EP2078569A1 - Method and device for sorting flat posted items by order of route - Google Patents

Abstract

The method involves storing postal mails (P1-P3) in a sorting device with compartments in a sequence-sorting. The postal mails in storage modules (2) differentiated from the compartments by an internal extraction device (32), of a presorting device are presorted. The postal mails are stacked in the storage modules. The sequence-sorting is carried in two sorting operations. The postal mail is removed from the compartments after the sorting operations. A separation unit is delivered as a stack for delivering the postal mails to the storage modules. An independent claim is also included for a device for delivery sequence sorting of flat postal mails.

Description

The invention relates to a method for sequence sorting flat mailings, in which the mailpieces are stored in a sorting device with a number of F compartments sorted in sequence. In addition, the invention relates to a device for sequence sorting of flat mail items with a sorting device having a number of F compartments for storing sorted mail items and a process means for controlling the sequence sorting.

Flat postal items, such as letters, large letters, postcards, shrink-wrapped magazines and the like, are sorted in letter centers or large post offices in very large numbers according to their address and, possibly after a presort, 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 order to be able to sort a large quantity of mailpieces in a short time, a high throughput of the flat mailpieces through the sorting systems is desirable.

In a sequence sorting of the mailings, a high number of mail items is brought from a random order in a predetermined order. The predetermined order may be dependent on the mailing addresses of the mailpieces, for example their delivery addresses. Such a sequence sorting is from the EP 0 634 957 B1 known.

For sorting a sequence of gears, several sorting passes are usually necessary, at the end of which, as a rule, large consignment quantities are stacked manually in a predetermined order Fächern removed and must be put back on a bed of a separating device. In a subsequent sorting process, these already presorted mailpieces can be sorted finer into the compartments. Since a removal of mail items from the subjects is complicated and error-prone, a sequence sorting with few sorting passes is advantageous. To carry out a sequence sorting with many mailing addresses, however, a large number of subjects is required.

It is an object of the present invention to provide a method for sequence sorting flat mailings, with which a sequence sorting to many mailing address can be achieved with a comparatively low error rate.

This object is achieved by a method of the type mentioned, in which the mailings are presorted according to the invention in a number of M memory modules, which differ from the subjects by an internal trigger device, a presorting. By pre-switching the pre-sorting device, the number of sorting passes-and thus a susceptibility to errors-can be reduced or mailpieces can be sorted to a higher number of mailing addresses with the same number of sorting passages.

The pre-sorting is expediently carried out such that sequential emptying of the memory modules into the sorting device-connected to the subsequent sorting of the mailpieces from the memory modules in the sorting device into their compartments-produces the sequence sorting in the compartments. During the sequential emptying of the memory modules into the sorting device, emptying of a first memory module and the formation of a coherent transmission stream from the memory module into the sorting device, followed by a second and then a third memory module and possibly further memory modules. By sorting the mail items in the subjects, so in a row Arranging the mail items in the compartments after the last sorting cycle, the desired arrangement of the mail items in the sequence of one or more deliverers is created.

The sequence sorting, that is, bringing the mail item in a desired order, can be created with a sorting pass, whereby in this case F x M mailing address can be sorted. In most cases, the mail items are placed in the desired order with two or three sorting passes, with the mailpieces then being brought into the desired order by the sequential emptying of the memory modules only in the last sorting pass.

The mailpieces can be postal items of all kinds, the length and width of each being considerably greater than their thickness, e.g. by at least the factor 10. The memory modules are designed for parallel recording of a plurality of mailpieces, expediently at least ten, in particular at least 50, which can be stored in the memory module, in particular stacked on each other. In contrast to the subjects, they each comprise an internal withdrawal device for separating the postal items stored in a storage module into a delivery stream, in particular with equal gaps between the postal items. The presorting device is connected upstream of the sorting device in the transport direction of the mailpieces. The mail items thus first pass through the presorting device and then through the sorting device.

In an advantageous embodiment of the invention, a lower mail item is stacked in the first memory module to be emptied in the sequence, at least one mail item lying above for at least some of the F boxes, and at least one postal item to be emptied in the following empty memory modules each stacked at least one for at least some of the F subjects each more overlying mail piece. As a result, the desired order of the sequence sorting can be easily achieved.

