JPH06104504B2 - Article merging method and device - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to an article merging method and an apparatus for merging articles stored in a plurality of merging storage lines, and particularly, to a transportation interval of articles after merging. The present invention relates to an article merging method and an apparatus for merging articles so that the merging ability (number / time) can be made substantially constant regardless of the size of the articles.

[Conventional technology]

As a conventional technique relating to a method of joining articles and a device thereof, Japanese Patent Publication No. 58-23294, Japanese Patent Publication No. 51-20358,
Those described in JP-A-51-151954 and JP-A-59-69314 are known.

The description of the above publication is briefly described in Japanese Examined Patent Publication No. Sho 58-2329.
No. 4, gazette, in order to improve the blending balance of sending articles from each tributary conveyor to the mainstream conveyor, after sequentially delivering articles from the downstream tributary conveyor of the mainstream conveyor to the upstream tributary conveyor, the upstream side It is described that articles are sequentially delivered from the tributary conveyor to the downstream tributary conveyor.

Further, in JP-A-51-20358, a delivery priority is given in accordance with an instruction from an article delivery outlet, a delivery sequence of articles is determined from the delivery priority and the loading status of a conveyor, and this delivery sequence is determined. It is described that articles are loaded on the conveyor from each article loading port based on the above.

Further, in Japanese Patent Laid-Open No. 51-151954, it is detected that all of the conveyed items that have joined the main conveying line have passed through a joining point on the most downstream side where the conveyed items are on standby among a plurality of waiting conveying lines. It is described that the following merging is performed.

Further, in Japanese Patent Laid-Open No. 59-69314, when a sub-line stopper opening / closing sequence is incorporated into a storage device having a sub-line number in the data input / output direction and a takt in the address direction, the storage device area is slanted. The diagonal tact is assigned to each of them, each diagonal tact always includes only the stopper open information "1" of one sub line, and the stoppers of other sub lines all have the closed information "0". The stored contents are arranged in a storage device such as a shift register, and the stopper provided at the outlet of each subline is opened / closed according to the stopper opening / closing information of the arranged sublines to transfer the conveyed product on the main line. It is described to be listed.

[Problems to be solved by the invention]

However, the conventional method of joining articles and the apparatus thereof as described above have the following problems.

In other words, none of the above publications suggests the delivery speed of articles from the merged storage line. When articles of various sizes are conveyed with a constant delivery speed of the articles, the conveyance intervals of the articles after merging are largely varied, and, for example, the articles are supplied at a certain interval or more in the subsequent process. When it is necessary, we have to decide the payout speed of the article corresponding to the smallest article,
As a result, there was an unnecessarily large space for large articles, and high merging capacity could not be obtained.

Therefore, an object of the present invention is to provide an article merging method and an apparatus for merging articles efficiently and quickly so that the space (conveyance interval) between the articles of the merging item can be made substantially constant. To do.

[Means for solving problems]

The present invention provides a method for merging articles stored in a plurality of merging storage lines 102, wherein the merging unit of the articles stored in the merging storage line 102 is an article having a similar length in the article transport direction. Formed to align with each other, the above merged storage line
When the above-mentioned article is dispensed from 102, the dispensing speed is changed so that the space between the merged articles can be made substantially constant regardless of the size of the article. The above objects are achieved by providing a method.

Further, the present invention provides an article merging apparatus for merging articles stored in a plurality of merging storage conveyors 1, as an apparatus for implementing such an article merging method,
From the merging storage conveyor 1 that stores the merging unit of the articles formed so that the articles having a similar length in the conveyance direction of the articles are aligned, the articles of the merging unit stored in the merging storage conveyor 1 are dispensed. The merging storage conveyor 1 is provided with a transmission that shifts the payout speed at this time so that the space between the merged articles can be made substantially constant regardless of the size of the articles.
An article merging device is provided which is characterized in that

〔Example〕

Hereinafter, embodiments of the present invention will be described with reference to the drawings.

FIG. 1 is a block diagram showing an example of a physical distribution system to which the method for merging articles according to the present invention is applied. In the figure, 101 is a picking line, which picks up and picks up an article for each type using a picking device based on predetermined batch picking data. A confluent storage line 102 temporarily stores the articles flowing from the picking line based on the patch picking data, collects the articles in a predetermined amount, and sends the articles to the next line. Reference numeral 103 denotes a merging / conveying line, which joins the storage lines one by one in order from the line in which predetermined articles are arranged, based on the batch picking data. Reference numeral 104 denotes a branch line, which is branched according to the data based on the branch load alignment data created according to the predetermined load alignment length, that is, the sorting group data. 105 is a load line, which stores the above-mentioned branched articles. 106 is a delivery line, and when a loading container number (car number) is set, delivery is performed for each container on a per line basis. Reference numeral 107 denotes a loading conveyor line, which transfers the discharged articles to the loading port of the container.
108 is loading and 109 is delivery. Here, the picking line 101 to the loading conveyor line 107 are automatically controlled by a computer.

