DE1233630B - Pulse generator for evaluating card or strip-shaped recording media - Google Patents

Description

Pulse generator for evaluating card or strip-shaped recording media In order to scan card-shaped recording media, it is often necessary to be synchronous to generate clock pulses for card movement, for example for controlling column by column Scanning operations are used in punch card scanners.

The scanning of punch cards usually takes place in lines or column by column. For the following explanation it is irrelevant whether a punch card is scanned line by line or column by column, it is therefore only scanned column by column Scanning is referred to. In the case of a line-by-line scanning, there would only be the terms "columns" and "rows" in the following description against each other to exchange.

In principle, there are three methods of clock generation synchronized with the card run known: the first time the card is stretched onto a sled or cart, which, like the clock generator, is driven in a manner specified by the machine will. Such arrangements are only possible for relatively low card throughputs. In the second method, the recording medium is driven by friction rollers or drivers approximately or exactly in sync with the running of the machine, with that of the clock generator is coupled, driven. A third procedure, which according to the current status the technology alone leads to the goal with high card throughput, consists in to drive the recording medium in a non-positive manner by friction rollers and to generate the clock to be controlled by the movement of the recording medium itself. The last Method has been implemented in particular with light-sensitive scanning means, those in a number which is the number of those taking place one after the other for each record carrier Scans corresponds to, and at a distance,; that by the column spacing the information perforations is determined, are arranged. These photosensitive Scanning elements are covered one after the other by the leading edge of the punch card or released by their rear edge. They are usually, each for connected to a differentiator. In this way one pulse at a time caused when one of the light-sensitive organs is covered or exposed will. On the one hand, such an arrangement requires a considerable amount of circuitry, on the other hand, they function perfectly due to the constantly accumulating paper dust questioned. Furthermore, it prepares the different light transmittance of the recording medium - in particular because of the differentiation of signals emitted by the sensing means - certain difficulties because of the recording media may be printed or have grease stains.

The invention is therefore primarily intended to create a clock generator which also realizes a clock generation controlled by the card edge, but it is cheap and reliable. The arrangement is with minor adjustments however, not only for clock generation, but also, for example, for scanning Information perforations in card- and strip-shaped recording media suitable.

The invention relates to a pulse generator for evaluating cards or strip-shaped recording medium by means of a gas jet which passes through a perforated plate provided with nozzle openings at defined points then passes through, if one is guided past the perforated plate, preferably at a continuous speed Release the recording medium or the markings made on it, nozzle openings.

The invention is characterized by at least one having the nozzle openings pneumatically coupled differentiating microphone, which by the release or interruption of the gas flow generated, rapidly decaying pressure pulses into electrical Converts signals.

The effect is therefore used, which occurs when opening in a jerky manner and closing of valves occurs in pipelines connected thereto. Included pressure waves arise, their frequency and amplitude depend on the pressure, the speed and the mass of the moving medium as well as the resonance properties of the pipe system depends.

In the arrangement explained in more detail below, for example by means of a fan, a gas flow is generated through a number of identical channels, the are temporarily closed or released by the recording medium. The recording medium thus takes on the function of the valve slide. By caused the sudden interruption or release of the gas flow, rapidly decaying Sound-like disturbance is - depending on the application - one or more Microphones converted into an electrical signal. Since this signal dies away quickly, thus does not exist as long as a gas flow occurs or does not occur Differentiators superfluous. The one described is also sufficient for a clock generator Kind of basically a single microphone. There is no paper dust Trouble. It is carried along by the flowing gas and can be filtered out if necessary will.

A dynamic microphone is particularly suitable as a microphone, since this has differentiating properties and therefore does not affect the static pressures appeals to.

The invention is illustrated below with reference to some of the figures Embodiments that introduce a clock generator explained in more detail.

F i g. 1 is a schematic overview representation of a clock generator for card-shaped recording media; F i g. 2 shows a detail of the clock generator the Fig.l; F i g. 3 shows a somewhat modified embodiment of a clock generator; F i g. 4 shows various gas flow channel shapes that can be used in such a clock generator with connection options for the microphone; F i g. 5 shows various usable Nozzle shapes.