The sorting device can be kept simple if the order sorting takes place in at least two sorting passes and the mailpieces are removed from the subjects after the first sorting pass and fed as stack to at least one separating means for feeding to the storage modules. The feeding can be done manually.

In order to be able to sort to a large number of mailing addresses, for example to 10,000 mailing addresses, each of which can be assigned to a possible delivery address or a mailbox, the sorting device comprises many compartments, e.g. 72 compartments, which are simply designed for cost reasons. In contrast, the memory modules are carried out considerably more expensive to be able to automatically separate the stored in them mailings again. A good ratio of sorting performance to sorting costs can be achieved if the number F of compartments of the sorting device is greater by at least a factor of 2 than the number M of storage modules.

The speed of the sorting process can be increased if the mailpieces are routed via M ₁ ≥ 1 parallel mail feeds to the memory modules and from there into M ₂ ≥ 2 parallel mailings to one segment each of the sorting device. Conveniently, each module is associated with only one segment and only promotes mailings there.

Fast pre-sorting can be achieved if the memory modules are combined in M ₃ ≥ 2 groups connected in parallel and mail items from a mail stream are introduced into memory modules of at least one group and at the same time mail items are removed from memory modules of at least one group.

In an advantageous development of the invention, the sequence sorting is performed in at least two sorting passes, wherein in the first sorting pass sorting in a first sorting mode and in the second sorting pass is sorted into a second sorting mode which differs from the first sorting mode in terms of sorting in the presorting device. A quick pre-sorting can be combined with a fine re-sorting. The sorting device and presorting device are expediently used in both sorting passages. In the second sorting pass, the mailpieces in the memory modules are then advantageously stored in such a way that the sequence sorting is produced by their sequential emptying - combined with the subsequent sorting of the mailpieces by the sorting device.

A high speed of presorting with a sorting resolution of M ₂ can be achieved if the mail items are presorted by the presorting device in the first sorting pass to M ₂ ≥ 2 parallel mailing discharges to one segment, in particular exactly one segment, of the sorting device.

A high sorting performance in terms of grading and / or sorting speed can be achieved by means of a bypass of the presorting device, which bypasses the memory modules and is used for presorting.

Mail items that have been stored in a bin in a bin form a subject content. In order to achieve a high sorting efficiency, it is advantageous if several technical contents are stored in the following sorting cycle in the same m memory modules, with m <M. At m = 4, the sorting method is particularly efficient in terms of efficiency and sorting quality.

If the sorting device has at least two segments, each with a multiplicity of compartments, then with the same advantage, all subject contents expediently become at least one Segments in the subsequent sorting cycle in the same m <M memory modules stored.

In particular, when using a sorting device having a plurality of segments, it is advantageous if a part of the M memory modules is assigned to one segment and another part of the M memory modules to another segment. A high efficiency of presorting can be achieved if it has a bypass in addition to the memory modules, which bypasses the memory modules and is used for sorting.

Here are expediently introduced in the bypass as many mail items, as in two memory modules. The bypass can thus be assigned twice as many addresses as a memory module.

A further advantageous embodiment of the invention provides that mail items are fed to a separating means and from there to the storage modules in sections, wherein the storage modules are emptied into the sorting apparatus after each section. It can be generated a uniform stream of mail to sorter.

Efficient sorting is achieved when a section consists of f> 1 subject matter, with mail items placed in a bin in a sorting pass forming a subject content. Depending on the size of the memory modules, several specialized contents can be stored in the memory modules before they are emptied again. Expediently, this consists of a section of f = n M ₁ technical contents, where n is an integer and the mail items are routed via M ₁ ≥ 1 parallel mail feeds to the memory modules.

The invention also relates to a device for sequence sorting of flat mail items with a sorting device with a number of F compartments for storing order-sorted items Mail items and a process means for controlling the sequence sorting.

It is proposed that the device comprises a presorting device arranged upstream of the sorting device in the transport direction of the mailpieces with a number of memory modules arranged parallel to M, which differ from the subjects by an internal take-off device, for receiving a plurality of mailpieces in parallel. High sorting fineness can be achieved with a small number of sorting passes.

