DE648086C - Conveyor system with several sections and storage facilities assigned to them - Google Patents

Description

Conveyor system with several sections and storage facilities assigned to them There are conveyor systems with, several sections and section-by-section transfer of the Destination identifier known from store to store. Passed in known arrangements the memories of voters, each set to a specific goal had to. The transfer of a target identifier from one section to the other took place accordingly in such a way that a voter of the next route section according to the setting of a corresponding selector for the previous section of the route has been set to a specific contact, which is the desired one, by current surges. Objectives of the associated conveying container. The passing on of the target identifier therefore takes a certain amount of time, which means that in quick succession time difficulties can arise in the container. According to the invention are the movable switching means in each, which characterize the destination of the conveying containers Section on special, each belonging to a particular one of the following receiving centers Groups - united, _ and these switching means are taking into account the order the conveyor hanger is only brought into an effective position for the same purpose. at the arrangement according to the invention therefore requires nothing more than a switching means from the group assigned to the desired goal from a rest position to the work position to transfer, so that the transmission of the target identifier is only a minimum of Takes time.

. Two exemplary embodiments of the invention are described below with reference to the figures. In Fig. I, a pneumatic tube line is shown in the lower half, at which three stations I, II and III are located; further stations can follow to the right. The traffic unwinds in the direction from left to right. each station is equipped with a number of transmitter ports; B. 2, 3, 4, 5 in station I equipped, each of which is assigned a specific goal from the outset, such that, for. B. all cans that are introduced into the nozzle 2 -, verden, are ejected at station II, all cans that are introduced into the nozzle 3, in station III, etc. are set to drive through and are electrically controlled by means of the switch magnets WMII and WM III. The control is mediated by the switching devices shown in the upper half of the figure, and each station that can receive cans is assigned such a switching device.

Each of these switching devices consists of a shaft L2 or L3, which is driven by an electromagnet T2 or T3 by means of a climbing wheel R, and on which a series of disks N are attached, and each switching device has as many disks N as the rifles traveling in the previous section of the route can have different destinations; is the 'total number of stations z. B. 5, the switching device of station II has four such disksN, since cans to stations II, III, IV or V can be on the way in the pipe section between stations I and II. On the periphery of each of these disks N are a number of movable switching members 0 at equal angular intervals. attached, in each case as many as cans in the upstream route section should be able to travel at the same time. These switching elements can be adjusted by electromagnets P in the radial direction. Is z. B. in station II the magnet P, energized, the movable switching element just in front of it is brought from the illustrated rest position radially outward into a working position, as it corresponds to the position of the switching element O in the drawing, and remains in this position even after the magnet is de-excited.

On the shaft L., there is also a frame made of insulating material U, rotatably introduced; a counting wheel Z is firmly connected to this frame. on the frame U., there are just as many contact plates V. to V ;;, as there are disks N. are. The frame U .., has a rest position that results when you are the frame, seen from above, clockwise, not quite i 8o 'from the one drawn Position turned around the shaft L, thinks. The frame U; ,, is in this rest position so only by a small angular amount compared to the row of magnets P. until P ;; offset, usually just before the left row of the movable switching elements O. to 0 ;;.

The frame is also under the influence of a not shown Spiral spring to prevent relative rotation of the frame U2 with respect to the shaft L2 seeks in such a way that this spring always tries to bring the frame U2 into the mentioned rest position, clockwise to turn back when viewed from above.

So is a movable switching element O of the row shown on the left has been pulled outwards by the associated magnet, and now becomes the wave L, rotated one step counterclockwise, the shaft L2 takes with the help of the switching element 03, which after a short turn of the shaft on the Contact plate V, the frame U2 abuts, the latter with, so that the above-mentioned Spring is tensioned. For example, if each of the disks N has eight movable ones Switching elements O, then the frame U-, after four steps of the wave, its each is 4.5 °, in the one shown. z location.

A magnet J2 'is attached below the shaft L =; If this magnet is excited, the frame U, with the counting disk Z., is shifted axially downwards a little bit on the shaft L. as a result, assuming the position of the individual parts shown in the drawing, the switching element 03 loses its contact with the contact plate V3 and arrives in front of a gap W in the frame U_>; As a result, under the action of the above-mentioned spiral spring, it snaps back clockwise, namely by one step, 45 ° in the selected example, since it is caught by any switching element O of the switching element row offset by q.5 ° in the working position will; because the magnet J; has meanwhile lost its excitement, so that the frame U .. immediately after @er has passed the switching element 03, under spring pressure, returns to its axial rest position, that is, it goes up a little again.

