goes high, whereby one input of NAND gate 312 appears high. In the event of non-payment, the output of the comparator 304 is high, so that a high level value also appears at the other input of the NAND gate 313, so that its output assumes a low value, but an inversion takes place through the inverter 314, whereby the an input terminal of the NOR gate 316 and the NOR gate 315 is supplied with a high input. As a result, the output of the NOR gate 317 assumes a high value and this level appears at the other input terminal of the NOR gate 316, whereupon its output assumes a low value. AND gate 315 causes its output assumes a high value, so that the other input terminal of the NOR gate 317 a A high level signal is received This state remains due to the cross-coupling of the NOT-OR gates 316 and 317 maintained and the monostable

ίο Multivibrator 319 is therefore an input with a lower Level too. It is now assumed that a document is in the Area between the light source 65 and the transistor 72 enters. This has the consequence that a low output appears on the input line 311, so that the

Output of NAND gate 313 assumes a high value. This state is reversed through the inverter 314, and at one input terminal of the NOR gate 316 therefore appears a low level. As a result, its exit takes place

a high value, so that again at the NOR gate 317 a high input level appears causing the output of the NOR gate 317 assumes a low value. This low level becomes the other The input terminal of the NOR gate 316, the output of which therefore remains high The high level signal is inputted to the input terminal 319a of the one-shot multivibrator 319 fed so that at its output terminal 3196 a Output pulse with a predetermined pulse width appears. At the same time, a positive-going pulse appears at the other output terminal 3i9c of the monostable multivibrator, which is one of transistors Q 3 and QA and a Zener diode CR 4 existing circuit is fed, whereby an output appears at the collector electrode of the transistor QA , which is used to advance an electromagnetic counter (FIG. 4c) by a count value. As mentioned above, the exit remains of the comparator 304 for the duration of a document pass at the low level, that is, during a Time span of about 50 milliseconds, after which the level value appearing on input line 311 increased abruptly to + 5 volts DC, so that the

The output of the NAND gate 313 is low and the output of the inverter 314 is high Assumes value, whereby the gates 316 and 315 a high level value is again supplied. Of the The output of the NAND gate 315 therefore takes

a lower value. The capacitance of the capacitor C3 and the resistance of the resistor R 6 are chosen so that the capacitor C 3 discharges slowly, whereby the high level at the one input terminal of the NOR element of the 317 connected terminal of the capacitor C3 is retained, so that a change in the state of the NOT-OR gates 316 and 317 bistable circuit and thus the supply of an error pulse to the monostable Multivibrator 319 is prevented until a sufficient time has elapsed to discharge the capacitor C3 . The discharge rate of the capacitor C3 is dimensioned accordingly, so that the capacitor is completely within a period of 20 milliseconds can discharge, with this period of time quite lies within the normal time interval for a production gap, while on the other hand it is prevented that the capacitor moves within shorter time intervals

unloads how they would be charged if in holes, cracks in the document passed between the light source 65 and the detector (transistor 72) or damaged areas of another kind should be present.

If the output of the NOR gate 316 assumes the high value, the NAND gate 318 provides an output with a low level, so that the discharge process of the capacitor C \ in the delay circuit 320 can begin. The time interval up to the complete discharge of the capacitor C4 amounts to about 100 milliseconds and thus exceeds the time required for the passage of a sheet through the area between the light source 65 and the transistor 72, so that at the other input of the NAND gate 318 an output with a high level is retained If a period of time has elapsed which is longer than the time required for the document to pass through the scanning area without a gap being detected, the output of the inverter assumes the low value, which causes is that the input of the connected NAND gate 313 drops, so that the circuit 310 can no longer generate any further counting pulse.

In summary, with regard to the mode of action of the in Fig. 3 and 4a shown receipt detector 300 and the circuit 310 determine that these circuits to serve to create a gap between the trailing edge of a document and the leading edge of the next following document, both of which are connected to transistor 72 to be distinguished from any holes or tears in the document itself, so that it there is no misinterpretation of such holes as funding gaps or funding distances, so with that no false counting pulses are generated. This distinction is made when counting receipts stamped code has a very far-reaching meaning.

It is assumed that the rear edge of a receipt has just passed transistor 72 (FIG. 3) after capacitor C3 (FIG. 4a) has been fully charged immediately beforehand. The output of the comparator 304 (FIG. 3) goes high. The output of the NAND gate 313 assumes the low value and the output of the inverter 314 assumes the high value. The counting pulse I _a is locked when the output 316a of the NOR element 316 has a high level value, which is why a high input appears at one input connection of the element 315. Since the output of inverter 314 is high, the output of NAND gate 315 goes low, thereby discharging capacitor C3. If the capacitor Ci has discharged to below the reset threshold value of the reset input 3176 of the NOR element 316, 317, the output 317a assumes the high value. This has the consequence that the output 316a of the NOR gate 316 assumes the high value. The time interval required for capacitor C3 to discharge from fully charged (approximately 5 volts DC) to the reset threshold (approximately 0.8 volts DC) is typically about 10 milliseconds. If one assumes a speed of the conveying movement of the documents of 150 cm / sec, then the trailing edge of the last document has moved over a distance of 15 mm within this period of time.

