DE1456727C3 - Information store for a conveyor device - Google Patents

Description

The invention relates to a memory arrangement for storing information in the form of a code, the Is assigned to objects that move in a circulating system that consists of a main conveyor and at least one auxiliary conveyor device co-operating with part of the main conveyor device forms a closed circuit, at several points of the conveyor Scanning points are arranged for detecting the passage of an object at the point in question and the sampling points supply control signals for the write-in and read-out operations of the memory arrangement.

In such a memory arrangement, the code of the object before it enters the with the auxiliary conveyor device common part entered by an operator in this memory, and when the object arrives at the end of this common orbit, this code must be repeated are read out in order to be able to decide whether the object is passed out to an output device or is given to the auxiliary conveyor. When information is stored and then has to be read out again for later interrogation, the information is usually in a Shift register written and periodically, e.g. B. on command of a timing pulse generator from a memory cell shifted to the next memory cell so that the information flows through all memory cells of the register migrates through until it reaches the end cell. If the information is not the code you want corresponds, it is erased or written back into the shift register by means of feedback, so that it can be queried again at a later point in time.

However, this type of information treatment can be used in the case of the conveying device specified at the beginning Difficulties lead.

From US Pat. No. 2,728,466, a conveying device is known which also consists of a main conveying device and an auxiliary conveying device which forms a closed circuit with a part of the main conveying device. In this known device, however, several output points are provided in the common part of the conveyor device, and the operator at the beginning of this common part enters a mechanical memory at which point the object is to be output. The mechanical memory contains a pin wheel for each object that can be located in the common part, the pins of which are set by input according to the position to be output. The pin wheels are all operated synchronously with the conveyor. If an output point is still occupied by the previous objects, the object continues into the auxiliary conveyor device, arrives again at the beginning of the common part, and the operator has to re-enter where the object that has been turned is to be output, just as with a newly arriving object.
In this known device, the operator must therefore know exactly at which of the dispensing stations the objects for a particular customer, for example, are collected, and he must constantly observe whether the number of objects for this customer is already complete. This can easily lead to difficulties, especially with objects that return to the beginning via the auxiliary conveyor device. In addition, the synchronism of the pin wheels with the conveyor is not easy to maintain.

The invention is based on the memory arrangement specified at the outset and aims to provide this memory device to be designed in such a way that information can be selectively extracted or written in, without this information having to be shifted one after the other through the memory, and in which the codes, which are assigned to the objects that are in both the main conveyor and the Auxiliary conveyor are located, according to the location of these objects in the store correctly are. This object is achieved by the invention in that the memory arrangement consists of one of the sampling points of the circular part of the main conveyor device controlled main memory and one of the scanning point the auxiliary conveyor controlled auxiliary memory consists that in the main memory the code information externally or the read information from the auxiliary memory can be written in and read out by itself or the information read from the main memory is used to write the auxiliary memory, and that the main and auxiliary storage locations can be written in or read out independently of one another.

Information memory in which information is received in the order in which it is received in a conveyor section Goods to be conveyed are stored and read out in the same order if the goods are to be conveyed Leave conveyor section again, are z. B. from DT-PS 901 158 known. The storage locations are included can be written in and read out independently of each other.

The information is usually supplied to the memory in binary-coded form and by z. B. Photocells, which are arranged in the sampling points, generated signals, the times can be determined

those on which information has to be written to or read from the memory (cf. FR-PS 1 354 124).

Embodiments of the invention are explained with reference to the drawing. It shows

F i g. 1 schematically the arrangement of a conveyor belt system,

F i g. 2 shows the arrangement of the associated memory.

In Fi g. 1 it is assumed that the conveyor belt system is to be used in a warehouse, in the trays or boxes at several loading points are filled with goods in different quantities have to. It can e.g. B. be a central warehouse to supply several shops, with the orders are different for each store because the stores do not need the same quantities. Because the trays have a limited size, the goods cannot be loaded on a single tray for a store, so that several trays have to be loaded for each store. The loading points are operated by a Conveyor belt on which the trays are loaded, supplied with goods. At the end of the tape, the for , j the individual stores collected certain trays and loaded into vans for shipment to stores. The distribution of goods for each store will be carried out at the beginning of the day and, if this is necessary for processing at the loading points, by automatic means, e.g. B. an electronic calculating machine analyzed.

The conveyor belt 1 runs past five loading points 2, 3, 4, 5 and 6, where trays filled with goods appear the tape will be given. The belt runs in the direction indicated by the arrow to a receiving point 8. However, before the trays reach this point 8, they must pass a person operating a keypad 9. This takes note of the store, for which the goods are intended on a tray running along it on the conveyor belt, and presses on an associated combination of keys of the field 9, so that the tablet in coded form characterizing information is generated, which in FIG. 2 is written to the memory shown. the Information generated by the keypad is not written to memory until the tablet is on the 'The conveyor belt has continued to run and has interrupted a light beam from a source 10 which is directed to a photocell 11 is directed.