Let it now be the mode of operation of the whole shown in Fig. I Appendix explained. For this purpose it is initially assumed that station I from a can to be sent to Station III; on station I will therefore a socket is inserted into the sending connector 3, at the same time the contact 3 ' is closed; as a result, an electric circuit is created via the magnets P ;; and T., which causes these two magnets to be excited. The excitement of the Magnet P3 becomes the switching element in front of it on the second to last disc from below N moved out into the working position and immediately afterwards the shaft L2 by means of the Stepping magnet T2 rotated by one step, d. H. so much that after execution of the step the next vertical row of contact members of the disk N den Magnet P faces. However, since the magnet P, as a result of opening the contact 3 'has lost his excitement in the meantime, there is initially no further adjustment a contact member; on the other hand, the adjusted contact member remains the second from the bottom Row in the working position and therefore takes the frame U2, the rest position of which is ivie above-mentioned, next to the magnet P, by stopping on the contact plate V, with. However, a circuit cannot yet be established via this contact come.

It is now assumed that a further can is now to be conveyed from station 1, namely one intended for station V. This sleeve is therefore inserted into the socket 5 and thereby the contact 5 'is closed. As a result, the magnets P5 and T2 in series now receive a current surge, with the result that the switching element of the uppermost disk N opposite the magnet P5 is now brought into its working position and then the shaft L., including the disks N and the entrained frame U2 through the magnet T2 is rotated one more step counterclockwise. Further bushings can now be introduced into station I. The number of cans sent there may z. B. be four; then the frame U. assumes the position shown in the figure, since it has carried out a total of four steps.

The four cans now travel at any distance in section A of the driving tube between station I and station 11 ' after they have passed the separating device ZR. This separating device serves to secure a certain minimum level between the sleeves. The number of bushes moving in the pipe section can be read on the counting disc Z2 in station II. As you can see from the drawing, the number .4 has become the foremost on this number disc; at this point z. B.: there is a window that reveals the number drum.

If the foremost socket, which, as mentioned, is intended for station III, arrives at station II, the travel contact RI (#j is briefly closed; this creates the following circuit: - @ -, R12, switching element 03, contact plate Vs, P3 (on station III), T3, earth. _ (In the figure it is assumed that the negative pole of the battery is earthed.) By energizing the magnet P3 in station III, the switching element 03 is moved into the working position and Then the shaft L3 is rotated by one step by means of the magnet T3. The excitation of the magnet .I2 pulls the frame U2 down a little - so that this circuit is interrupted again; Gap W of frame U2, and the frame jumps back one step. In this way, the target identifier of the first can is passed on to the switching devices of station III and, at the same time, this target order is passed on to the switching device directions of Station II have been made ineffective. The counting device Z2 now shows a 3, as a sign that now only three cans in the. Pipe section A are on the way. Since the switch W has not been set, the can falls from the receiver outlet of the station II immediately into the transmitter E'2 in order to be conveyed on to the next pipe section.

If no further broadcasts are made, it empties, gradually the pipe section A by inserting one sleeve at a time in the receiver outlet Station II arrives; the travel contact R1 (2 is closed every time, whereby the processes already described are repeated in a corresponding manner.

The third rifle was intended for Station II; As a result, when the travel contact R1 (2 on the part of this socket is closed via the circuit: +, R1 (2, J 02 (in working position), V2, WM2, earth) the turnout magnet Lt'M2 is excited and the turnout W2 is set to discharge. This circuit is immediately interrupted again by the snapback of this frame U2 by one step; however, the switch remains in the working position long enough to safely bring the can to the ejection; then the switch automatically returns to the rest position.

If the fourth sleeve has also left the tube, the one is there Switching device of station II is in the rest position again, since the frame U2 up to in the rest position has jumped back, and there also those switching elements O that had been transferred to the working position in some way, e.g. B. by an inclined guide, have been pushed back radially into their rest position. The display device Z2 is at O.

Are sent from the station II from cans, so to one of the Stations III, IV or V, the corresponding switching processes take place, only that in this case the switching device of station III is influenced.

The arrangement now also enables the intermediate sending of cans of from any station, regardless of whether there are rifles in front of or behind the intermediate point on the way. For example, there will be a rifle on Ward II at any time Introduced into the transmission socket 5 of this station, so with the help of the contact 5 'the magnets P5 and Ts in the switching device of station III are excited and thereby this target order is saved in the switching device. The order of the target jobs is not confused because the target orders are still in the Route section A moving rifles in the switching device III not yet saved are, but there only in accordance with the emergence of the bushes from the first section of the route in this Switching device are brought to storage.