Since the nominal value of the distance between the documents is about 18 mm, the leading edge has of the next document has not yet reached transistor 72. Because the discharge of capacitor C3 has reached the reset level and the Output 317a has assumed the high value, the output of the NOT-AND element 3i5 also takes the high so that capacitor C3 begins to charge before transistor 72 switches to the

ίο Appearance of the leading edge of the next receipt responds If the leading edge has appeared, the output of the comparator 304 assumes the lower value, whereupon the output of the NAND gate 313 assumes the high value, while the output of the Inverter 314 and the input 3166 of the NOR gate 316 assume the lower value, see above that the output 316a of the NOR gate 316 assumes the high value that is now at the one Input terminal of the NOR gate 317 and of the NOT-AND element 315 appears The lower However, the output of the inverter 314 appears on the other input terminal of the NAND gate 315, so that the NAND gate 315 continues to deliver the high output, which has the consequence that the Capacitor C3 continues to charge and has reached full charge before the next Trailing edge has passed the transistor 72 (see, for example, the voltage curve in FIG. 5c). the The above processes are then repeated for each following document.

If the document moved past contains a punched hole in the area detected by transistor 72, then it takes place the output level of the comparator 304 becomes high. But such a punched hole extends in the typical case in length about 3.2 mm. Does the document move at a speed of 150 cm / sec continues, the punch hole is on the transistor within a period of about 1 millisecond 72 passed, the capacitor C 3 in Has discharged only a little over the course of this time and its voltage level is still clearly above the threshold value for reset input 3176. The pulse iss therefore does not cause a reset. The circuit also prevents resetting if a whole series of punched holes appears (in typically a maximum of 12 holes can be provided in a row), since the capacitor C3 too as a result, it does not fall below the reset threshold value. It can therefore be prevented that defective

so places or holes other than punched holes with a size of about 13 mm or less in the direction of travel interpreted as conveying gaps will. There is no maximum value for the size of the gap or the distance between the rear and Specify the leading edge of consecutive documents. But for the minimum length of this distance is the determining the lower limit of the response of the circuit arrangement and it should preferably be about 10 mm.

The delay circuit 330 for preventing a production inhibition operates in a similar manner, wherein the one input terminal is connected to the voltage source for +5 volts DC voltage, while the other input port to the output port of the NOR gate 316 is coupled. It will Perceived the presence of a document, the other input of the NOT-AND element 318 takes the high value, whereby its output the low

Assumes value, whereupon the discharging process of the capacitor C5 can begin. If the output of the NAND gate 318 does not assume the high value in the course of a somewhat longer period of time than that in which the receipt should appear, then the capacitor C 5 discharges, whereby the output of the transistor Q 2 has the high value The state is reversed by the inverter 323, the output of which is fed to one input terminal of the NOR gate 324, while the output of a NAND gate 354 shown in FIG The input of the NOR gate 324 is fed a signal with a low level, whereupon the output of the NOR gate 324 assumes the high value. This state is reversed by the inverter 325, of which the input terminal of a shown in Fig.4e NOT -OR element 380 is supplied with a signal with a low level, which results in an actuation of the electromagnetic braking and coupling device in the manner described above, wodu A feeding of further documents into the document processing device is prevented, so that a jamming or jamming of the mechanism which is difficult to eliminate can be prevented or the document processing device can be brought to a standstill or slowed down during batch processing or statistical sampling.

At F i g. 4b is a block diagram of the electronic counter and the selector switch of Control device. The electronic counter 340 is made up of counting stages 341, 342 and 343 for the units, tens and Hundreds built up, which are connected electrically so that they have a binary count for each decimal able to deliver from 000 to 999. The electronic counter accumulates a count every time if it is controlled by a square pulse that is sent to output 3196 of the monostable multivibrator 319 appears. This pulse arrives at the input terminal 341a of the ones stage 341.

The units, tens and hundreds continue to have their respective input connections in stages 341, 342 and 343 coupled input means are provided which have adjustable thumbwheel switch assemblies connected to the control panel 13 of the document processing device 10 (see Fig. 1) are arranged. The thumb wheel switches 344 (ones), 343 (tens) and 346 (hundreds) are each marked with a on the monitoring panel of the so Receipt processing device 10 provided visible dial to a visual display of the position of each the thumbwheels for counting any decimal number from 000 to 999. The mrchanical Arrangement of the thumb wheels and number wheels are not for the sake of clarity The mechanical thumbwheel switch can be used on each of the input lines, for example so on lines 344a to 344c / of the one-digit thumbwheel switch, selectively a high voltage level can be supplied, this being applied to the relevant Leads to the relevant input connections of the unit counter and comparator 341

Thumbwheel switches 344-346 provide outputs in the form of a "complement of nine" whichever is required electrical connection of the electronic meter is significantly simplified, which will be discussed in more detail below will be.

The value of each decimal digit in the nine's complement is effectively derived from the decimal size "9" subtracted and a binary-coded decimal number "9" is a decimal number in the form of the nine's complement 9, which is interpreted as a binary-coded decimal zero. The binary coded decimal form of the decimal number 9 is 100], where the evaluation of the binary digits from left to right is "8", "4", "2" and "1"

The operation of the electronic counter 340 is based on the fact that the thumbwheel switches 344 to 346 so be set so that the number wheels concerned (Fig.4c) indicate the desired lot size. But the shading between the thumbwheel switches and the inputs of the units, tens and Hundreds 341 to 343 based on the binary-coded decimal and nine's complement form for example, assume a batch size of 50 sheets. In this case, the thumbwheels will be like this set so that the display shows the decimal number 050 The electronic counter stages 341 to 343 for the units, tens and hundreds input levels then have the binary-coded decimal and nine's complement form and give 1001, 0100 and 1001, respectively, with the leftmost Digit of every binary-coded decimal group is the most important binary bit position

Using the nine's complement form reduces the number of output connections on each of the electronic counter stages to two (2) output levels per counter, namely the decimal eight or the decimal one output. In the ones level, the decimal eight and the decimal one output are the Connections 341 6 or 341c, and the hundreds outputs are accordingly with 3426 and 342c or with 3436 and 343c.

