DE1449572C - Flow-controlled comparison device for two perforated recording media - Google Patents

Description

The invention relates to a fluid-controlled comparison device for two perforated recording media, which with their holes at a scanning station provided for each recording medium opens the passage for a fluid in enable a scanning channel. Use known comparison devices for perforated recording media Light sources, light-sensitive devices and mirrors for directing a light beam through a hole to be scanned on both recording media. As a result of abrasion, the mirrors gather dust easily and make the work of such photoelectric comparison arrangements unsafe.

On the other hand, it is known to read the information perforated recording media scanning stations to use, in which the holes in the recording medium generate a pulse of fluid in one cause channel leading away from the scanning station.

The invention is based on the object of comparing the details of perforated recording media to be carried out with simple means and high operational reliability, with the mechanical Devices that are susceptible to failure and are bulky, the known logic fluid switching elements should be used without moving parts.

In order to achieve this object, the above-mentioned fluid-controlled comparison device is so designed that according to the invention of two monostable fluid amplifiera each with one Power input, a control input and two output channels, the power input of one Fluid amplifier and the control input of the other fluid amplifier with each a scanning channel are connected and that the fluid-carrying outlet channels in the stable state connected to one another lead to an error display device, while the other output channels are open in such a way that only with the simultaneous occurrence of fluid in the Sampling channels the fluid flowing into the fluid amplifier from the power input through the fluid entering at their control inlets to the open outlet channels is distracted.

This not only avoids the above-mentioned potential for malfunctions, but also this comparison device also has a much simpler structure, making it more reliable and inexpensive.

The invention is explained in more detail below with reference to the drawings using an exemplary embodiment. They represent:

1 shows the overall arrangement for comparing the perforations of two recording media,

F i g. 2 and 3 the design of the scanning devices.

According to FIG. 1, a fluid source 1 is connected to two scanning stations 3 and 5 via lines 19. A transport control mechanism 11 shown as a block affects the movement of two Recording media 13 and 15 by the scanning stations 3 and 5.

The recording media 13 and 15 have holes representing encrypted data.

The fluid source 1 continuously gives a flow via the lines 19 to the inlets 21 and 23 of scanning stations 3 and 5. The fluid source 1 can be a pump or a compressor his and includes a pressure regulator of known design, so that the flow at largely constant Pressure is given to the lines 19. The inputs 21 and 23 are directly above the Transport tracks of the recording media; they have essentially the same dimensions as those to be scanned Recording media, so that all possible holes in a row of the recording media can be scanned simultaneously.

As many channels lead away from each scanning station as there are holes in a row of the recording medium. Of these, FIG. 1 for the scanning station 3, a scanning channel 25 a with the opening 27 α shown, which is arranged so that the presence or. Absence of a hole at a single point on the recording medium 13 is scanned. Iii Similarly, the opening 27 is ό of the sensing channel 25 is disposed b to the presence or absence of a hole at a single point on the recording medium 15 to be scanned. The scanning channels 25 α and 25 b lead to power inputs 31 α and 31 b of two fluid amplifiers 29 α and 29 b, which are arranged in a block 7. In addition to the power input 31 α, the fluid amplifier 29 α has two output channels 33 α and 35 α and a control input 37 α.

The fluid amplifier 29 b has, in addition to the power input 31 b, two output channels 33 b and 35 b and a control input 37 6.

The scanning channel 25 α is connected to the power input 31a of the fluid amplifier 29 a and the control input 37 b of the fluid amplifier 29 b , while the scanning channel 25 b is connected to the power input 31 b of the fluid amplifier 29 b and the control input 37 α of the fluid amplifier 29 a. The output channels 35 α and 35 b can lead to the outside or can be connected to a flow return 39 of the fluid source 1 by means of channels 39 α and 39 b. The channels 33 a and 33 ft are connected to a common output channel 41 to which an error display 9 and the transport control mechanism 11 are connected.

The fluid amplifier 29 α and 29 b can in a known manner from plate-shaped! Material can be made, the channels being cut, etched or otherwise provided in one side of a plate, and this surface is then covered with a second plate.