According to the illustration of FIG. 1, a noise damper 3 is connected downstream of a blower 1 via a line 2 and is connected to a plate-like nozzle plate 5 via a number of individual lines 4. This has channels 8, for example in the form of round bores with a course perpendicular to the recording medium path. Opposite the nozzle plate 5 and parallel to it, a similar nozzle plate 7 is arranged at such a distance that a recording medium 6 can just be passed between them without forcing. The nozzle plates 5 and 7 have as many channels 8 and 9 as there are successive scanning processes for each recording medium. On the side facing the recording medium 6, the channels 8 and 9 (FIG. 4) each merge into a nozzle opening 10 and 11 , respectively, with the nozzle openings 10 and 11 facing each other in pairs. The channels 9 and 8 are each individually connected to one of the lines 4 and 12, respectively. The lines 12 are connected to a container 13 which surrounds a microphone 14. 15 is an outlet opening for the gas flow guided past the microphone 14.

The lines 12 are matched to one another in length and cross section so that the sound signals fed through them to the microphone 14 have the same transit time and otherwise have the same properties. The lines 4 as well as the lines 12 consist, for example, of plastic tubes.

The channels in the nozzle plates 5 and 7 are single or multi-row single or multiple column spacing of the recording medium 6, depending on how many Columns are each scanned simultaneously, arranged. That way delivers the microphone 14 clock signals synchronous with the movement of the recording medium 6, and one for each column scanning process.

The omission of the nozzle plate 7 is conceivable if the microphone, for example in the in F i g. 4c, on the upstream side of the recording medium is connected to the channels 8 of the nozzle plate 5.

In Fig. 2 shows a further embodiment for the nozzle plates. The reference numbers are largely the same as in FIG. 1. The nozzle plate 5 according to FIG. 2 does not have more as many individual channels as the nozzle plate 7, but an all nozzle orifices 11 of the nozzle plate 7 covering the groove 16 with the Geräuschd the like via a single line 4 damper 3 and the blower 1 is connected.

In a further modified embodiment according to FIG. 3 is not applicable the nozzle plate 5. A fan 1, which in this case is on the downstream side of the recording medium 6 is arranged, sucks through the channels 9 of the nozzle plate 7 and the connected thereto Lines 12, past the microphone 14, air directly from the surrounding space at. The recording medium 6 slides along the nozzle plate 7. Be there through its front or rear edge gradually the one behind the other Nozzle openings 11 covered or released. A silencer is expected in this Case can usually be dispensed with. If, however, it is not waived should, it would have to be arranged in the airway between the microphone 14 and the fan 1.

In Fig. 4 various connection options for the microphone 14 are shown. As the F i g. 4 b and 4 c show, the microphone can also be arranged outside the gas flow. It is then in acoustic connection via lines 17 (FIG. 4 b) or 18 (FIG. 4 c) with the channels 9 and 8 of the nozzle plates 7 and 5, respectively.

It must be mentioned again that, according to the principle described, sound signals are produced both during the interruption by the card leading edge and by the rear edge of the cards. In this context, however, it is important that when the gas flows at the microphone are interrupted, voltage pulses with a substantially negative amplitude are produced, while the release of the gas flows at the microphone produces voltage pulses with a predominantly positive amplitude. With sufficiently known filter means it is therefore not difficult to separate the different signals in order to use only one type of clock generation. This is particularly important when the individual record carriers within the scanning station follow one another at shorter intervals than their length corresponds to, since then in a certain range two types of timing grid, namely one from the trailing edge of the previous record carrier and the other through the The leading edge of the subsequent recording medium caused overlap. The mutual disturbance of the timing pattern originating from the beginning and end of the card, which could also be mutilated as a result of interference phenomena, can be eliminated even more reliably if two or more microphones are only connected to channels 9 and 8 of a specific section. During the passage of a card 6 in this case, for example by a counting circuit, after a certain number of clock pulses occur, the next microphone is switched to, which only provides clock pulses while the relevant card edge is in the area of the nozzle group assigned to it .

The following is the scanning of the information perforations on a punch card or a perforated tape on the basis of the stated principle. Are there the nozzle openings of the nozzle plates 5 and 7 in the direction of travel of the recording medium not one after the other, but depending on the number of simultaneously to be scanned Recording tracks (rows) arranged side by side. The number of intended Nozzle openings are equal to the number of lines on the recording medium or at Multi-deck punch cards equal to the number of lines of the deck to be scanned. Should several Columns are scanned simultaneously, so are corresponding sets of nozzle openings to be arranged one behind the other with the column spacing. Each nozzle opening has its own Microphone connected, as the spatial position of each hole for its information content matters.