The output of each counter stage is in binary coded decimal and nine's complement form 1001, which in the simple binary-coded decimal form corresponds to a display 0000 binary coded decimal form (BCD) a connection of all four output stages with the peripheral logic circuitry require, whereas in the arrangement according to the invention only two for each stage Output connections for sensing the nine's complement state decimal "9" are required.

The outputs 3426 and 342d in the tens stage 342 and the outputs 3436 and 343c / in the hundreds output stage 343 are all connected to the relevant input connections of a NAND element 349 which provides an output when the binary coded decimal nine's complement output of each of the Stages 342 and 343 are present simultaneously in the form 1001. This output is in an inverter 350 conversely, the output terminal 350a of which is connected to the input line 351 shown in FIG. This figure is a basic circuit diagram in which the various switches and Other operating devices are shown, which are shown on the control panel 13 of FIG. 1 are provided.

The input line 351 is connected to a fixed terminal 352a of a switch 352 for batch processing and statistical sampling also placed a second fixed connection 3526 and one movable switching arm 352c has the movable switching arm 352c against the fixed contact 352a on, the high output of the inverter 350 via line 353 becomes the one at a time Input terminal of each of the in FIG. 4d illustrated

th NAND gates 354, 355 and 356.

The other input terminals of the NlCHT NAND gate 354 are connected to the decimal "8" output 341 of the b Einerzählstufe 341 (F i g. 4b) and connected to the output 316a of the NOR gate 316, which together with the NOR gate 317 forms the one-step filter circuit (SS filter) (FIG. 4a). The NAND gate 354 provides an output at 354a which is low when all three inputs are high, indicating that the ones stage of the electronic counter has reached a decimal "8" state that the tens and the hundreds each have reached a decimal "9" state and that the output of NOR gate 316 is high, which in turn indicates that the leading edge of the 49th sheet was felt. This output is fed to NOR gate 324 (Figure 4a) which provides a high output when the output of inverter 323 and NAND gate 354 are low. This state is reversed by the inverter 325, so that a lower input level appears at the NOR gate 380 of FIG . The special features of the actuation of the electromagnetic brake and the clutch device depending on the mode of operation of the logic circuit structure of FIG. 4a will have to come back in the following.

The other inputs of the NAND gate 355 are connected to the decimal "8" output 341 6 of the electronic One counting stage 341 or to the output 317a of the NOT-OR element 317 of FIG. 4a laid and that Element delivers a lower output level when the tens and hundreds counters are each in the Are in a decimal "9" state when the ones step output 3416 is high (indicating a decimal "8") and when the output of NOR gate 317 is high (which in the absence of a receipt the case is). This low level output becomes one input of a NOR gate 357 fed, which is cross-coupled with a NOR gate 358, so that a flip-flop (gate FF) is formed. The output terminal 357a of the NOR gate 357 is connected to the one input terminal of the NOR gate 358, while the output terminal 358a of the NOR gate 358 is connected to the other input terminal of the NOR gate 357. The remaining entrances of the NOR element 358 are connected to the start switch 385 or via elements 373 and 374 (FIG. 4e). with line 361 of FIG. 4c connected to the fixed terminal 362a of a switch 362 for the statistical sampling is placed, which also has a movable switching arm 3626 and a fixed Has contact 362c (see FIG. 4c). The movable switch arm 3626 is connected to a grounded bus line 363 placed so that the associated input of the NOT-AND gate 355 in the mode of operation of the statistical Sampling can be kept at ground potential (i.e. at a low level). The movable one Switch arm 362ft is with the movable switch arm 3646 of a party switch 364, which also includes fixed contacts 364a and 364c. The through the Blocking indicated by dashed line 365 is such that both arms are each in the same position occupy, and if so one of the switching arms (for example, the switching arm 3626) in the upper Position against the fixed contact (here: 362c), the other switching arm (in this case the Switching arm 3646) against the upper fixed contact (364c).

So if the document processing device works in the statistical sampling mode, so the NAND gate 355 provides a low output when the hundreds and tens both are in the decimal "9" state if the

ίο One level is in the decimal »8« state and if the output of NOR gate 317 is high, indicating the absence of a receipt whereby a low level input appears at NOR gate 357. This causes that the output 358a of the NOR gate 358 assumes the low value, whereby the NOR gate 412 of FIG. 4f, which supplies a gate signal in a manner yet to be described, is an input is supplied at a low level.

The process of completing the game is that the output of the NOT-AND element 356 assumes the lower value when the units counter 341 is in the decimal "9" state and when the tens and hundreds are also in the decimal " 9 «state, whereby a low level appears at the input of the NOR element 366, the other input of which is connected to the output terminal 321 i of the inverter 321 (see FIG. 4a), at which a high output appears as long as the The output of the OR gate 366 assumes the high value and is reversed by an inverter 367, whereupon an output with a low level appears on a line 368, which goes to the fixed contact 364c of the party switch 364. If this switch is in the closed position, the output with a low level via the switch arm 3646 and the line 369 becomes the one input of a NOR element 376 in FIG. 4e, which in conjunction with a NOR gate 357 as a running flip-flop to control the electromagnetic clutch device 131, the electromagnetic brake 137, de; Motor M and an indicator lamp 389 functions, as will be described in more detail.

