DE1295649B - Signal converter for signals of a code 1 out of 2 into signals of an n-digit binary code with the aid of a relay matrix - Google Patents

Description

In telegraphy and data processing, the task is often to create a specific symbol from individual electrical stimuli. In the case of the well-known telegraph alphabet number 2, five stream steps or model elements are known to form 25 = 32 different telegraph characters. In the field of data processing, this is referred to as a binary code 25. The supply of available characters or meanings increases in the given mathematical relationship with the exponent n. In practice, h is usually chosen to be less than 10 because the supply of characters to be distinguished or meanings so that it is sufficiently large.

It is known in a signal converter, for example in a 25 code five electromagnetic neutral relays through a network of rectifiers to be switched on in such a way that for each of, for example, 32 individual incentives only the associated Relays can be selected from the five possible, with the connection paths via so many rectifiers for each individual incentive run like current steps in the corresponding one Character or word are included.

However, there are certain coding cases where with voltages up to 200 V and above must be worked. The rectifiers and the relays must then be designed for this working voltage and must take into account the occurring induction voltages be correspondingly oversized. this leads to to series connection of several rectifiers or diodes and increases the needed space and the price.

It is also from the magazine “New Technology in the Office”, issue 4, 1963, a pyramid circuit known for 32 outputs with five switching stages is designed. However, this is exactly the opposite case as with the registration. With this arrangement, one of 32 outputs must be found or when the 5-code signal is input in parallel or in series will. A reversal of the operation is not suggested here and also not without it further possible.

The invention relates to a signal converter which has the listed Avoids disadvantages of the known arrangements and in which the means used to a minimum in terms of space and costs.

According to the invention, this is done in a signal converter for signals of a code 1 from 2n into signals; an n-digit binary code with the help of a matrix containing n electromagnetic relays with 2n input and n output lines achieved in that the electromagnetic relays suitable for parallel tapping, magnetically controllable protective tube; have contacts and each of the n relays Carries excitation coils, which are connected in parallel or in series according to the combination options. The advantageous structure of the signal converter is achieved by restricting to as many electromagnetic circuits as corresponds to the exponent number, which in a manner not known by a plurality of coils form a functional unit, the contacts being designed as protective tube contacts.

According to an advantageous embodiment of the invention, the signals are stored in that the iron circuit of each electromagnet at least a holding coil is assigned. Preferably the poles are the electromagnets one holding contact and one or more galvanically independent contacts Output contacts assigned.

According to a further advantageous embodiment of the invention is the iron circle of each electromagnet is U-shaped and the coils on both Distributed parallel legs. The protective tube contacts are attached so that their air gap between the two poles of the parallel legs of the electromagnetic magnets lies.

A favorable spatial shape of the signal converter is achieved by that the electromagnet and the protective tube contacts between circuit boards from electrical and magnetically non-conductive material are attached and with these a compact Form a building block.

An embodiment of the invention is shown in the drawing. It shows F i g. 1 shows the basic structure of the signal setter, FIG. 2 one executed Signal converter in the side view, partly in section, F i g. 3 the same Signal converter in top view.

The principle shown in FIG. 1 has a 2 "code with a number of electromagnets equal to the number of the exponent n, with a 2n code in the example five electromagnets 51 to 55. The iron circle of each electromagnet is U-shaped and has two legs 56 in each case and 57.

The inputs Zn of the signal converter are denoted by 1 to 32 in the example. A number of magnet coils 58 of the electromagnets 51 ... 55 are preferably located in parallel in each of these input lines.

At least one contact k1 ... K5 is assigned to each electromagnet, which is in one of the output lines 59 . .. 63 lies. Another each electromagnet associated contact hl ... h5 is located with an electromagnet own holding coil S1 ... S5 in parallel to a hold circuit 64 in which a contact is mounted g.

The F i g. 1 shows the signal converter in the idle state. If, for example, a voltage is applied to the line 2, a current flows through the coils 58 of the electromagnets 51, 53 and 55. A magnetic flux is generated in the iron legs of these electromagnets, under the influence of which the contacts k1, k3 and k5 the outputs 59, 61 and 63 close. The other contacts k2 and k1 remain open because their electromagnets have not been excited. The electromagnets 51, 53 and 55 also close the contacts hl, h3 and h5 at the same time. As a result, a current flows through the holding coils S1, S3, S5, so that even after the voltage on the line 2 has ceased, the said electromagnets remain energized and the signal is stored.

It is only when contact g is opened that the holding coils are de-energized, so that the excitation of the electromagnets 51, 53 and 55 ceases and all actuated contacts open again. The starting position for the arrival of the next signal on one of the lines 1 to 32 is thereby reached. When such a signal arrives, the corresponding electromagnets are then excited in accordance with the distribution of the coils 58 of this line and the associated outputs 59 ... 63 via the contacts k1 ... k. closed.

The mechanical structure of such a storing signal converter is shown in FIGS. 2 and 3 shown. Three plates made of electrically and magnetically non-conductive material 65, 66 and 67, which can carry a printed line guide on their sides 68, 69, 70 , are connected to one another by pillars 71. The U-shaped iron circles of the electromagnets 51 ... 55 are pushed through the middle plate 66 and fastened to it.

The coils 58 and also the holding coils S1. . . S5 are divided so that half the number of turns of the corresponding coil is arranged on one leg 56 and the other half number of turns on the other leg 57 of the same electromagnet. For this purpose, a common bobbin 75 is expediently pushed onto each leg 56 or 57 , which coil body 75, separated by flanges 76 , receives the individual turns.

