DE546202C - Electrical storage arrangement - Google Patents

Description

Electrical storage arrangements There are electrical storage arrangements known, whose task it is to carry out several different orders in sequence and in the same order in which they were saved take effect individually for any control processes at given times permit. Such facilities find z. B. in shunting technology for railway gully systems Use. Also for automatic train sequence displays in modern urban rapid transit such memories are proposed or in operation. Likewise in the area of Telescopic mail switching arrangements become known in which such storage devices for the automatic control of pneumatic tube deliveries in pipe networks with a plurality use is made of stations without identification of the carriers. One Such a storage device consists, for example, essentially of a row of stepping mechanisms (rotary selectors), each of which can be set to one specific step can accept any order, as well as two auxiliary rotary selectors (Control switch), one of which is the sequence of assignment of each Memory when storing, the other determines the effectiveness of the stored Allows orders in the appropriate order. The present invention relates a storage arrangement, especially for pneumatic tube systems, in which the order the occupancy of the individual memories when saving as well as the effectiveness of the stored orders in the appropriate order by placing them Memory itself and by means of switching means assigned to them and dependent on their position is determined.

This arrangement has an advantage that the memory device is light can be expanded.

When using special control switches common to all memory selectors there is naturally a certain relationship between these switching means: It can at most, only as many memory selectors are used as the control switches Have steps. Once this limit is reached, extensions are only possible Installation of new, larger control switches possible. As according to the invention for the control The sequence of the memory selector to be used does not have these common auxiliary switches (Control selector) used, but the position of the memory element itself in connection are used with switching means assigned to them, there are technically none More limits for any size expansion. Another conclusion from the the idea underlying the invention is the Voltage independence the storage device. This should be understood as follows: If for any Basically (blown fuse, etc.) the operating voltage fails and gradually returns after some time (e.g. after a fuse has been reinserted), the memory device in all its parts the position corresponding to the previous occupancy take again so that no order can be lost. This requirement could are not completely fulfilled in the previously known storage devices. The memory selector and the control selector remained, but the occupancy indicator could not depend solely on the position of the electorate. be made. According to the invention, the characteristics of the occupancy and the complete The memory device is occupied solely by the position of the memory selector made dependent and accordingly could the task of voltage independence in represented senses can be solved. These processes are based on the description made attentive in detail.

It should also be mentioned that the memory arrangement shown also brings an economic advantage for smaller systems in which only a few different types of jobs are to be stored at the same time. It is obvious, that a tax procedure in which the common control means a larger Require effort, the less economical, the smaller the number of links for which the common tax resources are necessary. All the more economical is therefore a tax procedure in which the common tax resources at the expense of . The resources assigned to the individual memory selectors are reduced, as in the present case Invention is the case.

In the following, the illustrated in the drawing, according to the invention executed memory device are described. As an application example may a telescopic mail system can be considered. The orders to be saved are then the one at the transmitting station. destinations set one after the other in the same order - dispatched pneumatic tube carriers. So there are several rifles with different ones Aim in the same route. The points leading to the various receivers must then automatically be provided by the storage device: at the right time will. The first order must therefore be the switch that corresponds to the target of the first rifle, place. As soon as the first can has passed the switch, the first order is placed deleted from the bush (by retracting or retracting contact) in the memory and thereby the second order takes effect automatically, etc. From those necessary in actual operation Locking devices that automatically prevent too close a series of cans and thereby secure the individual control processes operationally. apart from here because they do not belong to the essence of the invention and are also known. May it it is assumed that too close a series of rifles by some means is avoided.

The memory arrangement consists of a plurality of memory elements, namely there are as many memory elements as switching orders are to be stored at the same time. Each memory element consists of a step-by-step mechanism, namely the rotary dials that are customary in telephony technology are to be used as step-by-step mechanisms. Each rotary selector has three contact arms a, b, c. The switching order is identified by the position of the contact arms on a specific step. Two storage elements i and z are shown in the figure. The switching elements belonging to a storage element are framed by dash-dotted lines. All switching elements belonging to a memory element have the same numerical index.

For example, the rotary magnet D1 belongs to the memory element i Drive the contact arms rcl, b1, cl, which brush the contacts o to io. To the Memory element i are also assigned the relays Ui and Vi. The relays V are strong delayed on. The contacts of these relays are labeled ul, z4'2 etc. and v "-, v12 etc. The switching elements of the memory element 2 are analogously denoted by D2, U2, T12, u21, v21. .. designated. The individual storage elements i, a, 3 etc. close circuitry together to form a ring. Below this ring circuit are the switching elements that are common to the entire ring. You insist from a number of relays, the contacts of which with the corresponding small letters are designated. The individual contacts of the same relay are distinguished by numbers the. Furthermore, a step switch SW is provided for all memory elements together, which is driven by the rotary magnet DW. This rear derailleur is used to To make wear of all switching means evenly. Saving a Switching order takes place via the lines: an i to io. The submission of the switching order or the desired control process is triggered via the lines:, ab. i to io. It is assumed that the switching memory for a pneumatic tube system with in sections Passing on the target identifier can be used target. In such a system, each switch is assigned a switching memory the turnout according to the stored switching orders for the individual incoming pneumatic tube carriers is placed on diversion or passage. When sending a pneumatic tube carrier becomes the switching memory of the first by pressing a destination key set to be passed through. If the rifle after passing the switch does not leave the pipe section, d. H. to reach your target point even more Has to go through turnouts, the switching order to the switching memory is the next Switch passed on so that when the rifle arrives at the next switch the switch memory is set accordingly.