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 view of the memory module FIG. 1 in trigger function,

FIG. 3

a device for sorting flat postal items with a pre-sorting device and a subsequent sorting device,

FIG. 4

another device for sorting flat mailpieces with two mail feeders and a sorting device with two segments,

FIG. 5

a further device for sorting flat postal items during a first sorting sequence of a sequence sorting,

FIG. 6

the device off FIG. 5 during a second sorting pass,

FIG. 7

a further device for sorting flat mail items with large memory modules during a first sorting pass of a sequence sorting and

FIG. 8

the device off FIG. 7 during a second sorting pass.

In FIGS. 1 and 2, a memory module 2 is shown in a schematic representation, in FIG FIG. 1 in an introductory function, and in FIG. 2 in a trigger function. 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} 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 immediately before the roller conveyor 12, or advantageously comb-like manner between the roller conveyor 12 engages.

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 on anti-parallel to the stacking direction the roller belt 12 generates.

The memory module 2 also has a support roller assembly 28, which in the in FIG. 1 shown insertion function is pivoted to an inactive state. It can be moved in the pivoting direction 30 (FIG. FIG. 2 ) is pivoted into its active state and is part of a trigger device 32, which also includes the roller conveyor 12 and for removing the mail P ₁ - P _n from the memory module 2 is used.

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 34 upwards and thus releases the vent opening 16. 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 36, and the mail piece P _n , the leading edge just passes through the discharge opening 16 and is held by a scraper 38 in contact with the roll band 12. The scraper 38 supports the avoidance of double scoops, since its coefficient of friction is matched to the frictional torque acting on the roller conveyor 12 and with a double trigger retains the postal item not in direct contact with the roller conveyor 12. By means of the separating knife 20, a withdrawal pressure is set, which is indicated by the arrow 40.

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 device 42 for sorting the sequence of flat mail items 44, which in FIG. 3 represented by numbers 1A to FG. The device 42 comprises a sorting device 46 with a number of F compartments 48, of which in FIG. 3 five compartments 48 are shown. The number F is arbitrary and can vary from 2 to 300 or even higher. Through a control system 50, the in FIG. 3 is shown only greatly simplified, the mail items 44 are distributed according to their mailing address in the compartments 48. The distribution is controlled by a control means 52, which is embodied in the form of an electronic data processing device.

Upstream of the sorting device 46 is a presorting device 54 with six memory modules 56-66 and a bypass 68, on which the mailpieces 44 can be transported by a separating means 70 to the sorting device 46, bypassing the memory modules 56-66. The memory modules 56-66 are implemented as described for FIGS. 1 and 2.

To carry out a sequence sorting, a guidance of the mailpieces 44 from the separating means 70 to the compartments 48 is controlled by the control means 52 in accordance with the method described below. The sequence sorting is performed in a single sorting pass. The mail items 44 are pre-sorted to the extent that their mailing addresses are present only in an address space with F x 7 predetermined mailing addresses. In this case, a plurality of mailpieces 44 may have the same mailing address.

The presorted, stacked mailpieces 44 are separated by the separating means 70, placed in the form of a mail flow on a mail feed 72 and passed to an address reading means 74. This reads the delivery address and, if necessary, the name or mailbox of the mailings passed by 44 and the control means 52 assigns each delivery address or each mailbox a shipment address to. Subsequently, the mailpieces 44 are distributed to the memory modules 56-66, with all the mailpieces with the mailing addresses xB being stored in the first memory module 56, with 1≤x≤F. Analogously, the mailpieces 44 with the mailing addresses xC are transferred to the second memory module 58 stored, etc., and mail items 44 with the mailing addresses xG in the sixth memory module 66th

In FIG. 3 For example, the mail items 44 are shown in the first memory module 56 as if they were already completely sorted therein according to the mailing addresses 1B, 2B, 3B,..., FB. This strict order is in FIG. 3 only for the sake of clarity. Really, the mail items 44 with the mailing addresses 1B, 2B, 3B,..., FB are randomly mixed up in the memory module 56.

