EP2067535A1 - Method for sorting flat postal packages - Google Patents

Abstract

The method involves carrying out sorting operations in respective adjacent segments (42, 44). Overflow packages in one of the sorting operations are allocated to a storage module (46f) which is closed due to filling process. The overflow packages are deposited in one of storage modules (46a-46e), and are interposed in a sorting process of one of the sorting operations. Flat postal packages (52) are analyzed before sorting in a packaging time. Undetected postal packages are deposited in other storage modules during the analysis. An independent claim is also included for a device for sorting flat postal package using a sorting device.

Description

The invention relates to a method for sorting flat postal items.

Flat postal items, such as letters, large letters, postcards, sealed magazines and the like, are sorted in letter centers or large post offices in very large numbers by their address and stored in a variety of stacking compartments. The achievable fineness of the sorting is determined by the number of sorting passages and the number of stacking pockets in each sorting pass into which the mailpieces are distributed. In particular, the sorting of mail items in the sequence of orders of one or more deliverers is a process in which, due to the large number of addresses, usually several sorting runs must be made. After the last sorting run, the mailpieces are then in the order in which the deliverers distribute the mailpieces to the addressees.

It is an object of the present invention to provide a method for sorting flat postal items, with which a sequence sorting can be carried out quickly and reliably.

This object is achieved by a method for sorting flat mail items with a sorting device having at least a first and a second segment each having at least N memory modules, wherein in the first segment a first sorting pass and in the second segment a subsequent second sorting pass is performed In the first sorting overflow programs, which are assigned to a closed storage module due to filling, stored in one of the other memory modules and inserted into the sorting process of the second sorting cycle. With the help of the sorting device with at least two segments, the Sequence sorting be carried out quickly. By storing the overflow transmissions in the further memory module, a reserve volume in the memory modules can be kept small and thus a large number of mail items can be sorted simultaneously. The inclusion of the overflow messages in the sorting process, suitably controlled by a process means, allows to keep the number of incorrect sorting low.

The sorting is expediently a sequence sorting. Sequence sorting may be performed by placing a plurality of mailpieces from a random order into a predetermined order. The predetermined order may be dependent on the mailing destinations of the mailpieces, eg their delivery addresses. A sorting process can be understood as a sorting process in which a plurality of mail items are distributed to memory modules as a function of their mailing destinations. In a subsequent sorting process, these already presorted mailpieces-possibly less rejected mailpieces-can be sorted more finely and sorted into the memory modules of the second segment for this purpose as well, depending on their mailing destinations. Depending on the number N of memory modules in each segment and the number n of sorting passes, the sequence sorting of a maximum of N ⁿ addresses is possible.

The mail items can be postal items of all kinds for mailing, whose length and width are each considerably larger than their thickness, for example by at least a factor of 10. The memory modules are designed to receive a plurality of mailpieces, expediently at least ten, in particular at least 50 can be stored in the memory module, in particular stacked on each other. The memory modules are advantageously last-in-first-out modules, that is to say those memory modules in which the last stored mail item is first again stored out of a multiplicity of mailpieces, ie it is removed from the memory module. Many postal items can be loaded and unloaded quickly, reliably and inexpensively.

A closed storage module due to filling can be understood to mean one that is characterized by a process means for controlling the sorting such that no mail item is to be introduced into this memory module due to sufficient filling. The marking can be an electronic signal. The overflow mailings may be mail items that would be stored in the closed storage module if it were not closed. The depositing can be done by stacking. An insertion into the sorting process of the second sorting pass can be done by singulating from a storage module and introducing it into the sorting process of the second sorting pass.

In an advantageous embodiment of the invention, the mail items are examined prior to sorting for a broadcast destination out and not detected in the investigation shipments are stored in a dedicated memory module, the overflow messages are stored in the same memory module. The unrecognized programs can be separated and grouped with very little effort, so that they can be presented to a postman in a group. The memory module provided for this purpose is advantageously a memory module of the first segment. The shipment destination may be a delivery address.