FIG. 2 is a block diagram showing an example of a control system using this computer. This control system includes a general management CPU (central processing unit) 201, a physical distribution CPU 202, a control CPU 203, and a sorting system 204.

The overall management CPU 201 performs overall management of the entire physical distribution system. For example, it creates a delivery order schedule of goods based on order data and sends it to the lower physical distribution CPU 202. Further, the physical distribution CPU 202 determines a sorting group of the corresponding articles according to the delivery order schedule of the articles, creates branch load alignment data and batch picking data, and outputs this to the control CPU 203. Further, the control CPU 203 creates a required control command on the basis of the branch load alignment data and the batch picking data, which is then sorted by the sorting system 20.
Output to 4. Furthermore, the sorting system 204 performs required control such as merging control, branching control, and payout control by the sequencer.

The physical distribution CPU 202 in the control system creates required data as follows according to the flow chart in FIG. The details will be described for the case where an article is divided into five containers and loaded as shown in FIG. Incidentally, FIG. 4 (a) is a schematic plan view showing a main part of a sorting device which is used together with the article merging device of the present invention to constitute the physical distribution system of FIG.
FIG. 4 (b) is a schematic sectional view taken along the line AA of FIG. 4 (a). In these drawings, 301 is a container for loading articles, 302 is a container loader, 303 is a load line, and 30
4 is a branch line, which includes a load line 303 and a branch line 304.
Are provided in two stages. Further, 303-1 is a loading line during loading, and 303-2 is a loading line during sorting. Also, in these drawings, the articles are shown as small squares corresponding to the respective sizes.

(Step S1) ... Divide the container volume into multiple parts.

In the example of FIGS. 4 (a) and 4 (b), the volume of the container (delivery vehicle carrier) 301 is set as follows:
To divide. That is, since the container 301 in this case is a rear door (loading port), it is divided into six parts in the longitudinal direction. The number of divisions is obtained by dividing the container length by the length of a relatively large article (an integer) because it is more stable during shipping when the article with a large planar dimension (length or width) is stacked below. It was taken. Although the traveling direction of the container 301 is aligned with the longitudinal direction of the article, the present invention is not limited to this.

(Step S2)… Determine the assortment length.

The number of articles that can be accommodated in the one dividing portion determines the length of the load arrangement so that the articles can be stored on approximately one load aligning line. Therefore, as shown in FIGS. 4 (a) and 4 (b),
The articles stored in the load arranging line 303 are loaded in the dividing portion of the container 301. And so on
The articles stored in the packing line 303 of ,,, and are, in order, of the container 301 ,,,.
It will be loaded in the division of and. Since there is no article to be loaded in the divided portion of the container 301 (the article is divided into five), no article is loaded at all.

(Step S3) ... Creation of branch assortment data.

Now, it is assumed that the delivery order of the goods is given to 15 stores as shown in Table 1.

In Table 1, a to g represent product type categories,
As shown in FIGS. 4 (a) and 4 (b), the articles are arranged in descending order of the length dimension. As can be seen from Table 1, the order contents are not uniform and vary widely among the product types.

In creating the branch load alignment data, first, the delivery destinations are rearranged in the loading order as described above, and the goods are arranged in the length dimension order as described above. Next, based on this Table 1, for each article from the first store, a multiplication value obtained by multiplying the quantity and the length dimension is obtained, and the multiplication value is sequentially added in the right direction for each article. Find the value. Then, when the added value of the lengths almost reaches the length of one packing line, the data is divided, and the products up to this point are set as one sorting group, and the number of the branch destination packing line is determined for each product. Create branch data so that it will be branch-stored on the assortment line of. In Table 1 above, the total quantity of goods addressed to 15 stores is 14
The 5 pieces are divided into 5 pieces in consideration of the length of the packing line, the capacity of the container and the delivery efficiency. That is, a total of 29 divided into 5 divided into 21 for store 1, 6 for store 2, and 2 for store 3, and so on.
1 for store 3, 1 for store 4, and 5 for store 5, total 27, 5 divided into 6 for store 5, 5 for store 6, 13 for store 7, and 8 for store 7 in total, 31 divided into 5 divided into 5 for store 8
30 pieces, 5 pieces for store 9, 12 pieces for store 10, and 8 pieces for store 11
And 5 divided into 2 for store 11, 7 for store 12, and 13
There are a total of 28 for a total of 9 addresses, 7 for stores 14 and 3 for stores 15, each of which has a predetermined number of 30.

In the orders shown in Table 1 above, the general management CPU 201 determines the number of delivery destinations that can be loaded for each container (one vehicle), and also determines the order of delivery routes.

(Step S4)… Create batch picking data.

