DE1060445B - Coordinate selector - Google Patents

Description

GERMAN

The invention relates to a particular type of coordinate selectors, namely those in which Crossing row and row coils are provided, each extending over the entire row in question or row extend. At the crossing points of the row and row coils there is a contact set provided whose contacts (protective tube contacts) are made of magnetizable material, and their working air gap each lies between the two coils that actuate them. To keep closed contacts special holding coils are used, which only work in one coordinate direction, i.e. either along the lines, or along the rows, and also extend over the entire coordinate in question.

Fig. 1 shows an example of such a voter structure. It has four crossing points and consequently has four sets of contacts 1, 2, 3 and 4, each of which consists of a protective tube contact, for example. The sets of contacts are comprised of row coils A and B and row coils C and D. In addition, the two holding coils H 1 and H 2 are also provided, which hold a closed protective tube contact in this state when they are excited. The holding coils are here parallel to the series coils; however, they can also be arranged parallel to the line coils. Of course, the number of crossing points of such a selector can be chosen to be as large as desired.

The mode of operation of such a coordinate selector is that when a line and a series coil to the contact set provided at the intersection of these two coils Closing its contacts sufficient magnetic field is applied. The working air gap of the contacts namely lies between the row and the line coils. The contact sets and the coils are dimensioned so that when two coils are excited, which are located on both sides of the working air gaps, the relevant Contacts are operated. If the contacts are now to be switched off after the associated line and series coil are kept in the closed state, the associated holding coil is energized set, which then supplies the magnetic field required for the permanent closure of the contacts.

The object of the invention is the expedient activation of the holding coils. According to the invention are for Switching on the holding coils own protective tube contacts provided by the holding coils themselves and are excited by the line or row coils running parallel to them. This protective tube contact can now be provided either in the contact set provided at each intersection, with which are encompassed by a holding coil, for their shuttering coordinate selectors

Applicant:

Siemens & Halske Aktiengesellschaft,
Berlin and Munich,
Munich 2, Wittelsbacherplatz 2

Dipl.-Ing. Rudolf Nitsch, Munich-Solln,
has been named as the inventor

protection tube contacts are to be connected in parallel, or as a special protective tube contact arrange outside of the contact sets for one holding coil only.

2 shows an embodiment in which the protective tube contacts provided for switching on the holding coils are accommodated in the contact sets of the selector. In order to simplify the representation, only a single row of the coordinate selector according to the invention with the contact sets 1, 2 and 3 is shown in this figure (and also in FIG. 3). As a result, only one row coil RS and one section of each of the three row coils ZS1, ZS 2 and ZS 3 arranged one above the other are shown in the figure. Parallel to the series coil RS is z. B. the holding coil HS. When the series coil RS and, for example, the line coil ZSl are excited, the contacts of the contact set 1 are actuated, with the contact J 1 provided for switching on the holding coil HS being closed, which is thus connected to the circuit shown in broken lines into which the voltage source U is switched on. the holding coil HS is energized. The provided in the contact sets 2 and 3 the protective tube contacts s 2 and s 3, which are also provided for switching the hold coil HS, act in the same way as the three contacts si, are connected in parallel s2 and s3. The excited holding coil HS holds with the actuated contact set obviously those reed relay s 1 ... j 3 which caused its activation, so that the energization of the holding coil is automatically maintained. In order to be able to trigger the set of contacts held by the holding coil, the break contact k is provided in the circuit of the holding coil HS , with the opening of which the circuit for the holding coil is interrupted. The contact set held by the holding coil HS thus returns to the rest position, with

809 747/118

also the protective screw contact si provided for switching on the holding coil. . .s3 is opened.

3 shows the further embodiment described above, according to which a special protective tube contact J is provided for each holding coil. This protective tube contact ί is encompassed by the series coil RS lying parallel to the holding coil HS . The protective tube contact s can now be designed so that it is already made to respond with the excitation of the associated series coil RS. (The control coil SS , which is also shown, is initially disregarded.) In this case, it closes the circuit shown in dashed lines with the voltage source U for the holding coil HS and thus causes it to be excited. If the protective pipe even addressed s contact, he continues to be held by the field of the energized coil holding HS. In addition, the holding coil, of course, also holds the through the series inductor RS and one of the rows coils ZSL to ZS 3 marked contact set 1 to 3. As in the embodiment shown in Fig. 2 lies in the current circuit of the holding coil HS the normally closed contact Ä \ the opening of which the energization of the holding coil HS interrupts and thus the contact sets of the selector, insofar as they were held by the relevant holding coil in the addressed state, triggers. As can be seen, the embodiment according to FIG. 3 has the advantage over that of FIG. 2 that only one protective tube contact needs to be provided for each holding coil for switching on, while in the arrangement shown in FIG the holding coil is consumed.