If a second detection attempt with previously unrecognized programs is undertaken before the second sorting pass, then a high recognition rate can be achieved. The newly identified programs in the second detection attempt can be inserted into the memory module assigned to the recognized transmission destination and fine-sorted in the following sorting cycle.

Collisions of mailpieces can be avoided if the overflow transmissions, and in particular also the unrecognized mailpieces, are transferred to a memory module of the second segment before the recognition attempt. Also, you can continue Unrecognized programs are stored in the designated memory module of the first segment.

The overflow messages can be inserted into the sorting process quickly and with little effort if they are inserted into the sorting process in the second sorting pass immediately before or after the emptying of the closed memory module.

Unrecognized mailpieces can simply be kept separated when placed in a memory module of the second segment. The storage module of the second segment is expediently provided as an overflow module.

In a further embodiment of the invention, the overflow transmissions are stored in the first sorting pass into a memory module of the second segment. A separate memory module for overflow transmissions can be dispensed with.

Advantageously, the overflow transmissions between the first and the second sorting pass are stored in at least one partially occupied memory module of the first segment as foreign mailpieces. In this way, it is also possible to dispense with a separate memory module for overflow transmissions in the second segment. The thus occupied memory module thus houses previously mail items that are originally assigned to him and sorted into it, and subsequent overflow broadcasts.

The memory module that is externally assigned to overflow transmissions is advantageously a memory module that is provided for emptying after the closed memory module in the second sorting pass. When emptying the memory modules of the first segment in the second sorting pass, a blockage of the externally allocated memory module due to overflow transmissions can be avoided.

In a further embodiment variant of the invention, the memory module, which is emptied last in the first sorting pass, is assigned a smaller target area before the first sorting pass than before, in particular as all previous ones. In this way it can be avoided that the last memory module overflows and the overflow transmissions can not be sorted into a subsequent memory module. The destination area may specify a statistical mail quantity in the memory module and is e.g. a postal code area or a number of addresses.

In another embodiment variant of the invention, the overflow transmissions are deposited as foreign mail items during the first sorting cycle into at least one partially occupied storage module of the first segment. In this way, the sequence sorting can be carried out particularly quickly.

Advantageously, mail items that are originally assigned to the foreign-occupied storage module according to the foreign assignment are stored in at least one further storage module of the first segment as foreign mailpieces. Thus, a mixing of mail items that are assigned to different memory modules can be avoided. As at the time of a specialist overflow usually only a small proportion of the consignment is to be sorted, including only a few mail items that are intended for the meantime additionally filled with mail from the overflowed memory module memory module. If this is the case, these mail items are expediently in turn directed into a memory module, from which is sorted again in the subsequent sorting process for the affected memory module, etc. In this way, the probability that still come mail items that are assigned to the last affected memory module, ever smaller. If the memory modules downstream of the subsequent sorting pass are not sufficient, a memory module of the second or other segment can be used before the last memory module is reached.

In order to avoid a blockage when emptying the memory modules in the subsequent sorting cycle, the externally occupied memory module is expediently a memory module that is provided in the second sorting channel for emptying after the closed memory module. The emptying is expediently a complete emptying. The further externally occupied memory module is advantageously provided for emptying after the first externally occupied memory module.

Despite overflow, the sorting can continue to be carried out reliably if, in the case of a storage module with overflow transmissions, the overflow transmissions are first emptied out of the storage module, then another storage module is emptied and then the former storage module is completely emptied.

The invention is also directed to an apparatus for sorting flat postal items. It is proposed that the device comprises a sorting device which has at least a first and a second segment, each having at least N memory modules, and additionally a processing means provided for this purpose, a first sorting pass in the first segment and a subsequent second sorting pass in the second segment to control, wherein the processing means is additionally provided to control in the first sorting a transfer of overflow messages associated with a memory module closed due to filling, in one of the other memory modules and the subsequent insertion of the overflow messages in the sorting process of the second sorting cycle.

All control steps necessary for further described details of the invention can be initiated by the processing means, which is then prepared accordingly.

Advantageously, the device comprises a circulation conveyor for transporting the mailpieces from one segment to the other segment. The mail can be transported reliably and quickly from one to the other segment.

The invention will be explained in more detail with reference to exemplary embodiments, which are illustrated in the drawings.