Mail items 44 with the mailing addresses xA are guided by the bypass 68 directly to the sorting device 46 and sorted there into the compartments 48. Hereby, mailpieces 44 with the mailing address 1A will be stored in the first mailing 48, those with the mailing address 2A in the second mailing, etc., wherein each mailing is uniquely associated with a mailing address xA.

If all the postal items 44 contained in the separating means 70 have been separated and all the mailpieces 44 with the mailing address xA have been supplied to the sorting device 46, then the memory modules 56-66 are emptied sequentially, ie one after the other in a predetermined sequence. First of all, the memory module 56 is emptied so that the mailpieces 44 with the mailing addresses xB are guided into the sorting device 46 and sorted there into the compartments 48 as described. Thereafter, the memory modules 58-66 are successively emptied into the sorting device 46, so that now lie in the subjects 48, the mail items 44 in the order xA, xB, xC, ..., xF, where x is the respective subject number. As a result, the sequence of the mailpieces 44 in the compartments 48 which is desired for a sequence sorting is produced.

The mail items 44 can now be removed from the tray 48 for tray 48 in the tray order 1 to F and combined to form a total stack or a plurality of sub-stacks and are in the sequence of, for example, a deliverer.

FIG. 4 shows in a further schematic illustration another device 76 for sorting the sequence of flat mail items 44 with two separating means, 70, 78, two mail feeders 72, 80 and two Sendungabführungen 82, 84 from a pre-sorting device 86 to a sorter 88. The following description of this and the other figures is essentially limited to the differences from the embodiment of the preceding figure, to which reference is made to the same features and functions. Substantially identical components are basically numbered with the same reference numerals.

The presorting device 86 comprises 18 memory modules 56-66, of which only six are shown for the sake of clarity. The sorting device 88 has 200 compartments 48, which are divided into 100 segments each into two segments 90, 92.

On the basis of in FIG. 4 In the following, a speed sequence sorting with a sorting gear is described, wherein also gear sequence sortings with a plurality of sorting gears can be executed on the device 76. Presorted mail items 44 with mailing addresses in an address space of 4000 mailing addresses are singled out in parallel with the singling means 70, 78, are passed to address reading means 74, 94 and sorted into the memory modules 56-66 via the mail feeders 72, 80 or directly to the sorting device 88 via the bypass 68 fed. In the first memory module 56, all the mailpieces 44 with the mailing addresses xy2 are now stored with 0 ≦ x ≦ 39 and y = 0, 2, 4, 6 or 8. By means of the bypass 68, all the mailpieces 44 become with the transmission addresses xu1 passed through with 0 ≤ x ≤ 39 and 0 ≤ u ≤ 9.

Once all the mail has been stored in the memory modules 56-66 or has passed through the bypass 68, the memory modules 56-66 are sequentially emptied, in this case in pairs, one after the other. The storage module 56 is emptied via the mailing discharge 82 only into the segment 92 of the sorting system 88 and at the same time the storage module 58 is emptied via the mailing discharge 84 only into the segment 90. Subsequently, the memory modules 60, 62 are emptied in pairs until the last memory modules 64, 66 are emptied simultaneously. The sequence sorting is completed and the mailpieces 44 can be sorted taken from the compartments 48 and, depending on the size of the transport container, assembled into one or more stacks. Due to the parallel supply and discharge of the mailpieces 44 to the memory modules 56-66, the sequence sorting is performed quickly.

Another device 96 for sequence sorting flat mail items 44 is shown in FIG FIG. 5 shown. It is constructed analogously to the device 76 and comprises six memory modules 56-66 and a sorting device 98 with 70 compartments 48, divided into two segments 90, 92. To carry out a sequence sorting method with two sorting passes, only the two are used in the presorting device 54 in the first sorting pass Segments 90, 92 sorted. For this purpose, presorted mail items 44 with mailing addresses in an address space of 9800 mailing addresses are separated from the two separating means 70, 78 in parallel from one stack and introduced as mailing streams with a plurality of uniformly arranged mailpieces 44 into the mail feeders 72, 80. In the first sorting the bypass 68 and the transport lines shown in dashed lines are not used.