An AND gate 370 and an inverter 372 are connected with their input connections to the output connection 321a (see FIG. 4a). The output of the inverter! 372 goes to the base electrode of a transistor Q 5 and normally keeps transistor Q 5 non-conductive

so state until the delivery inhibition delay circuit 320 has expired, whereupon the output of inverter 321 assumes the low value, so that inverter 372 delivers a high output, as a result of which transistor Q 5 becomes conductive. The collector electrode of the transistor is placed on the Leituni 390a of Figure 4c, so that a Förderhem tion indicator lamp 391 lights up

The other input connection of the AND element 37 (is connected to the output connection 376a of the NOT-OR element 376 at which a lower output appears when the start button of the control unit is pressed. If the start button has been pressed, then the output of the AND element is 370 high, whereby the output of the inverter 371 assumes the low value and a transistor Q 6 changes into the non-conductive state. The collector output of the transistor Q 6 is via the line 388 with the indicator lamp 389 of FIG

Part completion connected, whereby this lamp goes out if a part was not completed.

One input terminal of the NAND gate 393 of FIG. 4d is connected to line 361 of FIG. 4c placed, in turn with the switch 362 for the statistical sampling is connected. A second lead is via an inverter 394 to the output of the NAND gate 356 connected, while a third lead to the output 317a of the NOT-OR gate 317 (see F i g. 4a) is placed, so that a negative going output is generated when on the one hand the counting pulse is high, so what means that there is no document in the counting area of the flap 201 if, furthermore, all stages of the electronic counter are in the decimal "9" state and when the sample selector switch is in the upper position Switch position is brought. This negative going signal becomes the input port of a monostable Multivibrators 397 supplied, whereupon a negative pulse is generated.

The output of the NAND gate 356 is fed to one input terminal of an OR gate 366 and at the same time to an inverter 394. The output of the OR gate 366 goes to an inverter 367, the output of which is fed to the game switch 364 and (in the upper switch position of the game switch 364) via the line 369 to one input terminal of the NOR gate 376, which results in that the AND gate 370 is switched to the high state, whereby the transistor Q 6 goes into the conductive state, so that the indicator lamp 389 lights up, which indicates the completion of a batch.

If all of the inputs appearing on the NAND gate 393 are high, the negative one will be Pulse fed to the monostable multivibrator 397, which acts as a pulse spreading element, whereupon a Output pulse which goes to one input terminal of the NOR gate 373 of FIG serves a purpose to which we shall return.

The NOR element 373 is shown in FIG. the one with one input connection to the output connection 397a of the monostable multivibrator 397 (see FIG. 4d), while the other input connection is connected to the line 398 of FIG. 4c is connected, which is connected to the fixed contact 385a of a start switch 385, which also a movable switch arm 385c / contains. This is a momentary switching device that can be depressed to close the switch arm 3856. However, if the button is released, so the switching arm 385t is released from the fixed contact 385a, since for this purpose a (for reasons of Clarity not shown) loading organ is provided by this depression of the Start switch appears in the input of the NOR gate 373 a low level, so that its output the assumes a high value, whereupon this condition is reversed by the inverter 374, so that the an input of the NOR gate 375 assumes a low value forms a bistable multivibrator (run flip-flop) in cross-coupling with the NOR gate 376. Of the Output of inverter 374 also appears on line 359 of FIG. 4b.

Depression of the start switch causes the setting of the thumbwheel switches 344 to 346 to be transferred to the electronic counter 340, as will be explained in more detail below. If the input of the NOR gate 375 assumes the low value, a high value appears as the output, whereby a high input level is impressed on one input terminal of the NOR gate 376, the output of which assumes a low value when there is no halt state given is. The high output of the NOR gate 375 is fed to an input terminal of a NAND gate 379, the remaining input terminals of which to the start switch 385 or to the output terminal of one with a NOR gate 378 in the form of a second flip-flop (Stop flip-flop) cross-coupled NOR gate 377 are placed. The outputs of the NOR gates 375 and 377 are both high when the counter is running and the start switch has been depressed and then released, whereupon the output of the NOR gate 379 assumes a low value which is now a NOR gate 381 is received so that its output assumes a high value, whereby a transistor Q 7 changes over to the conductive state. As a result, an electromagnetic coil K \ is excited, with the result that the switching arm 402a of a switch 402 is folded over against a fixed contact 4026. The switching arm 402a is electromagnetically coupled to the solenoid K 1, as indicated by the dashed line 403 which regulates the percentage of each half cycle of an alternating voltage curve to be fed to a bridge rectifier 462 for generating a direct current output, connected to an alternating current source 404

The NAND element 407 (FIG. 4d) has the function of energizing the motor M , which is controlled by the presence of a document under the sensor, provided there is no conveyance inhibition. This ensures that every document is ejected in the flow when the Stop button is pressed and when the document is the last in a batch The NAND element 407 has the lower value and keeps the relay Ki energized as long as there is no delivery inhibition state (321a, FIG. 4a) and a document passes the sensor

The NAND gate 381 also energizes the relay KX when either the start button is pressed or when the run flip-flop is turned on or when the stop flip-flop is turned off (ie, reset).

The output of NOR gate 380 goes high when one of its inputs is low, causing the inverter 382 and the emitter electrode of a transistor <? 8 a high input level is received Whenever the document processing device is not in the running state or in the

ω is "stop" state or when the delay circuit to prevent a delivery inhibition has expired so its output assumes a high value, whereby the transistors QS and <? 9 are excited, so that the electromagnetic brake 137 shown in Fig. 2 receives an excitation signal

The output of the inverter 382 is fed to the base electrode of a transistor Q 10 which, together with a transistor QU, is used to actuate the electroma-

-magnetic clutch is energized 131 when the output of inverter 382 becomes the high value, as an inverse function of the logical command for energizing the transistors Q8 and Q occurs. 9