As described above, a plurality of containers are sequentially laid one by one, divided into container units, and assigned to almost all lines of the packing line 303, and the total of all articles is set as the total pinking amount. In other words, the number of packed goods loaded = the number of pickings. In Table 1 above, the total number is 3000. All containers are summed up for each product type, and in this case, picking data is created so that articles are picked in descending order of length.

As described above, articles are loaded in the container 301 in a predetermined loading state, as shown in principle in FIG. In FIG. 5, 301 'is a container door.

By performing the control as described above, the following advantages can be obtained.

That is, a plurality (rarely a single) delivery destination is calculated for each container (1 vehicle) by the general management CPU 201, and after the delivery destination order is determined, the distribution CPU 202 performs the above calculation processing to create batch picking data. However, since batch picking is performed based on this batch picking data, it is possible to perform multiple-container cloth picking as compared with one-container unit picking, which is efficient.

In addition, instead of branching and arranging for each store, when the capacity of the container is divided into a plurality of items, the number of articles is divided and the articles are stored along the length direction on the lining line within the capacity of the container. Therefore, space efficiency is good.
In the order example shown in Table 1 above, as shown in FIGS. 4 (a) and 4 (b), a,
It is possible to carry out branch load alignment with b, c, d, e, f and g.

It should be noted that the articles are discharged from the load-aligning line 303 for each load-aligning line and sequentially stacked on the divided portions of the container 301, so that the stores 1 and 2 in Table 1 can be distributed to the stores 3 and 3.
Although one copy addressed to each type is mixed and mixed, when the distributor (driver) delivers to these destinations in the order of store 3, store 2 and store 1, the deliverer arrives at the destination and the container When the door is opened, the corresponding article is present in the divided portion that almost faces. That is, the items to be delivered later do not come to the front and the items to be delivered earlier do not go to the back, and it is possible to select and unload the relevant items from the facing divisions, The same effect as branching and loading by store can be obtained. As a result, not only can the deliverer efficiently carry out the unloading work, but in the past, the deliverer makes it possible for the deliverer to deliver another container by previously placing it on the container by the deliverer himself. It is possible to effectively secure the delivery time, for example.

Next, an example of an article merging apparatus of the present invention applied to the above-described physical distribution system and an example of a sorting apparatus applied to a physical distribution system together with the article merging apparatus of the present invention will be described.

FIG. 6 is a plan view showing the outline of an embodiment of an article joining device of the present invention. In FIG. 1, reference numeral 1 denotes three sets of merge storage conveyors that form the merge storage line 102 of FIG. 1. On this merge storage conveyor 1, articles that have been picked and temporarily stored based on the batch picking data are sequentially stored. A predetermined number of articles that are stacked and placed form a confluence unit that is continuously paid out. In addition, 2 is a combined delivery conveyor which is installed at the delivery end of each of the merged storage conveyors 1 and which dispenses the above-mentioned articles in lot units (for each merged unit), and separates them one by one, or 3A, 3B A merging and delivering conveyor which is arranged so as to be substantially orthogonal to the conveyor 2 and which delivers the delivered articles. By the merging and delivering conveyor 2 and the merging and conveying conveyors 3A and 3B, a predetermined amount of the articles on the merging storage conveyor 1 are printed. The merging / conveying line 103 shown in FIG. 1 for sending out to the next line is constructed. The merging / conveying conveyor 3B is arranged so as to incline through the floor pit FP provided on the floor as shown in FIG. 6, and the switching conveyor 4 provided below the floor (see FIG. 11).
It is designed to send goods to.

More specifically, each unit in one embodiment of the apparatus for joining articles according to the present invention will be described.
It is configured as an accumulation conveyor having an accumulation function and a simultaneous dispensing function, and has a length (for example, 30 m) necessary to store the articles that form a joining unit that is continuously dispensed. That is, the merging storage conveyor 1 is in contact with the carrier roller 1A, the sensor 1B provided for each required number of the carrier roller 1A, and the carrier roller 1A, as shown in FIGS. 7 (a) and 7 (b). The pad chain 1C that rotates the carrier roller 1A and this pad chain 1C
A lifting mechanism including a mechanical valve 1D for pushing-separating from 1A and an air actuator 1E and the like, and a drive device (not shown) with a transmission device for driving the pad chain 1C are provided. Although not shown, an air circuit for biasing the mechanical valve 1D is also provided so that the articles can be simultaneously paid out. The rear end 1F (about 5 m in length) of the merge storage conveyor 1 does not have a sensor and a lifting mechanism, and the pad chain 1C is constantly pressed by the carrier roller 1A. Instead of the above-mentioned accumulation conveyor, a conveyor as described in JP-B-58-27167 may be used. Further, in FIG. 7 (b), the article is shown as a square on the carrier roller 1A.