During a first time period, mail items 44 become from the first consignment feeder 72, to which the first segment 90 was assigned by the control unit 52 as a transport destination, guided to the storage module 58 and stored there. Mail items 44 from the first mail feeder 72, to which the second segment 92 has been assigned, are guided to the memory module 56 and stored there. Mail items 44 from the second mailing feeder 80, to which the first segment 90 has been assigned, are guided to the memory module 66 and stored there. And mail items 44 from the second mail feeder 80, to which the second segment 92 has been assigned, are guided to the memory module 64 and stored there.

During the first time period, the memory modules 56, 58, 64, 66 thus fill up with mailpieces 44 according to their statistical distribution according to transport destination and thickness. The degree of filling of the memory modules 56, 58, 64, 66 can be monitored by the control unit 52 with the aid of sensors.

At a time when the memory modules 56, 58 have reached a predetermined degree of filling, eg half full, the first period ends and a second period begins. In this second period, the mail items 44 from the first mail feeder 72 are no longer fed to the memory modules 56, 58, but to the memory modules 60, 62, corresponding to their transport destinations to the memory modules 60, 62. At the same time, the memory modules 56, 58 are emptied by the stored in them mailings 44 as FIG. 2 sporadically described and the consignment discharges 82 and 84 are supplied for further transport into the segment 92 and 90, respectively.

At a further time, one of the memory modules 64, 66 will then be filled, with the other of the memory modules 64, 66 likewise being largely filled. The similarity of the filling levels of the two memory modules 64, 66 depends on the distribution of the mailpieces 44 according to their transport destinations and on the capacity of the memory modules 64, 66.

The larger their capacity, the more similar is their relative degree of filling according to the laws of statistics. Therefore, it is advantageous if the memory modules 56-66 can hold as many mailpieces 44 as possible, e.g. a stack height of at least 500 mm.

At this additional time, the third operating mode in which the mailpieces 44 of the mailer feeders 72, 80 are stored in the memory modules 56, 58 and 60, 62 and at the same time the mailpieces 44 are loaded from the memory modules 64, 66 into the mailing discharges 82, 84 ,

The emptying of the memory modules 64, 66 occurs approximately in half the time as the filling of the other memory modules 56-62, so that the memory modules 64, 66 are emptied when the memory modules 56, 58 approximately half filled and the memory modules 60, 62 approximately are filled. At this point in time, when the memory modules 64, 66 are emptied, the control unit switches to the next operating mode in which the mailpieces 44 are stored in the memory modules 56, 58 and 64, 66 and the memory modules 60, 62 which are still full are emptied ,

If the memory modules 60, 62 are emptied at a next point in time, the control unit 52 switches to the next operating mode, in which the memory modules 60 - 66 are stored and then expelled from the then full memory modules 56, 58.

In this way, in the following between three different modes of operation is changed, in each of which two of three groups each filled with two memory modules 56 - 66 and a group with two memory modules 56 - 66 is emptied. The switching times are made dependent on the filling levels of the memory modules 56-66, in particular on the time of complete emptying of those memory modules 56-66 which are being emptied. The switching time may alternatively, additionally and in particular in a higher command hierarchy of a degree of filling of those memory modules 56 - 66 are set, is being stored in the. If, for example, one of them is completely filled, a changeover of the operating modes is initiated even if one or both of the memory modules 56 to 66 to be emptied are not yet completely emptied.

This pre-sorting creates a uniform flow of mail into the two segments 90, 92, largely independent of the distribution of the mailpieces 44 in the mail feeders 72, 80 according to transport destination, whereby a high throughput is achieved.

A finer sorting takes place only in the sorting device 98. The bins 48 of the first segment 90 are loaded with all the mailpieces 44 with the mailing addresses 2nF + (4f - 3) and 2nF + (4f - 1), where n is an integer between 0 and 69, f is the bin number and F = 70 In the compartments 48 of the second segment 90, all the mailpieces 44 having the mailing addresses 2nF + (4 (f-35) - 2) and 2nF + (4 (f-35)) are loaded. In tabular form: broadcast address 1st segment 2nF + (4f - 3) and 2nF + (4f - 1) 2nd segment 2nF + (4 (fF / 2) - 2) and 2nF + (4 (fF / 2)).