A power jet applied to the power input 31 α of the fluid amplifier 29 α passes through an opening 43 α into a chamber 45 a. The cross section of the opening 43 a is smaller than the cross section of the power input 31 α, so that the power jet enters the chamber 45 α at high speed. The chamber 45 α is designed so that the power jet flows from the opening 43 a in the absence of a control jet from the control input 37 α through the chamber 45 α into the output channel 33 a. This can be achieved in that a divider 47 a is offset on one side of the path of the power beam and that the right corner of the opening 43 a is rounded.

If a power beam to the power input 31a and a control beam to the control input 37 α is given, the power jet flows into the output channel 35 α. The control jet placed at the control input 37 α enters the chamber 45 a and hits the power beam so that it is deflected to the left by the splitter 47 a and into the output channel 35 α flows.

The fluid amplifier 29 b operates in a similar manner. A power jet applied to the power input 316 emerges from the opening 43 b as a jet at high speed into a chamber 45 b, is deflected by a splitter 47 b and flows into the output channel 33 b when there is no control jet. If a flow control jet is applied to the control input 37 b, then the power jet is deflected into the output channel 35 b.

The recording media 13 and 15 are brought into the scanning position, and the fluid source 1 brings pressurized flow into inlets 21 and 23 of sampling stations 3 and 5. There are four possible states: the recording media 13 and 15 both have a hole; neither the record carrier 13 nor the recording medium 15 is provided with a hole; the recording medium 13 has a hole, the recording medium 15 has none, or the recording medium 15 has a hole, however the recording medium 13 has none.

First of all, it is assumed that neither of the two recording media contains a hole. In this Trap, the flow from the fluid source 1 reaches the inlets 21 and 23, but there there are no holes in the recording media 13 and 15, this flow cannot enter the Scanning channels 25 a and 25 6 occur. As a result, no flow signals are sent to the fluid amplifiers 29a and 296 given, and there is no flow in the exit channel.

In the second case, both recording media have a hole. From the fluid source 1 The flow passes through the line 19, inlet 21, the hole in the recording medium 13, the scanning channel .25 α into the power input 31 α and the control input

jo gang 37 b _: At the same time, the flow from the fluid source 1 flows through line 19, input 23, the hole in the recording medium 15,, scanning channel 25 b into the power input 31 b and the control input 37 a. Thus, the hole in the recording medium 13 results in a power jet in the fluid amplifier 29 α and a control jet in the fluid amplifier 29 b, while the hole in the recording medium 15 produces a power jet in the fluid amplifier 29 b and a control jet in the flow

ao medium booster 29 α results. The control jet from the control input 37 α deflects the power jet of the fluid amplifier 29 α so that it flows into the output channel 35 a. Similarly, the b protruding from the control input 37 of control beam directs the beam power · of the fluid amplifier 29 from b so that it flows in the output channel b 35th Since both power jets are deflected by the output channels 33 α and 33 b , no flow flows through the output channel 41.

In the third case there is a hole in the recording medium 13, but none in the recording medium 15. .. ·., -... ■ .. ,,. . ■;. ■■.:., .. ■ - ■■■: The details are not the same, so that a flow should occur in the output channel 41 for setting the error display device 9. As a result of the hole in the recording medium 13, a flow flows from the fluid source 1 in the scanning channel 25 α and generates a power jet in the fluid amplifier 29 α and a control jet in the fluid amplifier 29 b: Since there is no hole in the recording medium 15, no flow flows in the scanning channel 25 b to generate a power jet in the fluid amplifier 29 b or one Control jet in the fluid amplifier 29 a. As a result, flows of a leaking power beam α in the output channel 33 from the opening 43 and from there through the outlet passage 41 for error display device 9 and the transport control mechanism 11 to stop the card transport, is determined by the source of error. When the transport control mechanism includes electrical circuitry, the flow in output channel 41 can be converted to an electrical signal by an electrical pressure switch of known design.

After the source of the error has been determined, a keyboard, which is not shown, can be used to send a clear signal to clear the error display and to resume the transport operation.