In Fig. 4f, a NAND element 410 is shown, which has one of its connections to the line 411 of FIG. 4c is placed, which is guided to the movable switching arm 412b of a switch 412t /, which has fixed contacts 412a and 412c is applied. The other input terminal of the NAND gate 410 is connected to the switching arm 3836 of a switch 383 which, in the normal state, bears against the upper fixed contact 383a, whereby the output of the NAND gate 410 assumes the low value when both inputs are high are (in the normal state and in the stacked state). This low value is fed to one input terminal of a NOR gate 412, the output of which has a high value as long as one of its inputs remains low, thereby driving a transistor Qi2 into the conductive state. As a result, a coil K 2 is excited, with the result that the switching arm 413a, which is magnetically coupled to the coil K 2 in the manner indicated by the dashed line 414, allows a base level potential to appear on the output line 415 for the flap 201, whereby the relay 204 is excited (see FIG. 1 a), the armature of which is mechanically connected to the flap 201 so that the flap is guided into the position in which the documents are fed to the stacker 80. A Zener diode CÄ 7 is used to suppress excessive back EMF when the contacts of the relay F1 are subsequently opened.

In FIG. 4f, an inverter 416 is also shown, the input connection of which is connected to the switch 383, the input being low in the operating state of statistical sampling, so that one input connection of a NOR gate 417 has a high input, the other input connection to the Line 419 of FIG. 4c, which in turn is routed to the fixed contact 362a of the switch 362 for statistical sampling, which delivers a high value when the switch arm 3626 is turned to the side of the upper fixed contact 362c, whereby the output of the NAND element 417 is low Assumes value so that the excitation of the relay coil K 2 is maintained

It is now back to FIG. 4c, the adjustable thumbwheel switches 344-346 are shown, the setting of the respective number wheel with a hand-operated thumb wheel 344a to 346a are provided so that on the windows 3446 to 3466 (for the ones, tens and Hundreds) any decimal number can be set. The setting value is shown in FIG. 4c as an example 050 is shown, which means a count value of "50" in batch processing or in statistical sampling means every game then contains 50 sheets or every 50th sheet for the statistical one Sample taken.

An electromagnetic counter 426 is also provided on the monitoring panel, which at any time displays the count value for intermediate counting or for continuous counting. The pulse input 426a is applied to the emitter electrode of the transistor Q 4 shown in FIG. 4a. A stop switch 387, which has a switch arm 3876 and a fixed contact 387a, is also provided on the control panel. In addition, a continuation switch 386 with a movable switching arm 3866 and a fixed contact 386a is also provided.

The different modes of operation will now be described.

Assume that a large number of sheets

ίο should be counted. The switch 383 is in the upper position Brought one position in which it rests against the fixed contact 383a for normal operation. The switch arm 4126 is in the lower switch position, in which it rests against the fixed contact 412c, which is the Indicates batch operation.

If the current is initially switched on, the delivery inhibition delay circuit 320 expires and goes into the "delivery inhibition" state, whereby the delivery inhibition indicator lamp 391 is switched on and the running flip-flop (FIG. 4e) via the inverter 321, the OR gate 366 and the inverter 367 (Fig. 4d) to the NOR gate 376 is reset. In the reset state, the running flip-flop keeps the motor M switched off (via the elements 379 and 381 as well as the transistor Q 7 in FIG. 4e) and also keeps the electromagnetic brake 137 supplied with power (namely via the NOR Member 380 and the transistor QS of FIG. 4e) and the coupling device 131 without current (via the inverter 382 and the transistor Q 10 of FIG. 4e).

In normal operation, the start switch 385 is pressed and released again, so that the switching arm 3856 is guided against the fixed contact 385a, whereby one input connection of the NOR gate 373 shown in FIG. 4e has a low-level input. This has the consequence that the output of the NOR gate 375 assumes the high value, whereby the bistable flip-flop (running flip-flop) consisting of the NOR gates 375 and 376 for the "run" - State is provided. The stop flip-flop (Fig.4e) is reset at the same time. The start switch 385 also releases the delay circuit 320 via the NAND element 318 (FIG. 4a) and the motor drive via the elements 379 and 381 and the transistor Q 7 (FIG Running flip-flop is set via the NOR gate 380, the inverter 382 and the transistors Q10 and QU, the clutch device 131 is excited while the electromagnetic brake 137 via the NOR gate 380 and the transistors QS and Q 9 is de-excited. After the start switch 385 has been released, the second input of the NAND gate 379 assumes the high value. In the "running" state, the output of the NOR gate 377 is high (see Fig. 4a), so that the three inputs of the NAND gate 379 are high, whereby its output assumes the low value This causes the output of the NOR gate 381 to go high, thereby driving the transistor Q 7 into the conductive state. As a result, the relay coil Kl is excited, whereby the motor M for commissioning via the switch 402 (which is now closed) to the

AC power source is turned on. When going through of each of the separate documents by the accelerating wheels 60 (see Fig. 1) becomes the photosensitive transistor 72 energized so that in the

described manner a count takes place. The counting pulses appear at the output terminal 319c of the monostable multivibrator 319 shown in FIG. 3 and 4a performs the functions of an automatic setting of the desired threshold value and the prevention of a misinterpretation of tears, slits, punched holes or perforations in a document as supposed "funding gaps". If a document passes transistor 72, the light value is reduced, which has the consequence that the detector (Fig. 3) produces a low-level output which is fed to the capacitor C2 (Fig. 4a) which filters out motor-generated noise in the signal which is then transmitted via the NAND gate 313 and the inverter 314 for setting the integrating one-step filter (SS filter, FIG. 4a) is passed on, which serves to prevent the misinterpretation of holes or damaged areas in the documents as supposed "funding gaps". The output of the integrating one-step filter is fed to the monostable multivibrator 319, the output 319c of which is fed to the transistors Q 3 and Q 4 , which act as level translators and current amplifiers for controlling the counter 426 (FIG. 4c).