Transverse to the coil, the contacts k1 designed as reed relays ... k5 and hl ... h5 pushed through the plates 65, 66, 67 and are soldered at their ends to the printed wiring of the plates 65 and 67th In addition, these protective tube contacts are held by helically bent bronze wires 72 on the poles 73 and 74 of the electromagnets, with a bronze wire wrapping around the two protective tube contacts assigned to the electromagnet and engaging with its ends behind hook-shaped recesses 77 of the coil formers 75 .

The known bottle protection contacts, in which a movable spring 79 and a rigid counter spring 78 are melted into a flat glass tube, are preferably used as protective tube contacts. Under the influence of a magnetic field, the movable spring executes a lateral movement, and the beveled end faces of both springs make contact.

The protective tube contacts are attached to the electromagnets in such a position that they lie with the working air gap 81 between the poles 73, 74 of the associated electromagnet. The switching status of the protective tube contacts can be seen from the outside at any time on the signal converter.

The individual coil connections are led out to the printed circuit of the plates 65, 67 and soldered to them. Plugs 82 are attached to all plates 65, 66, 67 so that the module formed by the plates, the pillars and the electromagnets can be plugged in.

A modification of the signal converter can be made in such a way that parts of the iron circuit of the individual electromagnets 51 ... 55 are made of permanent magnetic material or that permanent magnets are attached parallel to the protective tube contacts. In both cases it can be achieved that the actuated contacts k1. . . k5 can be held by the permanent magnetic flux even after the excitation of the electromagnets has ceased. However, the permanent magnetic flux must not be so high that the contacts are already actuated by it. The holding coils S1 ... S5 are then expediently designed as discarding coils.

The output signals can also be re-stored in electromagnetic switching means, for example flip-flops, which are placed in the output lines in a suitable manner. These electronic switching means, in particular in transistor construction, are advantageously attached to the plates 65 and 67 of the signal converter.

Claims (17)

Claims: 1. Signal converter for signals of a code 1 from 2n into signals of an n-digit binary code with the aid of a matrix containing n electromagnetic relays with 2n input and n output lines, characterized in that the electromagnetic relays are magnetically suitable for parallel tapping have controllable protective tube contacts (k1 ... kg) and each of the n relays (51 ... 55) carries 2n excitation coils (58) , which are connected in parallel or in series according to the possible combinations (FIG. 1). 2. Signal converter according to claim 1, characterized in that the iron circuit of each electromagnet (51 ... 55) is assigned at least one holding coil (S1 ... SS) (F i g. 1). 3. Signal converter according to claim 1 and 2, characterized in that the poles (73, 74) of the electromagnets (51 ... 55) each have a holding contact (hl... H5) and one or more galvanically independent output contacts (k1 . .. k.) are assigned (Fig. 1, 3). 4. Signal converter according to claim 1 and 2, characterized in that the iron circle of each electromagnet (51 ... 55) is U-shaped and the coils (58, S1 ... SS) are distributed over both parallel legs (56, 57) (Fig. 1, 2). 5. Signal converter according to claim 1 to 3, characterized in that the protective tube contacts (k1 ... k5, hl ... H5) are attached so that their air gap (81) between the two poles (73, 74) of the parallel legs Electromagnet (51 ... 55) lies (F i g. 2, 3). 6. Signal converter according to claim 1, characterized in that the electromagnets (51 ... 55) and the protective tube contacts (k1 ... k5) between boards made of electrically and magnetically non-conductive material (65, 67) are attached and with these one form a compact building block (Fig. 3). 7. Signal converter according to claim 1, 2 and 6, characterized in that that the individual coil connections are led to the boards (65, 67) and the Interconnection on the circuit boards (65, 67) using the printed method Circuits is carried out (Fig. 3). B. Signal converter according to Claim 6, characterized in that a central plate (66) is provided for supporting and holding the electromagnets (51 ... 55) (Figs. 1, 3). 9. Signal converter according to claim 6, characterized in that the protective tube contacts (k1 ... k5) are stored in the outer boards (65, 67) and are directly soldered there (FIG. 3). 10. Signal converter according to claim 1, characterized in that the position of the protective tube contacts (k1... K5) to the poles (73, 74) of the electromagnets (51 ... 55) is secured by a helical spring (72) made of non-magnetic material (Fig. 2, 3). 11. Signal converter according to claim 6 and 8, characterized in that that the three circuit boards (65, 66, 67) as circuit boards with plug-in devices (82) are provided and form a pluggable module (Fig. 3). 12. A signal converter according to claim 1, characterized in that parts of the ferromagnetic circuits of the electromagnet (51 ... 55) are at least partially formed from permanently magnetic material, which hold (.. K1. K5) is actuated reed relays by adhesion (F i g. 1). 13. Signal converter according to claim 1, characterized in that permanent magnets are attached to the protective tube contacts (k1 ... k5) in parallel that the contacts (k1 ... k,) after the excitation of the electromagnets (51 ... 55) has ceased to exist remain closed (Fig. 1). 14. Signal converter according to claim 1 and 3, characterized in that in the case of permanent magnetic holding of the actuated protective tube contacts (k1 ... k # _) instead of the holding coils (S1 ... S $), ejector coils are attached (F i g.1) . 15. Signal converter according to claim 1 and 6, characterized in that when the output signal is re-stored from the protective tube contacts (k1 ... k $) in electronic switching means, preferably flip-flops, the electronic switching means on the boards (65, 67) of the Building block are arranged with (F i g. 3). 16. Signal converter according to claim 1, characterized in that the coils (58) of the electromagnets (51 ... 55) are designed so that operating voltages of a few 100 V are permissible (Fig. 1). 17. Signal converter according to claim 1 and 2, characterized in that all holding coils (S1 ... SS) are assigned a common contact (g) which determines the duration of the holding (F i g. 1).