In the last of the above-mentioned cases, recording medium 15 contains a hole in the position to be scanned, and recording medium 13 contains no hole. From the fluid source 1, the flow passes through the hole into the scanning channel 25 b and generates a power jet in the fluid amplifier 29 6 and a control jet in the fluid amplifier 29 a. However, since in the recording medium

there is no hole, no flow flows through the scanning channel 25 α to generate a power jet in the fluid amplifier 29 a or a control jet in the fluid amplifier 29 b. As a result, the power beam emerging from the opening 43 b flows through the output channel 33 b and into the output channel 41.

For each point to be scanned in a row of the recording media, a scanning channel 25 a, a scanning channel 25 b with the two fluid amplifiers 29 α and 29 b is required. The output channels 41 of all flow amplifiers can be connected to a common error display 9 and a common transport control 11.

Simultaneous scanning of all character positions on a card-shaped recording medium would require MxN = MN flow amplifier pairs, where M represents the number of card columns and N the number of possible positions in a column where perforations can be made.

An arrangement is shown in FIG. 2 in which the time required for the scanning is M times as great, but which only requires N pairs of flow amplifiers. In this arrangement, the flow passes from a flow source through a channel 47 to a chamber 49 in a reading head 51. The chamber 49 has an opening next to the card transport path, which extends over the width of the card and is at least as wide as the openings 27. There are N openings 27, one for each possible character position in a column of the recording medium. Each opening 27 is through one in F i g. 2, flow guide channel (not shown) connected to a power input of a pair of fluid amplifiers. The same scanning arrangement is provided for scanning a second recording medium. According to FIG. 2, the record carrier moves from left to right, with N character locations being read with each scanning operation. After M scanning operations, all of the character positions on the recording medium have been read.

3 illustrates another arrangement which is particularly suitable for scanning card-shaped recording media. The corresponding character positions in all columns are scanned simultaneously in order to generate flow signals which reach the openings 27. This arrangement requires M fluid amplifier pairs, but all of the character locations on the card can be read in TV scan operations.

Have both scanned recording media 13 and 15 holes and generated in the scanning channel 25 α

ίο flowing flow a power jet in the fluid amplifier 29 a, before the flow flowing in the scanning channel 25 6 generates a control jet in the fluid amplifier 29 α , the power jet arrives in the output channel 33 α and the output channel 41 and would thus set the error display device 9, even if the recorded Characters are the same. If the flow flowing in the scanning channel 25 b generates a power jet in the fluid amplifier 29 &, before the

ao. If the flow in the scanning channel 25 a generates a control jet in the fluid amplifier 29 b , the power jet enters the output channel 33 & and would cause a false error display. (

These possibilities for error are eliminated by the fact that artificial delays are provided which delay the occurrence of the power beams until the control beams have started to flow. This is achieved in that the power beam input channels are made longer than the control signal input channels. Or a delay chamber 53 a, 53 b can be provided in each power jet inlet channel, which form flow capacities. This latter method is shown in Fig. 1, where the delay chambers 53 a, 53 b are formed by delaying the power inputs 31 a, 31 b .

As a further possibility, a clock pulse with the signal in the output channel 41 can be in a logical AND circuit of a flow amplifier linked in this way that the signal in output channel 41 is checked after the fluid amplifier pair Had time to reach the final state. In this case, the artificial delay elements are not required.

1 sheet of drawings

Claims (2)

Patent claims: 1. Fluid-controlled comparison device for two perforated recording media which, with their holes at a scanning station provided for each recording carrier, clear the passage for a fluid in a scanning channel, characterized in that two monostable fluid amplifiers (29 σ, 29 6) each have a power input ( 31a, 31Z>), a control input (37 a, 376) and two output channels (33 a, 33 6; 35 a, 3Sb) the power input of one fluid amplifier and the control input of the other fluid amplifier, each with a sampling channel (25 a, 25 6 ) are connected and that the fluid- carrying output channels (33 a, 33 b) connected to one another in the stable state lead to an error display device (9), while the other output channels (35 a, 35 b) are open, so that only when Fluid in the sampling channels that from the power input of the fluid amplifier it is diverted to the open outlet channels by the fluid entering at their control inlets. 2. Comparison device according to claim 1, characterized in that a delay chamber (53 a, 53 b) is arranged in front of each power input.