The delivery inhibition delay circuit 320 and the delay circuit 330 for preventing a delivery inhibition cannot expire as long as the time interval between the detection of delivery gaps does not exceed the blocking time setting of these circuits , which can be found on line 430 of FIG. 4c has an effect In the normal operating state, the movable switching arm 3646 is folded over against the lower fixed contact 364a, whereby this signal state via the line 369 for transferring the bistable flip-flop consisting of the NOR gates 375 and 376 to the blocking state of one input terminal of the NOR gate 376 of FIG. 4e is fed, so that the output of the NOR gate 375 assumes the low value, with the result that the output of the NAND gate 379 assumes the high value the output of the NAND gate 407 (see FIG. 4d) also has the high value, whereby the output of the NOR gate 381 assumes the low value, so that the transistor Q 7 is controlled and in the non-conductive state the motor control circuit is de-energized by opening contacts 402a and 4026. In addition, the running flip-flop (FIG. 4e) is reset, the counting is blocked by the NAND gate 313 (FIG. 4a) and the delivery inhibition indicator lamp 391 lights up.

The inverter 321 and the NAND element 313 (FIG. 4a) form together with the elements 314, 317 and 318 a lock that maintains the conveyance inhibition level when the receipts are removed and which also prevents the receipt detector from being used at the eo Setting to the lower (darkened) light value generates incorrect counting pulses

The counting process continues as long as beige is given into the input magazine 14 (FIG. 1). The receipt processing apparatus can be brought to a standstill on any occasion by depressing the stop switch 387, whereby the ground potential is applied to one input terminal of the NOR gate 378 via the movable contact 3876 and the fixed contact 387a. Here, the output of this element assumes a high value, so that the output of the NOR element 377 assumes the lower value, which in turn has the consequence that the NAND element 379 delivers a high output, whereby the stop Flip-flop is put. This signal state, in conjunction with the high output of the NAND gate 407 (see FIG. 4d), causes the NOR gate 381 to provide a low output, thereby disconnecting the motor M from the AC power source. The output of the NOR gate 377 is also fed to the NOR gate 380, so that its output assumes a high value, whereby the brake is energized and the clutch is de-energized. This prevents further conveyance of documents in the document processing device which have been detected by the gripping wheel, drive wheel or stripping wheel arrangement. At the same time, the brake is actuated to abruptly stop the gripping, driving and stripping wheels. By pressing the continue button or the stop button, the stop flip-flop (Fig. 4e) is reset.

The following describes the processes involved in statistical sampling.

The switch arm 412 £> is in the switch position "Discard" brought, the switch arm 360 £> in the "statistical sampling" position and the switch arm 352c in the position "batch processing / statistical sampling".

The thumb wheels are adjusted so that the number wheels are the size of the desired lot Show. In Figure 4c is an example of a setting in which each lot contains 50 sheets.

The start button is pressed. The number set on the thumbwheel switches is changed as a result of the grounding state caused by the depression of the start switch in the electronic counter 340 entered and is fed through the N ICHT-OR gate 373 (whose output assumes a high value), so that a low level appears at the output of the inverter 374, whereby the inputs 341c to 343c of the Counter steps 341 to 343 assume lower values and thereby the entry of the setting of the thumbwheel switch takes place in the electronic meter

The release of the start switch 385 causes a lower value to appear in the output of the NAND gate 379, whereby the output of the NOR gate 381 assumes the high value, whereupon the motor M is supplied with current.

The setting of the switches 364, 362, 383 and 352 has the consequence that the NAND gates 410 and 417 (FIG. 4f) deliver high levels which appear at the inputs of the NOR gate 412, at its other input high quiescent level appears (output 358a of the NOR gate 358, FIG. 4d> The output of the NOR gate 412 is low, whereby the transistor QU is switched to the non-conductive state, so that the relay K 2 is de-energized The relay 204 can therefore, under the action of the force of the loading means, execute a movement in the direction of the position indicated in broken lines, so that the documents via the belts 207 and 208 (FIG. 1 a) are discarded.

If the tens and hundreds of the counter are in the decimal »9« stateH nnH has Hi «· Finprctnfi»

reaches the decimal "8" state, and _{if the state of the counting pulse / M} indicates that the output of the NAND element 355 in FIG. 4d assumes the lower value, there is no evidence in the area of the relay 204 present, so that the output of the NOR gate 358 (which composed of the NOR gates 357 and 358 flip-flop forms the half of) the lower value assumes This level appears at one input of the NOR gate 412 , whereupon its output assumes the high value, so that the transistor <? 12 is energized, thereby supplying current to relay 204 , which is now the one shown in FIG. 1 a assumes the position shown in solid lines, so that the sheet removed as a sample is fed to the stacker 80.

Immediately before the guide flap is pivoted into the position shown in FIG. la reproduced in solid lines The sheet selected as a sample is positioned by actuating the clutch and brake devices slows down when the units level of the electronic counter has a count value of decimal "8" This signal state is reached via element 354 (FIG. 4d), elements 324 and 325 (FIG. 4a) and the NOT-OR gate 380 (Fi g. 4e) for actuating the Brake and clutch devices 137 and 131 weitergeieitet, through which now that as statistical Sample selected sheet is slowed down to allow sufficient time for the execution of the Swivel movement of the guide flap is available.

This pulse is taken from the leading edge of the slip preceding the statistical sample (i.e., the 49th receipt) and is triggered for the full duration of this receipt between the light source 65 and transistor 72 effective.