Show it:

FIG. 1

a top view of a memory module in insertion function

FIG. 2

a top view of a memory module and trigger function,

FIG. 3

a device for sorting flat objects with two segments each having eleven memory modules,

FIG. 4

the device off FIG. 3 in which mail has been sorted from the first segment to the second segment,

FIG. 5

another device for sorting flat objects with two segments, each with ten memory modules,

FIG. 6

the device off FIG. 5 in which overflow transmissions have been sorted from a memory module of the second segment into the first segment,

FIG. 7

the device off FIG. 5 in which mail has been sorted from the first segment to the second segment,

FIG. 8

the device off FIG. 5 after a third and last sorting pass,

FIG. 9

the device off FIG. 5 in which in the first sorting overflow shipments were sorted into already occupied memory modules of the first segment. the and

FIG. 10

the device off FIG. 9 in which mail items were sorted from the first segment to the second segment.

1 shows a schematic representation of a view of a memory module 2, which in the in FIG. 1 shown representation in an insertion function works. The memory module 2 is a last-in-first-out module in which the last-introduced mail item is executed first. It comprises a memory area 4, in which mailpieces P ₁ , P ₂ , P ₃ ,... P _n-1 are currently stored. In the illustration shown, the mail item P _{n will be} the next mail item transferred to the storage area 4. It is fed between two feed belts 6, 8 to the storage module 2 in the conveying direction 10 and then taken over by a roller conveyor 12. The roller conveyor 12 is driven in a controlled manner and conveys the mailpieces P ₁ , P ₂ ,... P _n-1 to a feed stop 14, whereby the mailpieces P ₁ , P ₂ , P ₃ ,... P _n-1 then located in a precisely defined position in the storage area 4 relative to their front and lower edges. The Zuführanschlag 14 blocked in the in FIG. 1 shown position also has a vent opening 16, which - as indicated by an arrow 18 - is led to just before the roller conveyor 12.

For the mail items P ₁ , P ₂ , P ₃ ,... P _n , it makes sense if they are brought into contact with the roll band 12 with a certain supply pressure. To set this Zuführandrucks a separating blade 20 and a bottom flange 22 are provided, which are very finely adjustable in the insertion of the memory module 2 in the stacking direction - ie the direction in which the stack in the storage area 4 increases - according to arrows 24, 26 are movable. By means of the separating knife 20, the Zuführandruck is generated in anti-parallel to the stacking direction on the roller conveyor 12.

The memory module 2 also has a support roller assembly 28 on, in the in FIG. 1 shown insertion function is pivoted to an inactive state, and in the pivoting direction 30 ( FIG. 2 ) can be pivoted to its active state.

In FIG. 2 the memory module 2 is shown in its trigger function. The support roller assembly 28 is in eingeschwenktem, active state and ensures that the next deducted mail item P _n is aligned in a plane that corresponds substantially to the plane defined by the roller conveyor 12 level and in the vicinity of the memory module 2 of the further conveying direction. The Zuführanschlag 14 is moved in trigger function according to arrow 32 upwards and so the exhaust port 16 free. In the FIG. 2 shown snapshot shows the mail piece P _{n + 1} , which is already fully withdrawn and transported in a take-off direction 34, and the mail piece P _n , the leading edge just passes through the discharge opening 16 and is held by a scraper 36 in contact with the roller belt 12. The scraper 36 supports the avoidance of double prints, since its coefficient of friction is matched to the force acting on the roller conveyor 12 friction torque and holds in a double trigger not standing in direct contact with the roller conveyor 12 mail item. By means of the separating knife 20, a withdrawal pressure is set, which is indicated by the arrow 38.