The tray continues to run on the belt until it reaches a light beam generated by a source 12 and directed onto a photocell 13. The pulse which is generated by the interruption of the light beam caused by the tray causes an interrogation of the memory as to whether the tray is intended for the shop for which goods are currently being collected at the receiving point 8. If z. B. the tray is intended for the shop B , but at the time when it reaches the light source 12, the receiving point 8 collects only trays intended for the shop A , the tray is directed onto an auxiliary conveyor belt 14 in the form of a loop and to one previous point of the main conveyor belt. At the same time, the memory takes note of the fact that the tablet is in the loop. The tray moves in a loop until it interrupts a light beam generated by a source 15 and directed onto a photocell 16. This indicates that the tray has reached the light source 15 and that as soon as a gap appears in the occupation of the main conveyor belt, the tray is placed on this main conveyor belt, namely in section 17, of which fact the store takes note.

When the tray now again reaches the light source 12 and the receiving point 8 has collected all the trays intended for the store and is now collecting trays for the store B , the tray goes straight to point 8, which is appropriately noted in the memory.

The memory according to FIG. 2 consists of a main memory R and an auxiliary memory S. Each memory has 112 memory cells into which information can be written via a tablet, the memory R containing information about the part 17 of the main conveyor belt and the memory 5 containing information about the loop 14. The memory R is monitored by two memory markers, one for the information about the tray next to the light source 12, which is referred to as the start marker 21, and a second for the information about the tray next to the light source 10, the end marker 22 is designated. The auxiliary memory S has a corresponding end marker 23 and a corresponding start marker 24. These markers move along the memories in the direction indicated by arrow A for main memory R and in the direction indicated by arrow B for auxiliary memory S. If a marker has reached the end of a memory, it starts again at the other end, so that it revolves around the memory as it were in a loop.

The two stores can be part of a larger one Form memory that is used for other computing purposes in the conveyor belt system. In this case it must another marker may be provided to mark the boundaries of each store.

Assuming that the final marker 22 marks the cell /? 109 as the next empty cell when a tablet is registered on the keypad 9 for the shop B , when the tablet interrupts the light beam generated by the source 10, the information becomes fed into the marker 22 so that it moves one position further and marks the cell A1. When a tray for shop A has reached the light beam 12, if the light beam is interrupted by the tray, an interrogation signal is fed to the marker 21 together with the information that the receiving station 8 collects trays intended exclusively for shop A. The start marker 21 interrogates cell A3, which is at the head of the queue (with information written in all cells /? 4 to Ä109, while cells Ri and R2 and cells /? 110 to Al 12 are empty), and if he notices that the tray located at the end of part 17 of the conveyor belt is intended for shop A , he supplies an output signal via line 25, which has the effect that the tray is conveyed to receiving station 8. When this signal has been generated, cell R3 is evacuated and initial marker 21 advances to mark the next cell A4.

If it had been found when interrogating cell Ri that the tray at the end of part 17 was intended for shop B and not for shop A , another output signal would have been given via line 25, which would deflect the tray onto the auxiliary conveyor belt 14 would result. At the same time, the information present in cell R3 would be transmitted via the tablet to the final marker 23 of the auxiliary memory 5 via the line 26. These

Information would be in an empty cell, in this case cell 5108, at the end of the queue in auxiliary storage be written, and the final marker 23 would have moved on to the next cell 5109 to mark.

If there are several trays in the loop, a corresponding number of cells in the memory 5 is occupied. If the information about the tablet at the head of the queue is contained in cell S2, then when the tablet interrupts the light beam generated by the source 15, the initial marker 24 queries cell 52, and when the tablet comes out of the loop 14 Moved in the main part of the conveyor belt, the start marker 24 transmits via the line 27 the information stored in the cell 52 to the end marker 22, which, when the tablet passes the photocell 11 , writes the information in the cell, which at that moment is marked by him (Λ109 in Fig. 2). When the information has been transferred from cell S2 , the header advances to mark cell S3.

If it is in the conveyor belt part 17 or in the loop 14 there are no trays, the start marker and the end marker coincide and the partial memories remain empty until the presence of a tray is detected. Because no correlation between tape movement and marker movement is required because the order of the trays is known there is no risk of errors due to changes in belt speed or slippage between the belt and the trays. It is therefore always certain that the first tray, its presence is detected by the photocell 13 which is the tray marked by the initial marker 21, regardless of the Speed of the belt.

For error control, a tray with an easily identifiable feature can be kept in the loop circulate, the entry of which into the memory is accompanied by a separate bit that identifies the Indicating trays.

For this purpose 2 sheets of drawings

Claims (1)

Claim: Memory arrangement for storing information in the form of a code, which is assigned to objects that move in a circulation system, which consists of a main conveyor device and at least one auxiliary conveyor device, which together with a part of the main conveyor device forms a closed circuit, wherein at several points of the conveyor device Scanning points are arranged to detect the passage of an object at the point in question and the scanning points supply control signals for the writing and reading processes of the memory arrangement, characterized in that the memory arrangement consists of one of the scanning points (10, 11 and 12, 13) of the circular part (17 ) the main conveyor device (1) controlled main memory (R) and an auxiliary memory (S) controlled by the scanning point (15, 16) of the auxiliary conveyor device (14) that the code information from the outside or the information read out of the auxiliary memory into the main memory (R) ichers (S) can be written in and read out by itself or the information read from the main memory (R) is used to write in the auxiliary memory (S), and that the main and auxiliary memory locations can be written in and read out independently of one another.