If only a uniformly dimensioned embodiment of protective tube contacts is to be used in the entire selector, a special control coil SS is expediently provided for actuating the contact ^. The contact is then actuated in the same way as the contact sets above it, using two coils on both sides of the overlap point of the protective tube contact ί. These are the series coil i? ^ And the control coil mentioned Λ \ Υ. In this case, the excitation of the holding coil HS is made dependent on the activation of the control coil SS , whereupon the holding coil HS, as in the previously described embodiments, takes over the holding of the protective tube contact s and the contact set that is still operated until the normally closed contact k opens will.

The control coil is expediently designed in accordance with the shape of the line and row coils as a flat, straight winding, which then includes all of the protective tube contacts provided for switching on the holding coils. In Fig. 3 of these protective tube contacts only the contact ί is shown. In the case of a construction of the relevant selector with three rows, apart from the protective tube contact,? two more are provided, which also enforce the control coil SS. Of course, it is also possible to provide a separate control coil for each protective tube contact s if special conditions occur. require. In this case, the control coil 5 \ S ″, shown elongated in FIG. 3, would be arranged in each case as a simple ring coil around the protective tube contact s .

4 to 9 show various circuits for a selector with three holding coils, which are not shown are.

The simplest way to switch on the control coil .SS is to provide a contact a only assigned to it, as shown in FIG. In addition to the control coil SS, which is switched on with the aid of the independently operated contact a , three series coils RS and three line coils ZS are drawn, each of which is excited via special setting contacts ek.

But you can excite the control coil
also immediately from the activation of the lines or Make the row coil dependent.

Fig. 5 shows an embodiment in which the

ίο Control coil SS is placed in series with the line and row coils. In this circuit, one setting contact ek belonging to a line coil and one setting contact belonging to a series coil, that is to say two setting contacts, must be closed in order to excite the control coil .S ¹ _{1 S ".}

In FIGS. 6 a and 6 b, two exemplary embodiments are shown in which the excitation of the control coil SS depends only on the actuation of a single setting contact. For this purpose, the control coil SS is connected in parallel either to the series coils RS or to the line coils ZS. 6a shows the parallel connection to the series coils RS, the excitation of the control coil depending on the setting contacts belonging to the line coils ZS , while in the circuit according to FIG. 6b the control coil SS is placed parallel to the line coils ZS and consequently the excitation the control coil is made dependent on the setting contacts belonging to the series coils.

The dependence of the energization of the control coil SS of only a setting contact can also be obtained if this show the control coil SS either only to the rows coil ZS or me switched to the series coils RS in series, as shown in Figs. 7 a and 7 b.

An electrically symmetrical embodiment can be achieved by building the control coil -S \ 5 "from two windings, one of which is placed in series with the row coils ZS and the other in series with the row coils RS , the direction of the winding of the two windings is to be selected so that when a line coil and a series coil are excited, the fluxes in the two windings add up.This type of circuit is shown in Fig. 8. The two windings of the control coil SS are designated here by I and II.

In FIG. 9, however, a circuit for a selector is shown in which each holding coil only has a protective tube contact s that switches it on, for each of which a separate control coil is provided. These are the control coils SS 1, SS 2 and SS 3. They are in series with the series coils RS, so that with the excitation of a series coil RS , the associated control coil also receives current, since it excites the relevant series coil with respect to the the holding coil must support the protective tube contact switching on.

Under the A ⁱ recondition in that the working air gap of the reed relays are disposed between the series of coils and the rows coils also lie in the arrangements shown in FIGS. 2 and 3, the number of coils RS and the holding coil HS both sides of the Überlappungsstelleii the encompassed by them Schutzroh rkontakte. As a result, all contacts of the row in question can now be actuated with simultaneous excitation of a series coil and a holding coil assigned to it, which would represent an incorrect actuation, since only the set of contacts whose line and series coil are energized is to be actuated. So it must be ensured that the activation of a holding coil from the disconnection