In order to be able to reliably ensure the at least largely vertical orientation of the mail items stored in the storage area 4 as the emptying of the storage module 2 progresses, the underfloor belt 22 is driven as indicated by an arrow and displaces the mail items stored in the storage area 4 in cooperation with the prestressed severing knife 20 ,

FIG. 3 shows a schematic representation of an apparatus 40 for sorting flat mail items with two segments 42, 44 each having M = 11 memory modules 46a - 46k, 48a - 48k, a separating means 50 for separating mailpieces 52, a reading means 54 for reading delivery addresses of the mailpieces 52 and a transport means 56 for transporting the mailings 52 from the separating means 50 to the memory modules 46a-48k. The device 40 is set up to carry out a sequence sorting process and comprises a process means 58, which is indicated only schematically, for controlling the sorting methods which are carried out by the device 40. Memory modules 46a-48k are as described with respect to FIGS. 1 and 2. The separating means 50 serves to transfer mailpieces 52 from a stack into a mail stream in which the singulated mailpieces 52 are transported at a uniform distance. The transport means 56 is a circulation conveyor which transports the mailpieces of the mail flow into the memory modules 46a-k, from there into the memory modules 48a-k and back to the memory modules 46a-k.

In the in FIG. 3 illustrated embodiment, a plurality of mail items 52 are sorted into a sequence of a delivery service. The delivery addresses of the mailpieces 52 are arbitrarily distributed in an n-dimensional address space of N ⁿ addresses, wherein a delivery address may include multiple addresses, possibly also the other way round. In this embodiment, let N = 10 = M-1 and n = 3, where n is the number of sorts. Both N and n can be chosen differently. By their delivery address and thus their address to be produced by the sequence sorting order of the mailings 52 is precisely defined, the order of mailings 52 with the same address is arbitrary.

After separating, the mailpieces 52 are fed to the circulation conveyor and pass through the reading means 54a, which optically detects the delivery address of the mailpieces 52 and forwards corresponding data to the processing means 58. In the processing means, an assignment of delivery addresses to addresses is stored, so that each item of mail is assigned an address in the address space, that is, for example, a number from 1 to N ⁿ can. The addresses are n-digit numbers xxx with 0 ≤ x ≤ N-1. Now the mail items 52 are respectively assigned to one of the N right memory modules 46a-j corresponding to the last position of their address, wherein the left memory module 46k serves as an overflow module and initially remains without mailpiece 52.

It may happen that the processing means 58 can not determine a delivery address from the data transmitted by the reading means 54 and that the corresponding mail item 52 can not assign an address and thus no memory module 46a-j. These mailpieces 52 are then assigned to the memory module 46k. In FIG. 3 these mail items 52 are indicated by dashed lines. In accordance with their assignment to the memory modules 46a-k, the mailpieces 52 are now transported by the circulating conveyor to the corresponding memory modules 46a-k and stored therein.

The number of mail pieces 52 sorted in the sequence sorting is set from the outset so as to fall below the storage capacity of all the memory modules 46a-k together. With a uniform distribution of the mailpieces 52 to the N ⁿ addresses, the memory modules 46a-j would thus be uniformly occupied, eg, 80%, so that 20% serves as a reserve for an unequal distribution. If the unequal distribution is greater, one of the memory modules 46a-j is filled to such an extent at a time that it is marked as closed by the processing means 58. The tag may be an electronic tag in the processing means 58. The filling of the memory modules 46a-j can be detected by corresponding sensors for determining a degree of filling or by the processing means 58 alone, which estimates the degree of filling of a memory module 46a-j on the basis of the mailpieces 52 stored in it.

At the in FIG. 3 illustrated embodiment are unequal many mailings 52 with delivery addresses, which is assigned an address with a 5 in the last digit, so that the memory module 46f during the first sorting cycle overflows and is marked accordingly by the process means 58 at this time.

From this point in time, postal items 52 having an address which have a last digit are assigned to the storage module 46k and stored there. Unidentified mailpieces 52 are also stored further in this overflow module, as indicated by the lowest dashed mail item 52 in FIG FIG. 3 is indicated. After completion of the first sorting process, the mailpieces 52 are sorted as in FIG. 3 is shown.

There is now the possibility that the unrecognized mailpieces 52 are again checked for identifiability before the second sorting pass. For this purpose, the mail items 52 are transferred from the overflow module into a memory module 48a-k of the second segment 44, e.g. into the memory module 48k, so that postal items 52 can be withdrawn from the storage module 48k and at the same time others can be stored again in the storage module 46k.