The sorting of the second sorting pass is in FIG. 6 shown. The mail items 44 of the 35 compartments 48 of the first segment 90 are given as 35 sections 100 into the singling means 70 and the mail items 44 of the 35 compartments 48 of the second segment 92 as 35 sections 100 into the singling means 72, eg manually. Now sorting in the presorting device 54 in a different sorting mode than in the first sorting pass.

In a first sorting step, the mailpieces 44 of the first compartments 48 of the two segments 90, 92, ie the compartments Nos. 1 and 36, separated in parallel and into the six memory modules 56-66 and the bypass 68 guided with the following sorting: Subjects No. 1 and 36: broadcast address 1. Memory module 56 2nF + 4, with F / 2 ≤ n ≤ F-1 2nd memory module 58 2nF + 4, with 0 ≤ n ≤ F / 2-1 3. memory module 60 2nF + 2, with F / 2 ≤ n ≤ F-1 4. Memory module 62 2nF + 2, where 0 ≤ n ≤ F / 2-1 5. Memory module 64 2nF + 3, with F / 2 ≤ n ≤ F-1 6. Memory module 66 2nF + 3, where 0 ≤ n ≤ F / 2-1 Bypass 68 2nF + 1, where 0≤n≤F-1.

Numbers 1-4 can be generalized as 1 ≤ m ≤ M / 2 depending on the number M of memory modules 56-66 used, and an existing bypass 68 can be counted as two memory modules 56-66.

After the mail pieces 44 of bins # 1 and # 36 are singulated, the singulation is stopped and the memory modules 56-66 are sequentially emptied into the sorter 88 in pairs, starting with the memory modules 60, 62, following the memory modules 64, 66, finally the memory modules 56, 58.

In a second sorting step, the next two sections 100 with the contents of the bins # 2 and # 37 are singulated and sorted into the memory modules 56-66 and the bypass 68 with the assignments: Subjects No. 2 and 37 broadcast address 1. Memory module 56 2nF + 8, with F / 2 ≤ n ≤ F-1 2nd memory module 58 2nF + 8, where 0 ≤ n ≤ F / 2-1 3. memory module 60 2nF + 6, with F / 2 ≤ n ≤ F-1 4. Memory module 62 2nF + 6, with 0 ≤ n ≤ F / 2-1 5. Memory module 64 2nF + 7, with F / 2 ≤ n ≤ F-1 6. Memory module 66 2nF + 7, where 0 ≤ n ≤ F / 2-1 Bypass 68 2nF + 5, where 0≤n≤F-1.

Thereafter, the mail items 44 are returned to the bins 48 before the third sorting step starts with the contents of the bins # 3 and # 38, and so on. When all 35 or F / 2 sorting steps have been performed, the mail pieces 44 are in the desired order and the sequence sorting is completed.

Depending on the storage capacity of the memory modules 56-66, a plurality of sections 100 can also be processed in a sorting step. An example of this is given in FIGS. 7 and 8. Analogous to FIG. 5 For example, mail items 44 are sorted from an address space having, for example, 128 mailing addresses to the bins 48 of the two segments 90, 92, as in FIG FIG. 7 is shown.

In the second sorting pass, the subject contents are put into the singling means 70, 78 as described. In the first sorting step, two subject contents are each assigned to a section 106 and sorted onto the memory modules 56-66. The two subject contents per memory module 56-66 are arranged in front and in the rear of the respective memory module 56-66. Subsequently, the memory modules 56-66 are emptied in pairs sequentially into the sorting device 104, starting with the memory modules 60, 62, following the memory modules 64, 66, and finally the memory modules 56, 58.

In the second sorting step, the second two sections 106 are first presorted in the memory modules 56-66 and then sorted in the bypass 68 and then in the compartments 48. In this example, the desired order of the mailpieces 44 already exists after the two sorting steps and the sequence sorting is completed.