Further, as shown in FIG. 8 (a), the above-mentioned joining and discharging conveyor 2 in the joining device separates the articles one by one,
It is a conveyor that is skewed and paid out, and a belt feeder
2A and 2B and a skewed merging conveyor 2C are arranged in series. The skewed merging conveyor 2C includes a driven skewed wheel 2D and a free roller 2E. Further, the belt feeder 2B and the skewed merging conveyor 2C are set at a higher speed than the belt feeder 2A. A curved conveyor may be used instead of the skewed merging conveyor 2C. Also, in FIG. 8 (b), PH
3, PH4 is a photo switch for detecting the completion of the payment of the goods.

The merging / transporting conveyor 3A in the merging device is a roller conveyor, and the merging / transporting conveyor 3B is a belt conveyor. These merging conveyors 3A,
3B is set to the same speed as the skewed merging conveyor 2C.

Further, in FIG. 6, reference numeral 31 denotes a transport storage conveyor for transporting picked articles and temporarily storing them, and like the merge storage conveyor 1, is constituted by an accumulation rayon conveyor. The transport storage conveyor 31 does not have to have a simultaneous payout function.

Further, in FIG. 6, reference numeral 32 denotes an article counting device, which is composed of belt conveyors 32A and 32B and photoswitches PH1 and PH2, as shown in FIGS.
Since the belt conveyor 32A is set to have a higher speed than the transport storage conveyor 31 and the belt conveyor 32B is set to have a higher speed than the belt conveyor 32A, the articles being conveyed can be separated one by one and the photo switch PH can be used.
It can be counted by 1 and PH2. The belt conveyors 32A and 32B are each driven by a motor with a brake (not shown).

As the counting device 32, the device shown in FIG. 10 can also be used. The counting device 32 in FIG. 10 is provided with a product type checking device 32C for checking the product types of the items that are being counted at substantially the same time as counting the items, except that
It is constructed similarly to the embodiment shown in FIG. The product type checker 32C has photo switches PH5 and PH on both lower ends.
It is composed of a gate type or a ram having 6 and a power cylinder for moving up and down the gate type frame, and the power cylinder is equipped with an air coder. Further, on one side wall of the portal frame, a dock 32 for two limit switches (not shown) for detecting the limit position of the vertical movement of the portal frame is provided.
C'is provided. In place of the photo switches PH5 and PH6, an outline inspection device by pattern recognition or the like, a height inspection device by ultrasonic waves, a length inspection device by the light shielding time of the photo switch, a type inspection device using a bar code, a load cell, etc. The weight inspection device according to the present invention may be used.

FIG. 11 (a) is a plan view schematically showing an example of an article sorting apparatus that constitutes the distribution system together with the article merging apparatus of the present invention described above, and FIG. 11 (b) is a plan view of FIG. 11 (a). A-
A sectional view taken along line A and FIG. 11 (c) are side views taken along line BB in FIG. 11 (a). The article sorting apparatus of this example is provided below the article merging apparatus of the present invention. . In these drawings, 4 is the above-mentioned switching conveyor, and as shown in FIG. 11 (b), the right end of the drawing moves up and down, and the article is placed on either the transport conveyor 5 or 15 installed in two layers above and below. Is reprinted. Like the conveyors 5 and 15 installed in the upper and lower two layers as described above, in FIG. 11 (a), the lower layer devices and the like are often not shown because they overlap each other.
In FIG. 11 (a), the reference numerals indicating the devices and the like are shown in the lower layer in parentheses in the vicinity of the related reference numerals and the like.

In addition, in FIGS. 11A to 11C, reference numerals 6 and 16 are index feeders for keeping a constant interval for the articles sent by the transfer conveyors 5 and 15 via the switching conveyor 4.
Further, 7 and 17 are provided with a branching device, and the branching line 104 in FIG.
The branch conveyors that make up the
The articles are sorted on the basis of the sorting group data to a large number of pull-in conveyors 8 and 18 which are arranged at a substantially right angle. Numerals 9 and 19 are inclined roller conveyors constituting the load-aligning line 105 of FIG. 1, and the articles sent by the pull-in conveyors 8 and 18 are self-propelled by the gravity component of the articles due to the inclination, and the load-alignment is performed. And it is designed to be stored.

Furthermore, 10 and 20 are payout devices constituting the payout line 106 of FIG. 1, and when the loading container number (car number) is set, the stopper means is released for each container and the payout is performed. (See FIGS. 13 (a) and 13 (b)). Further, 11 and 21 are conveyors that constitute the payout line 106 of FIG. 1 together with the above-mentioned payout devices 10 and 20, and are designed to send the articles paid out from the payout devices 10 and 20 to the loading port of the container. Further, 12 and 22 are transfers, and 13 and 23 are stoppers, by which the articles sent to the loading port of the container are loaded by the loading conveyor 14 (container loader 302 in FIG. 4) that constitutes the loading conveyor line 107 in FIG. Equivalent to). Further, between the upper-layer transfer conveyor 11 and the loading conveyor 14 is shown in FIG. 11 (c).
A switching chute 14A is provided as shown in FIG. This switching chute 14A descends to the connecting position when the article is delivered from the upper-layer transport conveyor 11, and jumps up to the non-connecting position when the article is delivered from the lower-layer transport conveyor 21 (shown by a broken line). Becomes From the loading conveyor 14, an article is loaded on the container 301 by an operator.