After the trailing edge of the document preceding the statistical sample has passed (ie the 49th document), the high value appears in the output of the NAND element 354, whereby the clutch and brake devices are actuated. When the gap appears between the rear edge of the 49th document and the front edge of the 50th document, the guide flap is set. As soon as this pulse ends and before the electronic counter advances by one count, the NAND element 355 (FIG. 4d) sets the guide flap flip-flop (i.e. the NOR elements 357 and 358) to excite the electromagnetic coil K2 (see Fig.4f), whereby the guide flap is brought into the position shown in Fig. La in solid lines. After counting the gap at the trailing edge of the document selected as the statistical sample, the output of the NAND gate 356 assumes the lower value, which enables the NAND gate 393 (see FIG. 4d) to use the monostable To operate the multivibrator 397 to generate a reset pulse for the statistical sampling, so that one input of the NOT OR element 373 receives a low-running pulse, whereupon a low-running pulse appears at the output of the inverter 374 and goes to the input terminals 341c, 342c and 343c , whereby the processing of the following document group is prepared by the relevant counters.

The documents following the document selected as a statistical sample are again included in the documents shown in FIG Shelf 215 shown promoted until the count in the same way as before until the next dusty sampling has progressed.

In batch processing, the movable switch 3646 is folded over to the side of the fixed contact 364 ( The shutter arm 352c rests against the fixed contact 352a and the thumbwheel switches are set based on the batch size concerned
Depression of the start button causes the count selected by thumbwheel switches 344 to 346 to be transmitted over line 359 to the electronic counter. The engine is brought into a ready-to-start state in the same way as before

ίο brought, but does not start until the start button is released. This measure ensures that the count value of the thumbwheel switches 344 to 346 (FIG. 4c) is transferred to the electronic counter before the device begins to work. If the start button is released, the input line is no longer occupied and the electronic counter can now counting. While the receipts are being transported past the transistor 72, the non-stable multivibrator 319 (FIG. 4a) receives the counting pulses, whereby the counting value of the electronic counter 340 increases

In the batch processing mode of operation, the decoders 349, 355 and 356 can operate. If a count "999" appears, the running flip-flop (FIG. 4e) is reset to interrupt the flow of documents and to switch on the indicator lamp 389 (FIG. 4c). The NOT-OR gate 381 (Figure 4e) enables the operation of the motor M as long as there is still a document under the transistor 72 (Figure 3) and as long as the delivery inhibition delay circuit 320 is not put into operation last receipt guaranteed when a batch is processed or when the stop button is pressed.

The documents are separated from one another, counted and stacked in the stacker 80 (see FIG. 1) until the 50th. Document is determined. This turns the NAND element 356 (FIG. 4d) into an operational one Brought state, whereupon the OR gate 366 a

• capable of delivering high output through the Inverter 367 is reversed. The low output of the inverter 367 is via the switch 364 the Input connection of the NOT OR gate 376 (Fig.4e), whereby the members 370 and 371 and the transistor Q 6 (FIG. 4d) for switching on the indicator lamp 389 are put into operation, which indicates the completion of a game. At the same time, the output of the NOR gate 375 takes place (Fig.4e) the lower value, whereupon the output

so the NAND gate 379 assumes the high value and the output of the NOR gate 381 assumes the low value, so that the transistor Q7 is de-energized and the motor M is switched off from the current source.

Simultaneously with this, the NAND gate 356 transmits, if it is in the operational state, a stop condition via the OR gate 366 and the inverter 367 (FIG. 4d) and via the switch 364 the one input connection of the NOR gate 376, whereby the clutch and brake device

w) are operated.

The finished batch can then be removed from the stacker 80, whereupon the start button for Initiate counting and stacking of the next batch is pressed.

The devices provided to protect against funding restrictions speak to an impending one Blockicrstatus on, so that a protection of the device is guaranteed, which takes effect before a

Funding inhibition has serious consequences

The production inhibition delay circuit 320 of FIG. 4a locks only for the duration of a time interval which is shorter than the normal time period between the palpation of two conveyor gaps, so that the NAND gate 313 (4a) entering other counts in the circuit 310 prevents the output is also the Switch 364 on the control panel (FIG. 4c) is supplied so that a stop signal is generated which is sent to the NOR gate 376 (FIG. 4e) and causes the NOR gates 375 to do so and 376 existing flip-flop is flipped, as a result of which the brake and clutch devices are excited via the members 380 and 382 and the transistors QS, Q 9 and <? 10, Q II. At the same time, the output of the inverter 321 (FIG. 4a) is fed into the line 390 of FIG. 4c via the inverter 372 and the transistor ζ> 5 (FIG. 4d), so that the delivery inhibition indicator lamp 391 lights up. Resetting the flip-flop consisting of the NOR gates 375 and 376 also causes the NAND gate 379 (FIG. 4e) to provide a high output. If the other input of the NOR element 381 is high, which is the case when the NOR element 407 (FIG. 4d) receives a lower input level from the inverter 321 , the NOR element 381 supplies one low output, whereby the motor / Vf is switched off from the power source, since the switching arms 402a and 4026 open due to the de-energization of the relay solenoid K I.

The delay circuit 330 for preventing a delivery inhibition, the limit time of which is somewhat shorter, runs down and causes the transistor (? 2 to go into the non-conductive state. This high level is reversed by the inverter 323, so that the NOR gate 324 a low input is approached, whereupon its output assumes a high value. This state is reversed by the inverter 325, whose output now assumes the lower value. This value appears at one input of the NOR gate 380 (Fig. 4e), are actuated so that the clutch and brake devices in the manner already described, so that a possible conveyor inhibition is prevented. the delay circuit 330 for preventing a conveying inhibition has a shorter lock time than the conveying inhibition delay circuit 320 so that the clutch and brake devices, an impending delivery inhibition The delay in funding • 5 works in this way far beyond that, when it de-energizes the motor M , which is thus brought to a standstill.