By suitable shaping of the cross section of the nozzle openings Both for the clock generator and for the punch scanner are taken care of that decisive signals only during the switch-on process or during the switch-off process of the gas flow occur. This is made possible, for example, by the triangular shape of the nozzle cross-sections achieved (see FIG. F i g. 5 c), which causes the movement of the recording medium edge or the perforation is first quickly exposed a large cross-section while the constriction of the gas flow takes place only gradually or vice versa. Through this the amplitude of the sound signals is very different.

This is of particular importance for the scanning of holes, since as a result of the small width of the holes, which also hardly differs from one another and the webs between the holes switch the gas flows on and off follow each other very quickly and possibly at regular intervals and the Differentiating the signals therefore becomes difficult. In addition, the clock generator are caused in the same way that the from the leading edge of the record carrier caused signals in their amplitude significantly different from those caused by the rear Different edge caused because, for example, the leading edge is a very Sudden constriction of the gas flows caused while the trailing edge the gas flows able to release only gradually.

Claims (11)

Claims: 1. Pulse generator for evaluating card-shaped or strip-shaped Recording medium by means of a gas jet that passes through a defined location Perforated plate provided with nozzle openings then passes through when an on the perforated plate recording media conveyed past preferably at continuous speed or the markings on it release nozzle openings, marked by at least one differentiating element pneumatically coupled to the nozzle openings Microphone that generates the gas flow generated by the release or interruption of the gas flow, converts rapidly decaying pressure pulses into electrical signals. 2. Pulse generator according to claim 1, characterized in that the microphone (14) is on the downstream side of the recording medium (6) is arranged in the gas stream. 3. Pulse generator after Claim 1, characterized in that the microphone (14) is outside the gas flow arranged and connected by lines to the nozzle openings (10 or 11) stands. 4. Pulse generator according to one of the preceding claims, characterized in that the microphone (14) is a dynamic microphone. 5. Pulse generator according to one of the preceding claims, characterized in that the gas flow is a pressure stream. 6. Pulse generator according to one of claims 1 to 4, characterized characterized in that the gas flow is a suction flow. 7. Pulse generator according to one of the preceding claims, characterized by its use as a clock generator controlled by recording medium edges, and characterized in that the nozzle openings (10 or 11) at the intervals of the recording gaps of the recording medium (6) or their multiple corresponding intervals in the running direction of the recording medium (6) are arranged one behind the other so that their number corresponds at least to the number of scanning processes taking place per recording medium and that they are moreover so arranged that they cannot under any circumstances come into contact with information perforations on the recording medium (6). B. Pulse generator according to one of Claims 1 to 6, characterized by its use as a perforation scanner for perforated recording media and in that the nozzle openings (10 or 11) are positioned next to one another according to the distance and the number of hole tracks to be scanned simultaneously and according to the distance and the number of simultaneously perforated plates to be scanned are arranged one behind the other and that each nozzle opening (10 or 11) or each pair of opposing nozzle openings (10, 11) is connected to a microphone (14) . 9. Pulse generator according to one of the preceding claims, characterized in that the lines (12 or 17 or 18) leading to the microphone (s) (14) are matched to one another in length and cross section so that corresponding sound pulses upon arrival at the Microphone (14) have required the same running time and are otherwise identical to each other. 10. Pulse generator according to one of the preceding claims, characterized by nozzle openings (10, 11) with a cross-sectional shape which results in a progressive or degressive cross-sectional change over a path covered in the feed direction of the recording medium (6), depending on whether a useful signal from the cover or is to be derived from the release process of the nozzle openings (10, 11). 11. Pulse generator according to claim 7, characterized characterized in that seen in the transport direction several microphones one behind the other are provided, which corresponds to the forward movement of the recording medium then switched over when the leading edge of the recording medium is in Area of the microphones assigned channels (9) is located. Considered Publications: German Patent No. 80,519; German exposition no. 1007 091, 1030 213, 1076 415, 1085 948, 1144 959; French patent specification no. 1,334,791; British Patent No. 858,391; U.S. Patent No. 2,567,552.