In FIG. 11 (a), the overflow lines 26 and 27 shown on the left side store articles that cannot be branched because there is no branch data.

Next, one embodiment of the method for merging articles of the present invention, which is carried out by using the apparatus for merging articles of the present invention shown in FIGS. 6 to 10, will be described.

The articles picked by the picking equipment (not shown) provided upstream of the transport storage conveyor 31 based on the above-described batch picking data are transported to the counting device 32 by the transport storage conveyor 31. If the article is placed on the merge storage conveyor 1 (the delivery of the article on the merge storage conveyor 1 is not completed), the belt conveyors 32A and 32B of the counting device 32 are stopped. Therefore, when the leading article reaches the counting device 32, the article is sequentially stored on the transport storage conveyor 31 without leaving a gap between the articles. When the delivery of the articles on the merge storage conveyor 1 is completed, the belt conveyor 32
A and 32B are operated, and the articles on the transport storage conveyor 31 are stored on the merge storage conveyor 1 while being counted by the photoswitches PH1 and PH2.
Further, if the articles arrive at the counting device 32 when the articles are not placed on the merging storage conveyor 1, the belt conveyors 32A and 32B are operated, and the articles are merged while being counted. It is stored on the storage conveyor 1.

The belt conveyors 32A and 32B of the counting device 32 are shown in Table 2 below.
Since the speed is set as shown in, the articles can be separated one by one and can be counted by the photo switches PH1 and PH2. That is, as shown in FIG. 9 (c), when the photo switches PH1 and PH2 are shielded in the order of a, b, and c, it is counted that one article has passed. Then, the counted articles are transported to the merge storage conveyor 1 and stored. Based on the batch picking data, when a predetermined number of articles have passed (counted) and the photo switches PH1 and PH2 are in the light entering state, the belt conveyors 32A and 32B are stopped and the succeeding articles are conveyed to the storage conveyor. Stored on 31.

When the counting device 32 including the product type checking device 32C as shown in FIG. 10 is used, the batch picking data (conveyance data including the conveyance order, the conveyance quantity, and the outer diameter dimension of the articles) is added. Photo switch PH based
5, PH6 is a predetermined height (for example, as shown in FIG. 10 (d), the photo switch PH5 is about 5 mm below the photo switch PH5, and the photo switch PH6 is about 15 mm below it).
By moving the power cylinder to the upper position), the types of the articles are checked at the same time when the articles are counted. That is, the power cylinder detects the amount of vertical movement of the power cylinder by measuring the pulse of the encoder, and the detection result indicates the outer diameter dimension of the article based on the batch picking data, that is, the height of the article in this embodiment. It is controlled to stop the ascending / descending at the time when it coincides with the command signal. Under such control, when the article reaches the position of the photo switch PH1 and the photo switch PH5 is shielded from light, it is normal if the photo switch PH5 is shielded and the photo switch PH6 is illuminated. Counted by photo switches PH1 and PH2,
It is conveyed to the merge storage conveyor 1. If a product type abnormality is detected by the photo switches PH5 and PH6, that is, at the same time as counting the actually conveyed articles, the actually conveyed articles are the above-mentioned conveyance corresponding to the count value. As a result of checking whether they match the outer diameter dimension of the article on the data, if it is detected that they do not match, the belt conveyors 32A and 32B stop. When the counting of a certain product is completed, the photo switch PH is reached to the height of the next product by the power cylinder.
5, PH6 goes up and down. If the next article arrives before the elevation is completed and the photo switch PG1 is shielded from light, the belt conveyors 32A and 32B are immediately stopped, and after the elevation is completed, the belt conveyors 32A and 32B are operated again. In the above explanation, the product type is checked for all articles,
Even if you check only the first and last products for each type of product that flows continuously, you can obtain the same effect as a 100% check, so you need a processing capacity that requires calculations instead of the photo switches PH5 and PH6. When using a low product type checking device, it is not always necessary to check all items.