Claims (1)

the associated series coil is made dependent and that, conversely, the deactivation of a series coil is made dependent on the activation of the associated holding coil. In an intermediate time that may be present, the relevant set of contacts could be held by the line coil. The same considerations apply to the equivalent case in which the line coils are arranged parallel to the holding coils. Compliance with this condition is inevitable if the holding coils are each built up from a holding and a compensation winding, of which the holding winding takes over the tasks of the holding coil when only energized, and the compensation winding when the associated line or series coil is switched on is excited as a result of the corresponding winding sense that it at least partially cancels the excitation of the holding winding. This principle can be implemented in various circuits. The exemplary embodiments discussed below are based on a selector in which the holding coils are parallel to the series coils. In the circuit according to FIG. 10, the compensation winding KW is between the contact ek for switching on the series coil RS lying parallel to the holding coil HS and the contact s for switching on the holding coil. The effect of this circuit is as follows: After the series coil RS and the line coil ZS have been excited by closing the contacts ek, the contact s that switches on the holding coil FIS is brought (see circuits according to FIGS. 2 and 3). When the contact s closes, the compensation winding KW and the holding winding HW receive current, the excitations of these two windings canceling each other out due to opposite winding directions. The holding coil HS can therefore initially have no effect, so that the above-described error excitation of other contact sets lying in the same row does not occur. If, however, the setting contacts ek are opened at the end of the marking process to designate the desired crossing point, the circuit for the compensation winding KW is interrupted, so that now the excitation of the holding winding can affect the closed contact set, whereby it is held. At the same time, the contact ^ for switching on the holding coil is also held. The holding winding must of course be dimensioned so that it can fully fulfill the tasks of the holding coil, even if, for example, as a result of later opening of the setting contact ek directly connected to the compensation winding, it remains energized for a while. In the circuit according to FIG. 10 there is namely a coupling between the marking circuit containing the setting contacts ek and the holding circuit containing the holding winding HW via the compensation winding KW. The aforementioned restriction in the dimensioning of the holding winding can be avoided if a circuit such as that shown in FIG. 11 is used. Here the compensation winding KW is parallel to the series coil RS via an auxiliary contact s2. This auxiliary contact is closed together with the contact s 1 for actuating the holding coil HS. Otherwise, the mode of operation of this circuit is the same as that of the circuit according to FIG. 10. When the contact part and.? 2 are closed, the compensation winding KW and the holding winding HW are magnetized in opposite directions. As soon as one of the setting contacts ek involved is opened, the compensation winding KW is also switched off, so that the magnetization of the holding winding HW, which can be measured accordingly, can now have an effect. The method of dividing a coil, as described above with respect to the holding coil, can also be used for the series coil. In the two circuits shown in FIGS. 10 and 11, only the compensation winding KW is then to be regarded as a part of the series coil RS, both parts being magnetized in opposite directions. The following sequence results in this case: With the excitation of the series coil and line coil, the associated set of contacts is actuated and contact s or contacts x1 and 9'2 are closed. The compensation winding KW thus receives a magnetization which cancels the field of the series coil RS. The relevant contact set is initially held via the line coil ZS. The holding coil HS also receives power. Incorrect actuation of contact sets belonging to the same row cannot occur, since the magnetization of the series coil RS is canceled by the compensation winding KW. As soon as one of the setting contacts ek involved is opened, the magnetization of the line coil ZS that is still present is canceled, so that only the field of the holding coil HS remains, which holds the contact set in question in the addressed state. In the circuit according to FIG. 11, a second contact, namely contact s 2, had to be used to achieve decoupling between the marking circuit and the holding circuit. This contact can be avoided by using a circuit as shown in FIG. Here the holding coil HS is formed by the compensation winding KW and the holding winding HW, which are excited in opposite directions. The compensation winding KW lies in the marking circuit and is also excited when the setting contacts ek are closed, that is, independently of a contact s. In order to compensate for the opposing magnetization of the compensation winding KW, which would initially prevent the relevant contact set from being actuated, the now more highly magnetized line coil ZS, which is arranged at right angles to the compensation winding KW and which is now more highly magnetized, supplies a field which at the crossing point in question corresponds to the field of the compensation winding Ä'W cancels. As a result, the normal field required to actuate the contact set acts at the intersection in question. The increased magnetization of the line coil does not have a detrimental effect on the contact sets which it continues to encompass, since this magnetization does not take place on both sides of the working air gaps, but only on one side, which cannot lead to any contact actuation. If the contact s is now also closed, the holding winding HW receives current and thus cancels the field of the compensation winding KW. In this state, only the row coil RS and the row coil ZS are effective, so that, as in the cases described above, no incorrect operation of the contact sets belonging to the same row can occur. When the marking circuit is disconnected by opening one of the setting contacts ek, however, only the field of the holding winding HW remains, which maintains the response state of the actuated contact set. Patent claims: 1. Coordinate selector with crossing line and row coils as well as additional holding