From the above description it can be seen that the invention provides a control device for document processing devices and the like which enables sheets or other documents to be processed while preventing more than one document from simultaneously using the drive and stripping means runs through, whereby the presence of a suitable for counting purposes distance between the separate documents is ensured, the functions of the control device extending to a count of documents in small or large numbers, a count of document groups of any specified partial size and to enable the counting of documents with retention of statistical samples of the counted documents, whereby precautions are taken to protect the device against damage caused by delay by anticipating an impending delay.

r> tion and to protect by immediate decommissioning of the document processing device, and where a Warning display in the form of a lamp (and / or, if desired, an acoustic warning device) is provided to the operator

in, if necessary, a possible state of suspension of funding to draw attention.

The electronics of the control system are also capable of sensing the separating distance between the Receipts counting pulses before they enter the stacker

π supply, with changes in the external influences that affect the sensitivity of the detector can be automatically compensated and prevents holes or damaged areas incorrectly in the receipts as "funding gaps" between

4 »different documents can be interpreted. The circuit 310 of FIG. 4a is constructed in such a way that an incorrect response in the case of the presence of defective points or other holes in the back between the lamp and the light-sensitive transistor.

4) carried out document, which in the conveying direction a Opening width up to 19 mm is prevented.

For this 8UhUt drawings

809 583/1 «R

Claims (1)

Patent claims: 3. Means for counting documents by the detection of a gap of at least a minimum duration between adjacent documents advancing in a first direction and spaced apart, the gaps serving to facilitate the counting of the documents and through the trailing edge of a document as well the leading edge of the next document are defined, with a light source located on one side of the path of movement of the spaced documents, with light-sensitive devices located on the opposite side of the path of movement for receiving light of maximum intensity from the light source when the trailing edge of a document is the Light source and the photosensitive devices happened, and for receiving light with lower intensity when a document is between the light source and the photosensitive devices, with threshold value setting devices for setting a before given threshold level, and with comparing devices for comparing the output level of the light-sensitive devices with the output level of the threshold value setting devices to generate a signal with a first level when the output of the light-sensitive devices is at least equal to the threshold level and with a second level when the threshold level is greater than the output level, the first level representing the presence of a gap, characterized in that the counting means delay devices (C3, R 6, CRl, Fig. 4a), which respond to the beginning of the gap level, by a delay period with a initiate predetermined interval, first logical link elements (315, F i g. 4a), which respond to the delay devices (C3, R 6, CR 1, Fig. 4a) and the change in the output signal of the comparator (304, Fig. 3) from the gap level to the remaining level in order to generate a counting pulse, and include second logic elements (316, 317, Fig. 4a) for preventing the generation of the counting pulse when the delay interval ends after the gap level has ceased, in order to ensure that gap intervals which are shorter than the predetermined interval are not erroneously interpreted as a valid counting pulse. 2. Device according to claim 1, characterized in that the delay device has a charge storage element (C3) and diode elements (CA 1) switched on between the first logic gates (315) and the charge storage element (C3) for fast charging of the charge storage element (C3) in the absence of a gap level at the output of the comparator (304) and t> o circuit elements (R 6) for limiting the discharge rate of the charge storage element (C3) when there is a gap level (FIG. 4a). 3. Device according to claim 1, characterized tr> by interference suppression elements (C1, R5, Fig.4a) coupled to the comparator (304, F i g. 3) to prevent the transmission of interference pulses as counting pulses. 4. Device according to claim 1, characterized by second delay devices (RS to R 10, CR 2, C4, F i g. 4a) for introducing a second interval at the end of the gap level and third logic elements (313, 321, Fig.4a) for Blocking of the first logic gates (315, FIG. 4a) in such a way that the generation of a counting pulse is prevented at the end of the second delay interval. 5. Device according to claim 4, characterized in that the second delay devices (R 8 to R 10) (CR 2, CA) are reset when each gap level occurs again (F i g. 4a) 6. Device according to claim 4, characterized in that the delay interval of the second delay device (RS to Ä10, CR 2, C4) is greater than the time which the longest document to be counted needs to pass through the photosensitive device, so that the second delay device is normally reset by the reappearance of each successive gap level before the delay interval has expired (Fig. 4a). 7. Device according to claim 1, characterized in that the threshold value setting devices Devices (303, C1, R 3, R 4) for setting the welding value level as a function of the output signal strength of the light-sensitive devices (72) includes such that component aging and other environmental operating conditions are compensated (Fig. 3). 8. Device according to claim 2, characterized in that the charge storage element is a Capacitor (C3) is (Fig. 4a). 9. Device according to one of the preceding claims, characterized in that the second logic elements (316, 317, Fig.4a) form a bistable circuit with a first and second input terminal and an output terminal, of which the first input terminal for generating a first output level on The output connection of the bistable circuit is connected to the output of the comparator (304, FIG. 3) each time the leading edge of a document is guided past the light-sensitive device (72, FIG. 3) and that the first logic elements are a logic element (315, FIG. 4a ) with two input connections and one output connection, of which one input connection is connected to the output (316a, FIG. 4a) of the bistable circuit, while the other input connection is connected to the output of the comparator (304, FIG. 3), and wherein the output terminal via the parallel connection of a resistor and one for a high output level in Forward-biased diode (CR 1, FIG. 4a) with the second input connection of the bistable circuit and with one connection of a capacitor (C3, FIG. 4a) connected to ground. 4a) is connected