The articles that have passed through the counting device 32 and have been transferred to the merging storage conveyor 1 have the merging / discharging conveyor 2 stopped. It is stored without a gap between and. This storage is completed when the stored articles substantially fill the merging storage conveyor 1 in the length direction thereof, that is, when a merging unit of articles consisting of a predetermined number of articles is formed on the merging storage conveyor 1. . In this case, the article storage completion means that from the first article to the last article after the last article has passed the photo switch PH2 (returned to the light entering state) based on the merged storage length data of the articles from the batch picking data. A controller (not shown) calculates the time required to store the objects without any gap, and when the last article passes the photoswitch PH2 and the above time elapses, that is, all the articles have a gap between them. It means when it is in a stored state without. Then, when the counting of the last article is completed, the belt feeders 2A and 2B are driven and the first article is moved to the photo switch PH3.
The belt feeders 2A and 2B are stopped when the item reaches the position, in preparation for the start of the delivery of the articles.

In the present embodiment, when the batch picking data is created in step S4 described above, all containers are summed up for each product type, and the articles are picked in descending order of the length dimension, and the merge storage conveyor 1 is moved in the length direction. A merging unit is formed by dividing the number of articles to be substantially filled. Therefore, in a certain merging unit, only one type of article may be stored, but since normally one merging unit is formed by a plurality of varieties of articles, merging switching is performed as compared with the case of merging in each merging type. Less frequently,
The switching loss time can be reduced, and as a result, the merging ability can be increased without increasing the conveyance speed of the articles at the time of merging.

A predetermined number of articles that have completed storage on the merged storage conveyor 1 to form a merged unit are delivered in the order in which the storage is completed. Converging storage conveyor 1
Can be shifted in four steps, and can be shifted to an appropriate payout speed according to the size of the article. That is, depending on the length of the article in the direction in which the article is conveyed, less than 330 mm, 330 mm or more and 390 mm
Less than, 390mm or more, less than 530mm, divided into four categories of 530mm or more, corresponding to the goods of each category, the payout speed of the goods 21.2m / min, 25.5m / min, 28.4m / min, 33.8m / min Has become. By changing the payout speed in this way,
Since the article dispensing interval can be made substantially constant regardless of the size of the article, the number of articles dispensed per unit time can be made substantially constant. When the articles stored on the merge storage conveyor 1 straddle a plurality of the above sections, the payout speed is changed according to the smaller section. However, as described in the above description of step S4, since the articles are conveyed in the order of the length, the articles are usually contained in one size section.

Before the merging / discharging conveyor 2 starts to discharge the articles onto the merging / conveying conveyor 3A, the merging / storage conveyor 1
Is changed to a predetermined payout speed based on the batch picking data, and when the operation of the merging / discharging conveyor 2 is started, the articles on the merging storage conveyor 1 are continuously moved without leaving a gap between the articles. (All articles are simultaneously started by using the simultaneous delivery function) The articles are delivered to the joining delivery conveyor 2, separated one by one by the joining delivery conveyor 2, accelerated, and delivered to the joining delivery conveyor 3A. It In this case, the articles are delivered onto the merging and conveying conveyor 3A that is skewed by the skewed merging conveyor 2C. By simultaneously delivering the articles on the merged storage conveyor 1 as described above, the variation in the article delivery pitch can be reduced. When the delivery of the article on the merge storage conveyor 1 is completed, the merge storage conveyor 1 is shifted to its fastest speed of 33.8 m / min (if it was delivered at this speed, it remains the same) to store the next article. Prepare still,
The photo switch PH3 will continue 2 times to complete the delivery of goods.
When the light is on for a second, it is determined that the photo switch PH4 corresponding to the delivered merge storage conveyor 1 is on.

When the delivery of the articles from a certain merge storage conveyor 1 is completed and the delivery of the articles from the next merge storage conveyor 1 is started, the article delivery start time is controlled so that the articles do not collide with each other. ing. That is, when the delivery of the articles from the merge storage conveyor 1 merged to the downstream side of the merge transport conveyor 3A is completed and the dispensing is started from the merge storage conveyor 1 merged to the upstream side of the merge transport conveyor 3A, the payment is performed. Upon completion (when the photo switch PH3 is in the light entering state for 2 seconds continuously, the photo switch PH4 is in the light entering state), the next payout is started. When the delivery of the articles from the merge storage conveyor 1 merged to the upstream side of the merge transport conveyor 3A is completed and the dispensing of the merge storage conveyor 1 merged to the downstream side of the merge transport conveyor 3A is started, After a lapse of a predetermined time (time until the delivered article reaches the photo switch PH4 corresponding to the merge storage conveyor 1 to be delivered next) after the delivery is completed,
When the photo switch PH4 corresponding to the merged storage conveyor 1 to be paid out next is in the light entering state, the next payout is started. Therefore, in the present embodiment, the predetermined time from the completion of the delivery of the article to the start of the delivery of the next article is as shown in Table 3 below.

Next, the sorting or moving operation of the articles by the above sorting apparatus will be described, and the details of the sorting apparatus will also be described.