Making the individual stored switching orders effective for the switch belonging to the switch memory is controlled by the travel contact dfl, which is arranged some distance in front of the switch in the travel tube and is briefly knocked over by the moving rifle. Behind the switch is a further travel contact a2 is arranged, which briefly when discharging a can is turned over. The switch is activated with the help of the relay W to deflect or drive through posed.

The way in which the switching order is stored and the switching order is passed on to the switching memory of the next switch is described in detail using the current circuit: Before a bushing enters the pipe section in which the switch is located, either the keypad on the transmitter or In a memory selector of the previous section, one of the wires at i to io is connected to battery voltage. When retracting the sleeve, the same actuates the travel contact dfl for a moment. Relay X picks up and is held via contact x1. Contact x2 connects test relay P to wire IV and contacts x3 connects relay interrupter RU to wire VI. The contact x4 brings the U relay of the storage element to which this arm is currently set via the arm of the switching mechanism SW. It is assumed that arm SW is in the position shown, so that relay U1 picks up. Relay U1 connects arm a1 of the memory selector with wire IV and thus with test relay P by means of its contact u11. Contact Z-12 places the rotary magnet Dl on wire VI, ie on the relay interrupter RU. The rotary magnet Dl receives interrupter current, so that the contact arms a1, b1, cl are advanced step by step. As soon as the arm a1 touches the step on which the battery voltage is applied, the test relay P picks up. The relay interrupter RU is now disconnected by the contact p1 and the memory selector i is stopped. The contact p ° applies voltage to the point El. This either causes the key magnet to respond, so that the pressed key jumps out, or the memory selector of the previous section, whose job has just been accepted, is sent to the zero position. The contact opens the holding path of relay X, which drops out. Contact x1 completes the opening of the holding path, so that relay X does not pick up again even after contact p3 has dropped. Contact x2 disconnects relay P, which drops out. Contact x3 disconnects the relay breaker. When contact x4 drops out, relay Ui in storage element i drops out. The previously released P relay closes its contacts p1 and p3 again, but this remains ineffective since X has been released. When relay U1 drops out, arm ax is separated from wire IV by contact u1'-, while the connection of arm b1 to wire V is prepared by contact u13. In the same way, contacts 2412 and u14 cause the rotary magnet to be separated from wire VI and connected to wire III in preparation.

The relay ITl picks up because the contact dl of the rotary magnet Dl remains in its rest position for a long time and the arm cl of the memory selector is in the working position. The separation of the arm a1 is completed by contact v11. Contact v12 causes the rotary magnet Dl to be connected to wire III. Contact v13 connects arm bi of the rotary selector with wire V, ie with the battery. Contact v14 pulls B and contact v "pulls the relay UZ of the next storage element a. In addition, v11 bridges the dl contact, so that the relay Vi stays on for as long as the selector moves home and the dl contact works via contact v- until the arm cl has reached the zero position. As a result of the switching operations described in the memory element i, as already described at the beginning, the next memory element a was connected to the storage cores IV and VI by pulling on its relay UZ, while the Memory element i was switched on by the de-energized state of its relay U1 and the energized state of its relay Vl to the sampling wires III and V. Furthermore, the attraction of the relay B by means of its contact b1 caused the attraction of the relay Fr, which in turn prevented the contact immediately by means of the contact JA that battery voltage came to point E2 via b1. Contact b = separates the arm of the switching mechanism SY T 'and the associated rotary magnet DW from the battery voltage and brings off the delayed relay H. As soon as B drops out again when the memory is empty, this rotary magnet DW receives a current surge via lai during the fall time of H, which switches SW by one step.

The free relay F3- remains in the activated state until only a single memory element is still unoccupied. Then all c-arms are the Memory selector except for one in the working position, and all U relays except for one are attracted. The only released U-relay and the only one in rest position c-arms that are located do not belong to the same storage element, but to two successive, so that the core II now no longer carries any earth potential and Fr falls off. The contact f rl now connects the connection point E2 with battery voltage. This either locks the transmitter's holding device or the station switch, which limits the previous section, via the connection point Az to discharge posed. So no rifle can enter the blocked section.