The mail items 52 are then transferred by the circulation conveyor from the second segment 44 back into the first segment 42 and pass on the way to the first segment 42, the reading means 54a. Previously unrecognized mailpieces 52 with sufficiently readable delivery addresses are then stored according to their delivery address or address in memory modules 46a-j, and furthermore unreadable mailpieces 52 and overflow transmissions are again stored in the memory module 46k.

The then subsequent second sorting is based on the representation in FIG. 4 explained. First, the storage module 46j is emptied and its mailpieces 52 are transported as a uniform mail flow from the circulation conveyor into the second segment 44. On the way there they pass a second reading means 54b for recognizing their delivery addresses. In the second segment 44, they are stored according to the second position of their address in the corresponding memory modules 48a-j. Then, in turn, the memory modules 46i, 46h, etc. are emptied and moved accordingly until the overflowed memory module 46f is deflated. Immediately after it has been emptied, the overflow module 46k is emptied, so that the mailpieces 52 with a number 5 in the last position of their address are successively sorted into the second segment 44. The unrecognized mailpieces 52 are stored in the memory module 48k, which can also serve as an overflow module when one of the memory modules 48a-j overflows.

Subsequently, the third sorting pass is carried out analogously to the second, in which the mailpieces 52 are sorted into the first segment 42 to the first position of their address. Now, the mailpieces 52 can be sequentially extracted from the memory modules 46a-j and are in the desired order. The unidentified mailpieces 52 are hereby separated and can be taken by the deliverer first and sorted by hand to the others.

FIG. 54 shows another device 60 for sorting flat postal items 52. The following description is essentially limited to the differences from the exemplary embodiment in FIGS. 3 and 4, to which reference is made with regard to features and functions that remain the same. Substantially identical components are basically numbered with the same reference numerals.

This device 60 comprises two segments 42, 44 with only N = 10 = M memory modules 46a-48j each, with no separate overflow module. Mailings 52 with insufficient readable delivery addresses are assigned the address 000 so that they are stacked in the storage module 46a, as indicated by the dashed lines. In the in FIG. 5 the memory module 46f again runs over. The overflow transmissions are now stored in a memory module 48a-j of the second segment 44, eg in the memory module 48j. As last "quasi-mailing" a separator card 62 with the address 000 is sorted.

In FIG. 6 It is shown that the overflow transmissions between the first and second sorting pass are now inserted into those memory modules 46a-e which still have sufficient storage space, for example into the memory modules 46d and 46e, as indicated by dashed lines in FIG FIG. 6 is indicated. These memory modules 46a-e must be those which are emptied in the subsequent sorting process after the overflowed memory module 46f.

The second sorting pass is in FIG. 7 shown schematically. In succession, all the memory modules 46a-j are emptied, wherein after the emptying of the memory module 46f, the memory module 46e is initially only emptied so far that only overflow transmissions are stored out. Then the memory module 46d is emptied immediately, but only so far that only overflow transmissions are stored out. Then the memory module 46e is completely emptied, then the memory module 46d and so on. In this way, all the mailpieces 52 with a 5 in the last position of their address are successively sorted into the second segment 44.

After the third sorting pass in FIG. 8 is indicated, are all unrecognized mail 52 at the beginning of all mail 52 in the memory module 46j and can be taken by the deliverer first and sorted by hand. The divider card 62 indicates the end of the undetected mail 52 area.

A further sorting method is explained below with reference to FIGS. 9 and 10, wherein the following description is in turn essentially limited to the differences from the exemplary embodiment in FIGS. 5 to 8.

Overflow messages remain in the first segment 42, so that the second segment 44 remains free and can possibly be used for other processes. You will be in that - in unloading order - Subsequent memory module 46e sorted, as indicated by the dashed lines. In this foreign occupied memory module 46e then no more mailings 52 can be sorted, which are assigned to this memory module 46e originally, so have a 4 at the last position of their address. They are therefore sorted into the subsequent memory module 46d, as is also indicated by the dashed lines. In this then no more mailings 52 can be sorted, which are assigned to this memory module 46d original, so that they are then sorted into the subsequent memory module 46c, etc. Since at the time of a specialist overflow usually only a small proportion of broadcasting is still sort , only relatively few mailpieces 52 are sorted by outsiders. If the memory modules 46a-e downstream of the subsequent sorting pass are not sufficient, a memory module 48a-j of the second segment 44 can be used before the last memory module 46a is reached.