However, precautions have been taken to ensure that the cans coming from section A and passing through station 1I cannot collide with the cans that are thrown into the transmitter sockets 3, 4 or 5 at station II. For this purpose, the moment a bushing passes the travel contact RK, the transmitters 3, 4 and 5 in station 11 are blocked by means of the locking device Sp, in that the winding S111 is energized via the travel contact and the locking slide is closed . This blocking is immediately lifted again if it is a case of a sleeve intended for station 1I itself, i.e. not moving any further, because in this case the switch magnet W, 41 Winding FM of the locking device is made live, which makes the lock ineffective. If the bushing is moving on, the blocking is released again as soon as the bushing reaches contact d.

The transmission facilities of the individual stations can also be in other Be designed so shows z. D. Fig. I on Station III is only one Send sockets 4., 5 for outgoing mail; in this case must be done by pressing a key o. The like. When the rifles leave, it is particularly clear whether the person entering The sleeve is intended for station I4 or station V; this is in the drawing indicated by two button contacts 4 "and 5".

Fig. 2 shows another embodiment of the invention. In this exemplary embodiment, rolling bodies serve as switching means for storing the target orders, to be precise balls of different sizes are used as rolling bodies, in such a way that a group of balls of a certain size is assigned to each target. Fig.2 shows such a switching device working with balls for a station; Corresponding switching devices are also available on the other stations. The balls are stored in slots A, B, C, D. If one of the magnets a, b, c or d receives a current surge at the outlet of these wells, e.g. B. because a can is dispatched to the previous station, a ball is released from the relevant slot; the ball falls into the funnel I_- ', which ends in a tube F. In this tube F, the balls initially remain in the order in which they were released. The individual target orders of the cans embedded in the assigned route section are thus saved. The balls are then released again individually in accordance with the exit of the bushes from the relevant section of the pipe F, under the control of the magnet G, which is influenced by a pipe contact. A ball released in this way falls into the tube H, which has branches e, f, g, h of different size diameters; the ball rolls so far in the tube H until it has found the outlet corresponding to its size and then closes the corresponding contact i, 2, 3, 4 when it falls down; but these contacts are connected to further lines i ', 2' etc., which lead to Magnetena, b etc. of the next station and there cause the release of a ball of the appropriate size. The line 4 ', for example, can be connected to the soft magnet of its own station, so that a ball emerging from the socket e causes the relevant sleeve to be discharged on the spot. It is clear that this device also enables intermediate transmission in a manner similar to that described for FIG.

Claims (6)

YATENTANSi'RÜCHI .: i. Conveyor system with several sections and these associated storage devices with movable switching means, which the target identifier of the containers transported in the section at the same time in their order either at the next receiving point or to the storage facility of the pass on the following section, characterized in that the goal of Movable switching means (O or spheres) in each of the conveying containers Section on special, each belonging to a particular one of the following receiving centers Groups are united and taking into account the order of the conveying containers be brought into an effective position only for the same purpose. 2. Conveyor system according to claim i, characterized by an electrical switching device (T., T3, Fig. I), which takes a step after recording a target identifier and that in each case provides the following switching means of each group for the inclusion of a new target order. 3. Conveyor system according to claim i or 2, marked by a electrical switching device (I2, I3, Fig. i), which after a Target order takes a step when a container arrives at a station, to prepare the next saved target order to take effect. q .. Conveyor system according to Claims 2 and 3, characterized in that the two switching devices work together in such a way that they simultaneously. as a counting device for counting the serve in the associated, section on the way container. 5. Conveyor system according to one of the preceding claims, characterized in that the switching elements (U, V) of the switching device according to claim 3 against .the action of a spring of the switching elements (N, O) of the switching device according to claim 2 in each case Step of the latter and taken under after a target order becomes effective the action of the spring is released by one step in the opposite direction will. 6. Conveyor system according to one of the preceding claims, characterized by locking devices (Sp), by which the intermediate sending of containers is prevented when an onward journey Container passes through the relevant station. Conveyor system according to claim 6, characterized characterized in that the locking device upon arrival of each container at the station is made effective and made ineffective again when either the discharge of the container at this station, e.g. B. the switch is set to discharge is, or -tvif the container leaves the station again on its onward journey. B. conveyor system according to one of the preceding claims, characterized by separating devices (ZR) in the driving tube, which cause a minimum distance between the individual containers is adhered to. G. Conveyor system according to one of the preceding claims, characterized in that that in each station each target station to be loaded from this station is a special one Transmitter is assigned in such a way that the desired goal is achieved simply by introducing one of the containers in a particular one of these. 'sender is marked without that special, the desired target characterizing switching measures' are carried out have to. i o. Conveyor system according to claim i, characterized in that as switching means different types of rolling elements can be used, each of which blends one Target corresponds to (Fig.2).