FIGS. 12 (a) and 12 (b) show the branch conveyor 7 (1
7 (a) is a plan view, and FIG. 7 (b) is a front view. In FIGS. 12A and 12B, a plurality of conveyor belts 7A feed articles (not shown) in the direction of arrow a. At a predetermined position between the conveyor belts 7A, a skewed wheel 7B is arranged so that its rotation axis 7C forms a predetermined angle with the traveling axis of the conveyor belt 7A. The rotating shaft 7C is supported by a bracket 7D so that the skewed wheel 7B can freely rotate, and the bracket 7D is supported by a lifting device 7E via an arm 7F. This branch conveyor 7 (17) is shown in Fig. 11 (a).
One set is provided for each of the many pull-in conveyors 8 (18) shown in FIG.

The branch conveyor 7 (17) with respect to the required pull-in conveyor 8 (18) is instructed by the above-mentioned instruction of the sorting group data.
As shown in FIG. 12 (b), the skewed wheel is pushed up in the direction of arrow b by the lifting device 7E to take the position of the broken line, so that the article is moved in the direction of arrow c and sent to the pull-in conveyor (not shown).

FIGS. 13 (a) and 13 (b) are the dispensing device 10 of FIG. 11 for dispensing the items stored in the load line 105 of FIG.
In the operation explanatory view of (20), the same figure (a) shows a plan view and the same figure (b) shows the AA line sectional view of (a).

In FIG. 13 (b), an article (not shown) is self-propelled on the free roller 10A as shown by an arrow d, but the lever 10E is normally positioned by the pay-out cylinder 10D so as to move the frame 10C to the frame 10C. Since it is pushed up, the stopper 10B and each lift channel 10F are positioned above the upper surface of the free roller 10A, and hold articles not shown in the figure.

When a predetermined signal is input, the cylinder 10D turns the lever 10E in the direction of arrow e, and the frame 10C turns around the shaft 10G in the direction of arrow f, so that the stopper 10B and the lift channel 10F are rotated.
Is below the upper surface of the free roller 10A. For this reason, articles not shown in the figure move and are conveyed from the drive wheel 10H to the conveyor 11
Transferred to (21).

FIG. 14 shows the loading conveyor 14 of FIG. 11 (in the case of the upper layer, a switching chute in which the articles (indicated by a chain line) placed on the conveyor 11 (21) and fed in the direction of arrow g are arranged in the direction of arrow h. Transfer 12 (2
FIG. 3 is an operation explanatory view of 2) and a stopper 13 (23). Since the transfer cylinder 12B and the stopper cylinder 13B do not operate when the article is not transferred, the upper ends of the wheels 12D and the stopper plate 13A provided on the frame 12C are located at a position lower than the upper surface of the drive roller 12A. . Therefore, an article passing therethrough proceeds in the direction of arrow g. If a signal for transfer operation is input, the trunk transfer cylinder 12B and stopper cylinder 13B will
Each wheel 12D operates in the direction of arrow j and k respectively.
Since the stopper plate 13A is pushed up to the position indicated by the broken line, the article is transferred in the direction of arrow h.

The features and the like of the embodiment of the merging method of the present invention and the embodiment of the apparatus described above are as follows.

-A merge unit is sequentially formed for each amount of articles that substantially fills the merge storage line along its length, and after the articles in the merge unit have been stored, these articles are merged, and The merging unit is increased by providing a relatively long merging storage line, and usually one merging unit is formed by a plurality of product types. Switching frequency is reduced and switching loss time can be reduced.

For example, a total of 3000 articles of 500 varieties (average length
0.4m) and 30m merge storage lines are used to alternately merge, the total switching loss time shown in Table 3 is 112 seconds (40 switching times). When switching every time, the total switching loss time is 14
00 seconds (500 switching times) and 300 in 1 hour (3600 seconds)
When 0 items are merged, the switching loss time ratios are 3% and 39%, respectively.

Therefore, in the above-described embodiments and examples, the conveying speed of the articles at the time of joining can be increased.

-After counting the items, the items are stored in the merge storage line, so that the counting can be performed relatively slowly, and counting mistakes can be reduced.

For example, when 3,000 articles are merged alternately by using three merging storage lines per hour, it is enough to count slowly at about 1000 pieces / hour, pay out at 3000 pieces / hour, and merge. On the other hand, when a counting device was installed near the confluence, it was necessary to count at a speed of 3000 pieces / hour, resulting in a counting error.

Therefore, in the above-described embodiments and examples, it is possible to reduce counting errors, more reliably track the articles, and join the articles at high speed without slowing the joining speed of the articles.

Since the transportation speed when the articles are discharged from the merged storage line is changed according to the size of the articles, the transportation interval of the articles after the merging can be made substantially constant.

If the payout speed of the articles is constant, the conveyance pitch of the articles after joining will be as follows.