In the subsequent sorting cycle, the memory modules 46a-j are emptied as in FIG FIG. 10 is indicated, so that the memory modules 46a-j are emptied in sequence. The unrecognized mailpieces 52 are again at the beginning of the overall order of all mailpieces 52.

Claims (15)

Method for sorting flat postal items (P ₁ -P _n , 52) with a sorting device having at least a first and a second segment (42, 44) each having at least N memory modules (46a-48k), in which in the first segment (42) a first sorting pass and in the second segment (44) a subsequent second sorting pass is performed, wherein in the first sorting overflow transmissions assigned to a memory module (46f) closed due to filling are stored in one of the other memory modules (46a-e, 46k) and in inserting the sorting process of the second sorting pass. Method according to claim 1,
characterized in that the mailpieces (P ₁ - P _n , 52) are examined prior to sorting for a mailing destination and in the investigation unrecognized mail items (46a - 48k) are stored in a dedicated memory module (46k, 48k), wherein the overflow messages are stored in the same memory module (46k, 48k). Method according to claim 2,
characterized in that before the second sorting a second detection attempt with previously unrecognized mail items (52) is undertaken. Method according to claim 2 or 3,
characterized in that the overflow transmissions prior to the detection attempt in a memory module (48k) of the second segment (44) are rearranged. Method according to one of the preceding claims,
characterized in that the overflow messages in the second sorting passage are inserted into the sorting process immediately before or after the emptying of the closed storage module (46f). Method according to one of the preceding claims,
characterized in that the overflow transmissions in the first sorting pass are stored in a memory module (48k) of the second segment (44). Method according to one of the preceding claims,
characterized in that the overflow transmissions between the first and the second sorting pass are deposited in at least one partially occupied memory module (46d, 46e) of the first segment (42) as foreign mailpieces (P ₁ - P _n , 52). Method according to claim 7,
characterized in that the memory module (46d, 46e) externally allocated to overflow transmissions is a memory module (46d, 46e) provided in the second sorting passage for emptying after the closed memory module (46f). Method according to one of the preceding claims,
characterized in that the memory module (46a), which is emptied last in the first sorting, before the first sorting pass a smaller target area is assigned, as before. Method according to one of the preceding claims,
characterized in that the overflow transmissions during the first sorting pass in at least one partially occupied memory module (46e) of the first segment (42) as foreign mail items (P ₁ - P _n , 52) are stored. Method according to claim 10,
characterized in that mail items (P ₁ -P _n , 52), which are assigned to the foreign-occupied memory module (46e) according to the foreign assignment, in at least one further memory module (46d) of the first segment as foreign mail items (P ₁ - P _n , 52) are stored. Method according to claim 10 or 11,
characterized in that the externally occupied memory module (46e) is a memory module (46e) which in the second sorting pass is provided for emptying after the closed memory module (46f). Method according to one of the preceding claims,
characterized in that, in a memory module (46d, 46e) with overflow transmissions, first empty the overflow transmissions from the memory module (46d, 46e), then dump another memory module (46c, 46d) and thereafter completely emptying the former memory module (46d, 46e) , Device for sorting flat postal items (P ₁ -P _n , 52) with a sorting device having at least a first and a second segment (42, 44) each having at least N memory modules (46a-48k), and a processing means (58) , which is intended to control a first sorting pass in the first segment (42) and a subsequent second sorting pass in the second segment (44), wherein the processing means (58) is provided to store overflow transmissions in the first sorting pass Fill are closed memory module (46f) assigned to one of the other memory modules (46a - e, 46k) and to control the subsequent insertion of the overflow messages in the sorting process of the second sorting pass. Device according to claim 14,
characterized by a circulation conveyor for transporting the mailpieces (P ₁ -P _n , 52) from one segment (42, 44) to the other segment (42, 44).

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