The relay W, which sets the points, is connected to the wire of the Multiple field: from o to io, the number of which corresponds to the target identifier for this section corresponding receiving station. As soon as the first occupied memory selector contains this target identifier and is therefore on the step to which W is connected (step i in the drawing), the switch is switched to discharge posed. This also happens, as already mentioned, when the next one Section is blocked and therefore battery voltage is at connection point A2.

When extending a rifle from the receiving station of this section actuates the same the extension contact a2, which brings the relay Y to pull. One second excitation possibility of this relay is via the connection point Al, the by the contact p = of the next switching memory at the moment for a short time is applied to battery voltage when the storage device of the next Section an order from the storage device of the shown in the drawing Section takes over.

The energized Y relay is held via contact y1. The contact y2 connects the relay interrupter with wire III and thus with the rotary magnet Dl of the first occupied memory step controller i, whereby the same work starts and runs into the zero position. As soon as step zero is reached, receives the relay O via the arm b1 and the wire V battery voltage and picks up. Contact q1 immediately disconnects the relay interrupter RU and stops the memory selector. Contact q2 separates the holding path for relay Y, which drops out, causing the switch-off of the relay interrupter and the separation of the stopping path by the contacts y2 and y1 is completed.

The relay Th of the memory element i just discussed drops out because the arm cl of the associated memory selector went into the rest position. So it is in this memory element both relay U1 and relay valley dropped out and thus the memory element free. In addition, through contact vlI 'the relay Uz of the next Storage element z is de-energized and now puts this storage element through its waste to the sampling wires V. The opening of the contact v13 causes the relay O to drop out, so that the rest condition of the removal device is reached again.

The circuit description shows that the relay U of a storage element is always activated when the preceding storage element contains an order. It is therefore used to connect its own memory element, which is the next one for storing a switching order, to test wire IV and to wire VI for driving the rotary magnet. The relay V of a storage element must have a considerable pull-in delay, since it receives current surges on one of the wires at i to io during the setting of the memory stepping mechanism, which should not cause it to pick-up. Only after the checking process does the relay V pull in via the contact d of the rotary magnet and the contact arm c, which is in the working position. As soon as the previous memory element has given its order, the relay U of the next memory element drops out. Therefore, after an order has been stored, only the relay V of the memory element that contains the order is picked up. Via the contacts of the relay V, the memory element is connected to the control wires III and V, via which the stored switching order is issued. Relay B is energized via a contact of relay U, the energized state of which identifies a memory element that has stored an order. Since the relay B can be excited by the contacts of all memory elements, it indicates the occupancy status of the memory arrangement and can, for example, be used to maintain the fan circuit in the pneumatic tube system for so long; as any order is stored. The relay B also takes over the switching of the switching mechanism STF, which, as already mentioned, determines the storage element that is to receive the first order by its position. SW always takes a step when B falls, ie when the memory has become empty. The relay Fr (free relay) is connected to wire II. Since this wire in each storage element is grounded via a u5 break contact and the rest position of arm c, wire II is connected to earth as long as two successive storage elements are still free. As soon as only a single one is unoccupied, at least its U relay is picked up and the last connection between wire II and earth has been interrupted. The relay Fr thus receives (provided that the relay B has picked up) current until only a single memory element is unoccupied. It is necessary to keep the last link free in order to prevent the limit at which the removal of the orders has to begin is not blurred when the entire circuit arrangement becomes powerless and all the relays drop out. If the current starts again after the malfunction has been rectified, then all V relays, whose associated tachometers are in the working position, and through these I # 'relays all U relays of the respective subsequent storage elements pull on, so that the state before entry the currentlessness is then completely restored.

From the description of the processes the following emerges: The relay h of a memory link attracts in your moment where the voter checks and drops off as soon as the voter has reached the zero position. The relay U is immediate operated by relay V, so that the contacts are actually on relay b ' could put. You would then only have one relay per storage element, however numerous contacts. Finally, the law according to which the relay V picks up and drops out, also purely, mechanically through a contact arrangement reach the voter himself who works according to the same law. With that would all relays in the memory elements are dispensable.

Claims (1)

PATENT CLAIMS: i. Electrical memory arrangement in which several different types of orders are stored in sequence and activated individually in the same order, characterized in that auxiliary switching means (relays U and V) which are assigned to each memory selector and their switching status from the position of the own and neighboring memory selector depends, through their respective switching status (U excited, Tl excited, U and V excited, U and V not excited) identify the sequence of storage and removal, the occupied status and the free status of the individual memory selectors. a. Electrical memory arrangement according to Claim i, characterized in that the memory selector to be occupied first of the memory selector which is circuit-technically combined to form a ring is determined by a switching means (SW) outside the ring. 3. Electrical memory arrangement according to claim i and 2, characterized in that a blocking of the occupancy of the switching memory is effected when all memory selectors are occupied except for one memory selector, so that the memory selector remains characterized by keeping a memory selector free when the switching device is de-energized the removal of the orders has to begin.