P = L + C P: Conveyance pitch L: Size of article (length) C: Gap between articles Therefore, the conveyance pitch P varies depending on the size L of the article (C is the size L of the article. Proportional variable).
In this case, when the gap C between the articles exceeds the sorting ability of the branch conveyor for branching the merged articles, it is necessary to provide a conveyance interval control means in front of the branch conveyor, and the whole physical distribution system can be provided. The configuration becomes complicated.

In the above-described embodiments and examples, since the articles can be merged at a substantially constant interval according to the ability of the branch conveyor, the sorting ability of the branch conveyor can be constantly exerted.

・ When counting items, the product types that are being counted are checked almost at the same time.Therefore, picking smears of products by picking devices or product misalignment due to counting errors can be detected, and the products are merged or sorted. The data can be repaired before being stolen, and large quantities of articles can be prevented from being missorted.

Therefore, in the above-described embodiments and examples, the follow-up smear of the article can be almost completely eliminated.

Although the article merging method and the apparatus thereof according to the present invention have been described above, the article merging method and the apparatus according to the present invention are not limited thereto. For example, the merging storage line 102 may be three lines. You don't have to.

In addition, the merge storage line 102 is located on the upper floor, and the packing line 1
Although 05 is arranged under the step, they may be provided in the same step.

〔The invention's effect〕

According to the article merging method and the apparatus thereof of the present invention, even when merging a variety of articles, the conveyance interval between the articles after merging and the article can be made substantially constant, so that the articles can be efficiently and quickly formed. The effect of being able to join is exhibited.

[Brief description of drawings]

FIG. 1 is a block diagram showing an example of a physical distribution system to which an embodiment of the method of joining articles according to the present invention is applied, FIG. 2 is a block diagram showing a control system of the physical distribution system, and FIG. Flowchart showing the control data creation procedure, No. 4
FIG. 4A is a schematic plan view showing the main part of the sorting device,
FIG. 5B is a schematic sectional view taken along line AA of FIG.
FIG. 6 is a schematic cross-sectional view showing the principle of loading of articles in a container, FIG. 6 is a plan view showing the outline of an embodiment of the article joining device of the present invention, and FIG. FIG. 7 (b) is a side view showing a principal part of the merged storage conveyor 1 in principle, and FIG. 8 (a) is a detailed view of the merged / delivered conveyor. Partially omitted plan view, FIG. 8 (b) is a plan view showing the outline of the merge delivery conveyor and merge transport conveyor, FIG.
FIG. 9A is a plan view showing the counting device, FIG. 9B is a side view thereof, and FIG. 9C is an operation explanatory view thereof.
FIG. 10 (a) is a plan view showing another counting device,
10 (b) is a side view thereof, FIG. 10 (c) is a perspective view of the product type checking apparatus, and FIG. 10 (d) is an operation explanatory view thereof.
FIG. 11 (a) is a plan view showing an outline of an example of a sorting device,
FIG. 11 (b) is a sectional view taken along line AA of FIG. 11 (a), FIG. 11 (c) is a side view taken along line BB of FIG. 11 (a), and FIG. 12 (a).
Is a plan view of the main part for explaining the operation of the branch conveyor,
FIG. 12 (b) is a front view thereof, FIG. 13 (a) is a plan view of an essential part for explaining the operation of the dispensing device, and FIG. 13 (b) is AA of FIG. 13 (a). FIG. 14 is a perspective view of a main part for explaining the operation of the transfer and the stopper. 1 ... Merge storage conveyor 102 ... Merge storage line

─────────────────────────────────────────────────── ─── Continuation of front page (51) Int.Cl. ⁵ Identification number Office reference number FI technical display location B65G 47/70 8010-3F // B65G 47/54 B

Claims (4)

[Claims] 1. A method of merging articles stored in a plurality of merging storage lines 102, wherein the merging units of the articles stored in the merging storage line 102 are close to each other in length in the conveyance direction of the articles. The articles are formed so that they are aligned with each other, and the dispensing speed when the articles are dispensed from the merging storage line 102 is set to a substantially constant space between the joined articles regardless of the size of the articles. A method of merging articles, which is characterized by shifting to obtain. 2. An article merging device for merging articles stored in a plurality of merging storage conveyors 1, wherein a merging unit of the articles is formed so that the articles having similar lengths in the conveying direction are aligned. Regardless of the size of the article, the payout speed at the time of delivering the article of the merging unit stored in the merging storage conveyor 1 from the merging storage conveyor 1 A device for merging articles, characterized in that the merging storage conveyor 1 is provided with a transmission device for changing the speed so that the intervals can be made substantially constant. 3. The device for merging articles according to claim (2), wherein the merging storage conveyor 1 is an accumulation conveyor having an accumulation function and a simultaneous dispensing function. 4. The payout end of the merge storage conveyor 1,
The article merging device according to claim (2) or (3), further comprising a merging / delivery conveyor 2 for delivering the articles stored in the merging / storage conveyor 1.