Claims (18)

Method for sequence sorting flat mail items (44), in which the mail items (44) are stored in a sorting device (46, 88, 98, 104) with a number of F compartments (48) sorted in sequence,
characterized in that the mailpieces (44) are pre-sorted into a number of M memory modules (56-66) different from the bins (48) by an internal fume hood (32), a presorting means (54, 86). Method according to claim 1,
characterized in that in the first in the sequence to be emptied memory module (56 - 66) for at least some of the F compartments (48) lower mailpiece (44) is stacked in the subsequently emptying memory module (56 - 66) at least one for at least some of the F compartments (48) overlying mail item (44) is stacked and in each case at least one for at least some of the F compartments (48) each further overlying mail item (44) stacked in the memory modules to be subsequently empty (56 - 66) becomes. Method according to claim 1 or 2,
characterized in that the order sorting takes place in at least two sorting passes and the mailpieces (44) are removed from the compartments (48) after the first sorting pass and fed as stack to at least one separating means (70, 78) for feeding to the storage modules (56-66 ). Method according to one of the preceding claims,
characterized in that the number F of the compartments (48) of the sorting device (46, 88, 98, 104) by at least a factor of 2 is greater than the number M of the memory modules (56 - 66). Method according to one of the preceding claims,
characterized in that the mail items (44) via M ₁ ≥ 1 parallel mail feeders (72, 80) to the memory modules (56 - 66) and from there into M ₂ ≥ 2 parallel mailings (82, 84) to each one segment (90 , 92) of the sorting device (46, 88, 98, 104) are guided. Method according to claim 5,
characterized in that the memory modules (56-66) are combined in M ₃ ≥ 2 groups connected in parallel and mail items (44) are introduced from a mail stream into memory modules (56-66) of at least one group and at the same time mail items (44) of memory modules (56 - 66) are removed from at least one group. Method according to one of the preceding claims,
characterized in that the sequence sorting is carried out in at least two sorting operations and in the first sorting gear in a first sorting mode and in the second sorting gear is sorted into a second sorting mode, which is different with respect to a sorting in the presorting (54, 86) from the first sorting mode. Method according to claim 7,
characterized in that the mailpieces (44) from the presorting device (54, 86) in the first sorting pass onto M ₂ ≥ 2 parallel mailing discharges (82, 84) to a respective segment (90, 92) of the sorting device (88, 98, 104) be pre-sorted. Method according to claim 7 or 8,
characterized in that the mailpieces (44) are stored in the second sorting pass in the memory modules (56-66) so that the sequence sorting is produced by their sequential emptying. Method according to one of the preceding claims,
characterized in that a bypass (68) bypassing the memory modules (56-66) of the presorting device (54, 86) is used for pre-sorting. Method according to one of the preceding claims,
characterized in that mail items (44) which have been stored in a sorting passage in a compartment (48) form a subject content, and a plurality of subject contents in the subsequent sorting pass are stored in the same m memory modules (56 - 66), with m <M. Method according to claim 11,
characterized in that m = 4. Method according to claim 11 or 12,
characterized in that the sorting device (88, 98, 104) has at least two segments (90, 92) each with a plurality of compartments (48) and all technical contents of at least one segment (90, 92) in the subsequent sorting pass into the same m < M memory modules (56 - 66) are stored. Method according to one of claims 11 to 13,
characterized in that as many postal items (44) as in two memory modules (56-66) are inserted into a bypass (68) of the presorting device (54, 86) bypassing the memory modules (56-66). Method according to one of the preceding claims,
characterized in that mail items (44) are fed to a separating means (70, 78) and from there in sections to the storage modules (56-66), the storage modules (56-66) being moved into the sorting apparatus (88, 98, 104) after each section. be emptied. Method according to claim 15,
characterized in that mail items (44) which have been stored in a sorting passage in a compartment (48) form a subject content, and a section (100, 106) consists of f> 1 subject contents. Method according to claim 16,
characterized in that the mailpieces (44) are routed through M ₁ ≥ 1 parallel mail feeders (72, 80) to the memory modules (56-66) and f = nx M ₁ , where n is an integer. An apparatus for delivery sequence sorting flat mail items (44) having a sorting device (46, 88, 98, 104) with a number of F compartments (48) for storing sequence-sorted mail pieces (44) and a process means (52) for controlling the delivery sequence sorting in extending from the compartments (48) by: - by one of the sorting device (46, 88, 98, 104) in transport direction of the mail pieces (44) upstream pre-sorting facility (54, 86) having a plurality of M parallel memory modules (66 56) an internal deduction device (32) distinguish, for receiving in parallel each of a plurality of mail items (44).

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